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+The Project Gutenberg EBook of Encyclopaedia Britannica, 11th Edition,
+Volume 11, Slice 6, by Various
+
+This eBook is for the use of anyone anywhere at no cost and with
+almost no restrictions whatsoever.  You may copy it, give it away or
+re-use it under the terms of the Project Gutenberg License included
+with this eBook or online at www.gutenberg.org
+
+
+Title: Encyclopaedia Britannica, 11th Edition, Volume 11, Slice 6
+       "Geodesy" to "Geometry"
+
+Author: Various
+
+Release Date: September 17, 2011 [EBook #37461]
+
+Language: English
+
+Character set encoding: ASCII
+
+*** START OF THIS PROJECT GUTENBERG EBOOK ENCYCLOPAEDIA BRITANNICA ***
+
+
+
+
+Produced by Marius Masi, Don Kretz and the Online
+Distributed Proofreading Team at http://www.pgdp.net
+
+
+
+
+
+
+
+
+
+Transcriber's notes:
+
+(1) Numbers following letters (without space) like C2 were originally
+      printed in subscript. Letter subscripts are preceded by an
+      underscore, like C_n.
+
+(2) Characters following a carat (^) were printed in superscript.
+
+(3) Side-notes were relocated to function as titles of their respective
+      paragraphs.
+
+(4) Macrons and breves above letters and dots below letters were not
+      inserted.
+
+(5) [root] stands for the root symbol; [alpha], [beta], etc. for greek
+      letters.
+
+(6) The following typographical errors have been corrected:
+
+    ARTICLE GEOFFREY: "... his history in chiefly one of quarrels, with
+      the see of Canterbury, with the chancellor William Longchamp, with
+      his half-brothers Richard and John, and especially with his canons
+      at York." 'William' amended from 'Willian'.
+
+    ARTICLE GEOLOGY: "... and at the same time greater appreciation has
+      been shown of the signification and strength of the geological
+      proofs of the high antiquity of our planet." 'strength' amended
+      from 'stength'.
+
+    ARTICLE GEOLOGY: "... it can be demonstrated that sometimes an inch
+      or two of sediment might, on certain horizons, represent the
+      deposit of an enormously longer period than a hundred or a thousand
+      times the same amount of sediment on other horizons." 'might'
+      amended from 'much'.
+
+    ARTICLE GEOLOGY: "But no such extensive disturbance of the normal
+      conditions of the distribution of life can take place without
+      carrying with it many secondary effects, and setting in motion a
+      wide cycle of change and of reaction in the animal and vegetable
+      kingdoms." 'kingdoms' amended from 'kindgoms'.
+
+    ARTICLE GEOMETRY: "The bases and altitudes of equal solid
+      parallelepipeds are reciprocally proportional; and if the bases and
+      altitudes be reciprocally proportional, the solid parallelepipeds
+      are equal." 'are' amended from 'and'.
+
+    ARTICLE GEOMETRY: "An alternative method of testing a relation is
+      illustrated in the following example:--If A, B, C, D, E,
+      F be six collinear points, then" 'following example:--' amended
+      from 'example: following'.
+
+    ARTICLE GEOMETRY: "3. In an hyperbolic involution any two conjugate
+      points are harmonic conjugates with regard to the two foci." 'an'
+      amended from 'a'.
+
+    ARTICLE GEOMETRY: "If two lines, given by their projections,
+      intersect, the intersection of their planes and the intersection of
+      their elevations must lie in a line perpendicular to the axis,
+      because they must be the projections of the point common to the two
+      lines." 'planes' amended from 'plans'.
+
+    ARTICLE GEOMETRY: "Where this is the case, if [alpha] be the measure
+      of curvature, the linear element can be put into the form" 'if'
+      amended from 'it'.
+
+    ARTICLE GEOMETRY: "The development of the consequences of these
+      metrical definitions is the subject of non-Euclidean geometry."
+      'subject' amended from 'subjct'.
+
+
+
+
+          ENCYCLOPAEDIA BRITANNICA
+
+  A DICTIONARY OF ARTS, SCIENCES, LITERATURE
+           AND GENERAL INFORMATION
+
+              ELEVENTH EDITION
+
+
+            VOLUME XI, SLICE VI
+
+            GEODESY to GEOMETRY
+
+
+
+
+ARTICLES IN THIS SLICE:
+
+
+  GEODESY                          GEOFFROY, ETIENNE FRANCOIS
+  GEOFFREY (Martel)                GEOFFROY, JULIEN LOUIS
+  GEOFFREY (Plantagenet)           GEOFFROY SAINT-HILAIRE, ETIENNE
+  GEOFFREY (duke of Brittany)      GEOFFROY SAINT-HILAIRE, ISIDORE
+  GEOFFREY (archbishop of York)    GEOGRAPHY
+  GEOFFREY DE MONTBRAY             GEOID
+  GEOFFREY OF MONMOUTH             GEOK-TEPE
+  GEOFFREY OF PARIS                GEOLOGY
+  GEOFFREY THE BAKER               GEOMETRICAL CONTINUITY
+  GEOFFRIN, MARIE THERESE RODET    GEOMETRY
+
+
+
+
+GEODESY (from the Gr. [Greek: ge], the earth, and [Greek: daiein], to
+divide), the science of surveying (q.v.) extended to large tracts of
+country, having in view not only the production of a system of maps of
+very great accuracy, but the determination of the curvature of the
+surface of the earth, and eventually of the figure and dimensions of the
+earth. This last, indeed, may be the sole object in view, as was the
+case in the operations conducted in Peru and in Lapland by the
+celebrated French astronomers P. Bouguer, C.M. de la Condamine, P.L.M.
+de Maupertuis, A.C. Clairault and others; and the measurement of the
+meridian arc of France by P.F.A. Mechain and J.B.J. Delambre had for
+its end the determination of the true length of the "metre" which was to
+be the legal standard of length of France (see EARTH, FIGURE OF THE).
+
+The basis of every extensive survey is an accurate triangulation, and
+the operations of geodesy consist in the measurement, by theodolites, of
+the angles of the triangles; the measurement of one or more sides of
+these triangles on the ground; the determination by astronomical
+observations of the azimuth of the whole network of triangles; the
+determination of the actual position of the same on the surface of the
+earth by observations, first for latitude at some of the stations, and
+secondly for longitude; the determination of altitude for all stations.
+
+For the computation, the points of the actual surface of the earth are
+imagined as projected along their plumb lines on the mathematical
+figure, which is given by the stationary sea-level, and the extension of
+the sea through the continents by a system of imaginary canals. For many
+purposes the mathematical surface is assumed to be a plane; in other
+cases a sphere of radius 6371 kilometres (20,900,000 ft.). In the case
+of extensive operations the surface must be considered as a compressed
+ellipsoid of rotation, whose minor axis coincides with the earth's axis,
+and whose compression, flattening, or ellipticity is about 1/298.
+
+
+_Measurement of Base Lines._
+
+  To determine by actual measurement on the ground the length of a side
+  of one of the triangles ("base line"), wherefrom to infer the lengths
+  of all the other sides in the triangulation, is not the least
+  difficult operation of a trigonometrical survey. When the problem is
+  stated thus--To determine the number of times that a certain standard
+  or unit of length is contained between two finely marked points on the
+  surface of the earth at a distance of some miles asunder, so that the
+  error of the result may be pronounced to lie between certain very
+  narrow limits,--then the question demands very serious consideration.
+  The representation of the unit of length by means of the distance
+  between two fine lines on the surface of a bar of metal at a certain
+  temperature is never itself free from uncertainty and probable error,
+  owing to the difficulty of knowing at any moment the precise
+  temperature of the bar; and the transference of this unit, or a
+  multiple of it, to a measuring bar will be affected not only with
+  errors of observation, but with errors arising from uncertainty of
+  temperature of both bars. If the measuring bar be not
+  self-compensating for temperature, its expansion must be determined by
+  very careful experiments. The thermometers required for this purpose
+  must be very carefully studied, and their errors of division and index
+  error determined.
+
+  In order to avoid the difficulty in exactly determining the
+  temperature of a bar by the mercury thermometer, F.W. Bessel
+  introduced in 1834 near Konigsberg a compound bar which constituted a
+  metallic thermometer.[1] A zinc bar is laid on an iron bar two toises
+  long, both bars being perfectly planed and in free contact, the zinc
+  bar being slightly shorter and the two bars rigidly united at one end.
+  As the temperature varies, the difference of the lengths of the bars,
+  as perceived by the other end, also varies, and affords a quantitative
+  correction for temperature variations, which is applied to reduce the
+  length to standard temperature. During the measurement of the base
+  line the bars were not allowed to come into contact, the interval
+  being measured by the insertion of glass wedges. The results of the
+  comparisons of four measuring rods with one another and with the
+  standards were elaborately computed by the method of least-squares.
+  The probable error of the measured length of 935 toises (about 6000
+  ft.) has been estimated as 1/863500 or 1.2 [mu] ([mu] denoting a
+  millionth). With this apparatus fourteen base lines were measured in
+  Prussia and some neighbouring states; in these cases a somewhat higher
+  degree of accuracy was obtained.
+
+  The principal triangulation of Great Britain and Ireland has seven
+  base lines: five have been measured by steel chains, and two, more
+  exactly, by the compensation bars of General T.F. Colby, an apparatus
+  introduced in 1827-1828 at Lough Foyle in Ireland. Ten base lines were
+  measured in India in 1831-1869 by the same apparatus. This is a system
+  of six compound-bars self-correcting for temperature. The bars may be
+  thus described: Two bars, one of brass and the other of iron, are laid
+  in parallelism side by side, firmly united at their centres, from
+  which they may freely expand or contract; at the standard temperature
+  they are of the same length. Let AB be one bar, A'B' the other; draw
+  lines through the corresponding extremities AA' (to P) and BB' (to Q),
+  and make A'P = B'Q, AA' being equal to BB'. If the ratio A'P/AP equals
+  the ratio of the coefficients of expansion of the bars A'B' and AB,
+  then, obviously, the distance PQ is constant (or nearly so). In the
+  actual instrument P and Q are finely engraved dots 10 ft. apart. In
+  practice the bars, when aligned, are not in contact, an interval of 6
+  in. being allowed between each bar and its neighbour. This distance is
+  accurately measured by an ingenious micrometrical arrangement
+  constructed on exactly the same principle as the bars themselves.
+
+  The last base line measured in India had a length of 8913 ft. In
+  consequence of some suspicion as to the accuracy of the compensation
+  apparatus, the measurement was repeated four times, the operations
+  being conducted so as to determine the actual values of the probable
+  errors of the apparatus. The direction of the line (which is at Cape
+  Comorin) is north and south. In two of the measurements the brass
+  component was to the west, in the others to the east; the differences
+  between the individual measurements and the mean of the four were
+  +0.0017, -0.0049, -0.0015, +0.0045 ft. These differences are very
+  small; an elaborate investigation of all sources of error shows that
+  the probable error of a base line in India is on the average [+-]2.8
+  [mu]. These compensation bars were also used by Sir Thomas Maclear in
+  the measurement of the base line in his extension of Lacaille's arc at
+  the Cape. The account of this operation will be found in a volume
+  entitled _Verification and Extension of Lacaille's Arc of Meridian at
+  the Cape of Good Hope_, by Sir Thomas Maclear, published in 1866. A
+  rediscussion has been given by Sir David Gill in his _Report on the
+  Geodetic Survey of South Africa, &c., 1896_.
+
+  A very simple base apparatus was employed by W. Struve in his
+  triangulations in Russia from 1817 to 1855. This consisted of four
+  wrought-iron bars, each two toises (rather more than 13 ft.) long; one
+  end of each bar is terminated in a small steel cylinder presenting a
+  slightly convex surface for contact, the other end carries a contact
+  lever rigidly connected with the bar. The shorter arm of the lever
+  terminates below in a polished hemisphere, the upper and longer arm
+  traversing a vertical divided arc. In measuring, the plane end of one
+  bar is brought into contact with the short arm of the contact lever
+  (pushed forward by a weak spring) of the next bar. Each bar has two
+  thermometers, and a level for determining the inclination of the bar
+  in measuring. The manner of transferring the end of a bar to the
+  ground is simply this: under the end of the bar a stake is driven very
+  firmly into the ground, carrying on its upper surface a disk, capable
+  of movement in the direction of the measured line by means of
+  slow-motion screws. A fine mark on this disk is brought vertically
+  under the end of the bar by means of a theodolite which is planted at
+  a distance of 25 ft. from the stake in a direction perpendicular to
+  the base. Struve investigated for each base the probable errors of the
+  measurement arising from each of these seven causes: Alignment,
+  inclination, comparisons with standards, readings of index, personal
+  errors, uncertainties of temperature, and the probable errors of
+  adopted rates of expansion. He found that [+-]0.8 [mu] was the mean of
+  the probable errors of the seven bases measured by him. The
+  Austro-Hungarian apparatus is similar; the distance of the rods is
+  measured by a slider, which rests on one of the ends of each rod.
+  Twenty-two base lines were measured in 1840-1899.
+
+  General Carlos Ibanez employed in 1858-1879, for the measurement of
+  nine base lines in Spain, two apparatus similar to the apparatus
+  previously employed by Porro in Italy; one is complicated, the other
+  simplified. The first, an apparatus of the brothers Brunner of Paris,
+  was a thermometric combination of two bars, one of platinum and one of
+  brass, in length 4 metres, furnished with three levels and four
+  thermometers. Suppose A, B, C three micrometer microscopes very firmly
+  supported at intervals of 4 metres with their axes vertical, and
+  aligned in the plane of the base line by means of a transit
+  instrument, their micrometer screws being in the line of measurement.
+  The measuring bar is brought under say A and B, and those micrometers
+  read; the bar is then shifted and brought under B and C. By repetition
+  of this process, the reading of a micrometer indicating the end of
+  each position of the bar, the measurement is made.
+
+  Quite similar apparatus (among others) has been employed by the French
+  and Germans. Since, however, it only permitted a distance of about 300
+  m. to be measured daily, Ibanez introduced a simplification; the
+  measuring rod being made simply of steel, and provided with inlaid
+  mercury thermometers. This apparatus was used in Switzerland for the
+  measurement of three base lines. The accuracy is shown by the
+  estimated probable errors: [+-]0.2 [mu] to [+-]0.8 [mu]. The distance
+  measured daily amounts at least to 800 m.
+
+  A greater daily distance can be measured with the same accuracy by
+  means of Bessel's apparatus; this permits the ready measurement of
+  2000 m. daily. For this, however, it is important to notice that a
+  large staff and favourable ground are necessary. An important
+  improvement was introduced by Edward Jaderin of Stockholm, who
+  measures with stretched wires of about 24 metres long; these wires are
+  about 1.65 mm. in diameter, and when in use are stretched by an
+  accurate spring balance with a tension of 10 kg.[2] The nature of the
+  ground has a very trifling effect on this method. The difficulty of
+  temperature determinations is removed by employing wires made of
+  invar, an alloy of steel (64%) and nickel (36%) which has practically
+  no linear expansion for small thermal changes at ordinary
+  temperatures; this alloy was discovered in 1896 by Benoit and
+  Guillaume of the International Bureau of Weights and Measures at
+  Breteuil. Apparently the future of base-line measurements rests with
+  the invar wires of the Jaderin apparatus; next comes Porro's apparatus
+  with invar bars 4 to 5 metres long.
+
+  Results have been obtained in the United States, of great importance
+  in view of their accuracy, rapidity of determination and economy. For
+  the measurement of the arc of meridian in longitude 98 deg. E., in
+  1900, nine base lines of a total length of 69.2 km. were measured in
+  six months. The total cost of one base was $1231. At the beginning and
+  at the end of the field-season a distance of exactly 100 m. was
+  measured with R.S. Woodward's "5-m. ice-bar" (invented in 1891); by
+  means of the remeasurement of this length the standardization of the
+  apparatus was done under the same conditions as existed in the case of
+  the base measurements. For the measurements there were employed two
+  steel tapes of 100 m. long, provided with supports at distances of 25
+  m., two of 50 m., and the duplex apparatus of Eimbeck, consisting of
+  four 5-m. rods. Each base was divided into sections of about 1000 m.;
+  one of these, the "test kilometre," was measured with all the five
+  apparatus, the others only with two apparatus, mostly tapes. The
+  probable error was about [+-]0.8 [mu], and the day's work a distance
+  of about 2000 m. Each of the four rods of the duplex apparatus
+  consists of two bars of brass and steel. Mercury thermometers are
+  inserted in both bars; these serve for the measurement of the length
+  of the base lines by each of the bars, as they are brought into their
+  consecutive positions, the contact being made by an elastic-sliding
+  contact. The length of the base lines may be calculated for each bar
+  only, and also by the supposition that both bars have the same
+  temperature. The apparatus thus affords three sets of results, which
+  mutually control themselves, and the contact adjustments permit rapid
+  work. The same device has been applied to the older
+  bimetallic-compensating apparatus of Bache-Wurdemann (six bases,
+  1847-1857) and of Schott. There was also employed a single rod
+  bimetallic apparatus on F. Porro's principle, constructed by the
+  brothers Repsold for some base lines. Excellent results have been more
+  recently obtained with invar tapes.
+
+  The following results show the lengths of the same German base lines
+  as measured by different apparatus:
+
+                                                 metres.
+    Base at Berlin   1864 Apparatus of Bessel   2336.3920
+        "     "      1880     "        Brunner      .3924
+    Base at Strehlen 1854     "        Bessel   2762.5824
+        "     "      1879     "        Brunner      .5852
+    Old base at Bonn 1847     "        Bessel   2133.9095
+        "     "      1892     "          "          .9097
+    New base at Bonn 1892     "          "      2512.9612
+        "     "      1892     "        Brunner      .9696
+
+  It is necessary that the altitude above the level of the sea of every
+  part of a base line be ascertained by spirit levelling, in order that
+  the measured length may be reduced to what it would have been had the
+  measurement been made on the surface of the sea, produced in
+  imagination. Thus if l be the length of a measuring bar, h its height
+  at any given position in the measurement, r the radius of the earth,
+  then the length radially projected on to the level of the sea is l(1 -
+  h/r). In the Salisbury Plain base line the reduction to the level of
+  the sea is -0.6294 ft.
+
+  The total number of base lines measured in Europe up to the present
+  time is about one hundred and ten, nineteen of which do not exceed in
+  length 2500 metres, or about 1-1/2 miles, and three--one in France, the
+  others in Bavaria--exceed 19,000 metres. The question has been
+  frequently discussed whether or not the advantage of a long base is
+  sufficiently great to warrant the expenditure of time that it
+  requires, or whether as much precision is not obtainable in the end by
+  careful triangulation from a short base. But the answer cannot be
+  given generally; it must depend on the circumstances of each
+  particular case. With Jaderin's apparatus, provided with invar wires,
+  bases of 20 to 30 km. long are obtained without difficulty.
+
+  [Illustration: FIG. 1.]
+
+  In working away from a base line ab, stations c, d, e, f are carefully
+  selected so as to obtain from well-shaped triangles gradually
+  increasing sides. Before, however, finally leaving the base line, it
+  is usual to verify it by triangulation thus: during the measurement
+  two or more points, as p, q (fig. 1), are marked in the base in
+  positions such that the lengths of the different segments of the line
+  are known; then, taking suitable external stations, as h, k, the
+  angles of the triangles bhp, phq, hqk, kqa are measured. From these
+  angles can be computed the ratios of the segments, which must agree,
+  if all operations are correctly performed, with the ratios resulting
+  from the measures. Leaving the base line, the sides increase up to
+  10, 30 or 50 miles occasionally, but seldom reaching 100 miles. The
+  triangulation points may either be natural objects presenting
+  themselves in suitable positions, such as church towers; or they may
+  be objects specially constructed in stone or wood on mountain tops or
+  other prominent ground. In every case it is necessary that the precise
+  centre of the station be marked by some permanent mark. In India no
+  expense is spared in making permanent the principal trigonometrical
+  stations--costly towers in masonry being erected. It is essential that
+  every trigonometrical station shall present a fine object for
+  observation from surrounding stations.
+
+
+  _Horizontal Angles._
+
+  In placing the theodolite over a station to be observed from, the
+  first point to be attended to is that it shall rest upon a perfectly
+  solid foundation. The method of obtaining this desideratum must depend
+  entirely on the nature of the ground; the instrument must if possible
+  be supported on rock, or if that be impossible a solid foundation must
+  be obtained by digging. When the theodolite is required to be raised
+  above the surface of the ground in order to command particular points,
+  it is necessary to build two scaffolds,--the outer one to carry the
+  observatory, the inner one to carry the instrument,--and these two
+  edifices must have no point of contact. Many cases of high scaffolding
+  have occurred on the English Ordnance Survey, as for instance at
+  Thaxted church, where the tower, 80 ft. high, is surmounted by a spire
+  of 90 ft. The scaffold for the observatory was carried from the base
+  to the top of the spire; that for the instrument was raised from a
+  point of the spire 140 ft. above the ground, having its bearing upon
+  timbers passing through the spire at that height. Thus the instrument,
+  at a height of 178 ft. above the ground, was insulated, and not
+  affected by the action of the wind on the observatory.
+
+  At every station it is necessary to examine and correct the
+  adjustments of the theodolite, which are these: the line of
+  collimation of the telescope must be perpendicular to its axis of
+  rotation; this axis perpendicular to the vertical axis of the
+  instrument; and the latter perpendicular to the plane of the horizon.
+  The micrometer microscopes must also measure correct quantities on the
+  divided circle or circles. The method of observing is this. Let A, B,
+  C ... be the stations to be observed taken in order of azimuth; the
+  telescope is first directed to A and the cross-hairs of the telescope
+  made to bisect the object presented by A, then the microscopes or
+  verniers of the horizontal circle (also of the vertical circle if
+  necessary) are read and recorded. The telescope is then turned to B,
+  which is observed in the same manner; then C and the other stations.
+  Coming round by continuous motion to A, it is again observed, and the
+  agreement of this second reading with the first is some test of the
+  stability of the instrument. In taking this round of angles--or "arc,"
+  as it is called on the Ordnance Survey--it is desirable that the
+  interval of time between the first and second observations of A should
+  be as small as may be consistent with due care. Before taking the next
+  arc the horizontal circle is moved through 20 deg. or 30 deg.; thus a
+  different set of divisions of the circle is used in each arc, which
+  tends to eliminate the errors of division.
+
+  It is very desirable that all arcs at a station should contain one
+  point in common, to which all angular measurements are thus
+  referred,--the observations on each arc commencing and ending with
+  this point, which is on the Ordnance Survey called the "referring
+  object." It is usual for this purpose to select, from among the points
+  which have to be observed, that one which affords the best object for
+  precise observation. For mountain tops a "referring object" is
+  constructed of two rectangular plates of metal in the same vertical
+  plane, their edges parallel and placed at such a distance apart that
+  the light of the sky seen through appears as a vertical line about 10"
+  in width. The best distance for this object is from 1 to 2 miles.
+
+  This method seems at first sight very advantageous; but if, however,
+  it be desired to attain the highest accuracy, it is better, as shown
+  by General Schreiber of Berlin in 1878, to measure only single angles,
+  and as many of these as possible between the directions to be
+  determined. Division-errors are thus more perfectly eliminated, and
+  errors due to the variation in the stability, &c., of the instruments
+  are diminished. This method is rapidly gaining precedence.
+
+  The theodolites used in geodesy vary in pattern and in size--the
+  horizontal circles ranging from 10 in. to 36 in. in diameter. In
+  Ramsden's 36-in. theodolite the telescope has a focal length of 36 in.
+  and an aperture of 2.5 in., the ordinarily used magnifying power being
+  54; this last, however, can of course be changed at the requirements
+  of the observer or of the weather. The probable error of a single
+  observation of a fine object with this theodolite is about 0".2. Fig.
+  2 represents an altazimuth theodolite of an improved pattern used on
+  the Ordnance Survey. The horizontal circle of 14-in. diameter is read
+  by three micrometer microscopes; the vertical circle has a diameter of
+  12 in., and is read by two microscopes. In the great trigonometrical
+  survey of India the theodolites used in the more important parts of
+  the work have been of 2 and 3 ft. diameter--the circle read by five
+  equidistant microscopes. Every angle is measured twice in each
+  position of the zero of the horizontal circle, of which there are
+  generally ten; the entire number of measures of an angle is never
+  less than 20. An examination of 1407 angles showed that the probable
+  error of an observed angle is on the average [+-] 0".28.
+
+  For the observations of very distant stations it is usual to employ a
+  heliotrope (from the Gr. [Greek: helios], sun; [Greek: tropos], a
+  turn), invented by Gauss at Gottingen in 1821. In its simplest form
+  this is a plane mirror, 4, 6, or 8 in. in diameter, capable of
+  rotation round a horizontal and a vertical axis. This mirror is placed
+  at the station to be observed, and in fine weather it is kept so
+  directed that the rays of the sun reflected by it strike the distant
+  observing telescope. To the observer the heliotrope presents the
+  appearance of a star of the first or second magnitude, and is
+  generally a pleasant object for observing.
+
+  Observations at night, with the aid of light-signals, have been
+  repeatedly made, and with good results, particularly in France by
+  General Francois Perrier, and more recently in the United States by
+  the Coast and Geodetic Survey; the signal employed being an acetylene
+  bicycle-lamp, with a lens 5 in. in diameter. Particularly noteworthy
+  are the trigonometrical connexions of Spain and Algeria, which were
+  carried out in 1879 by Generals Ibanez and Perrier (over a distance of
+  270 km.), of Sicily and Malta in 1900, and of the islands of Elba and
+  Sardinia in 1902 by Dr Guarducci (over distances up to 230 km.); in
+  these cases artificial light was employed: in the first case electric
+  light and in the two others acetylene lamps.
+
+  [Illustration: FIG. 2.--Altazimuth Theodolite.]
+
+
+  _Astronomical Observations._
+
+  The direction of the meridian is determined either by a theodolite or
+  a portable transit instrument. In the former case the operation
+  consists in observing the angle between a terrestrial
+  object--generally a mark specially erected and capable of illumination
+  at night--and a close circumpolar star at its greatest eastern or
+  western azimuth, or, at any rate, when very near that position. If the
+  observation be made t minutes of time before or after the time of
+  greatest azimuth, the azimuth then will differ from its maximum value
+  by (450t)^2 sin 1" sin 2[delta]/ sin z, in seconds of angle, omitting
+  smaller terms, [delta] being the star's declination and z its zenith
+  distance. The collimation and level errors are very carefully
+  determined before and after these observations, and it is usual to
+  arrange the observations by the reversal of the telescope so that
+  collimation error shall disappear. If b, c be the level and
+  collimation errors, the correction to the circle reading is b cot z
+  [+-] c cosec z, b being positive when the west end of the axis is
+  high. It is clear that any uncertainty as to the real state of the
+  level will produce a corresponding uncertainty in the resulting value
+  of the azimuth,--an uncertainty which increases with the latitude and
+  is very large in high latitudes. This may be partly remedied by
+  observing in connexion with the star its reflection in mercury. In
+  determining the value of "one division" of a level tube, it is
+  necessary to bear in mind that in some the value varies considerably
+  with the temperature. By experiments on the level of Ramsden's 3-foot
+  theodolite, it was found that though at the ordinary temperature of 66
+  deg. the value of a division was about one second, yet at 32 deg. it
+  was about five seconds.
+
+  In a very excellent portable transit used on the Ordnance Survey, the
+  uprights carrying the telescope are constructed of mahogany, each
+  upright being built of several pieces glued and screwed together; the
+  base, which is a solid and heavy plate of iron, carries a reversing
+  apparatus for lifting the telescope out of its bearings, reversing it
+  and letting it down again. Thus is avoided the change of temperature
+  which the telescope would incur by being lifted by the hands of the
+  observer. Another form of transit is the German diagonal form, in
+  which the rays of light after passing through the object-glass are
+  turned by a total reflection prism through one of the transverse arms
+  of the telescope, at the extremity of which arm is the eye-piece. The
+  unused half of the ordinary telescope being cut away is replaced by a
+  counterpoise. In this instrument there is the advantage that the
+  observer without moving the position of his eye commands the whole
+  meridian, and that the level may remain on the pivots whatever be the
+  elevation of the telescope. But there is the disadvantage that the
+  flexure of the transverse axis causes a variable collimation error
+  depending on the zenith distance of the star to which it is directed;
+  and moreover it has been found that in some cases the personal error
+  of an observer is not the same in the two positions of the telescope.
+
+  To determine the direction of the meridian, it is well to erect two
+  marks at nearly equal angular distances on either side of the north
+  meridian line, so that the pole star crosses the vertical of each mark
+  a short time before and after attaining its greatest eastern and
+  western azimuths.
+
+  If now the instrument, perfectly levelled, is adjusted to have its
+  centre wire on one of the marks, then when elevated to the star, the
+  star will traverse the wire, and its exact position in the field at
+  any moment can be measured by the micrometer wire. Alternate
+  observations of the star and the terrestrial mark, combined with
+  careful level readings and reversals of the instrument, will enable
+  one, even with only one mark, to determine the direction of the
+  meridian in the course of an hour with a probable error of less than a
+  second. The second mark enables one to complete the station more
+  rapidly and gives a check upon the work. As an instance, at Findlay
+  Seat, in latitude 57 deg. 35', the resulting azimuths of the two marks
+  were 177 deg. 45' 37".29 [+-] 0".20 and 182 deg. 17' 15".61 [+-] 0".13,
+  while the angle between the two marks directly measured by a
+  theodolite was found to be 4 deg. 31' 37".43 [+-] 0".23.
+
+  [Illustration: FIG. 3.]
+
+  We now come to the consideration of the determination of time with the
+  transit instrument. Let fig. 3 represent the sphere stereographically
+  projected on the plane of the horizon,--ns being the meridian, we the
+  prime vertical, Z, P the zenith and the pole. Let p be the point in
+  which the production of the axis of the instrument meets the celestial
+  sphere, S the position of a star when observed on a wire whose
+  distance from the collimation centre is c. Let a be the azimuthal
+  deviation, namely, the angle wZp, b the level error so that Zp = 90
+  deg. - b. Let also the hour angle corresponding to p be 90 deg. - n,
+  and the declination of the same = m, the star's declination being
+  [delta], and the latitude [phi]. Then to find the hour angle ZPS =
+  [tau] of the star when observed, in the triangles pPS, pPZ we have,
+  since pPS = 90 + [tau] - n,
+
+         -Sin c = sin m sin [delta] + cos m cos [delta] sin (n - [tau]),
+          Sin m = sin b sin [phi]   - cos b cos [phi] sin a,
+    Cos m sin n = sin b cos [phi]   + cos b sin [phi] sin a.
+
+  And these equations solve the problem, however large be the errors of
+  the instrument. Supposing, as usual, a, b, m, n to be small, we have
+  at once [tau] = n + c sec [delta] + m tan [delta], which is the
+  correction to the observed time of transit. Or, eliminating m and n by
+  means of the second and third equations, and putting z for the zenith
+  distance of the star, t for the observed time of transit, the
+  corrected time is t + (a sin z + b cos z + c) / cos [delta]. Another
+  very convenient form for stars near the zenith is [tau] = b sec [phi]
+  + c sec [delta] + m (tan [delta] - tan [phi]).
+
+  Suppose that in commencing to observe at a station the error of the
+  chronometer is not known; then having secured for the instrument a
+  very solid foundation, removed as far as possible level and
+  collimation errors, and placed it by estimation nearly in the
+  meridian, let two stars differing considerably in declination be
+  observed--the instrument not being reversed between them. From these
+  two stars, neither of which should be a close circumpolar star, a good
+  approximation to the chronometer error can be obtained; thus let
+  [epsilon]1, [epsilon]2, be the apparent clock errors given by these
+  stars if [delta]1, [delta]2 be their declinations the real error is
+
+    [epsilon] = [epsilon]1 + ([epsilon]1 - [epsilon]2)
+      (tan [phi] - tan [delta]1) / (tan [delta]1 - tan [delta]2).
+
+  Of course this is still only approximate, but it will enable the
+  observer (who by the help of a table of natural tangents can compute
+  [epsilon] in a few minutes) to find the meridian by placing at the
+  proper time, which he now knows approximately, the centre wire of his
+  instrument on the first star that passes--not near the zenith.
+
+  The transit instrument is always reversed at least once in the course
+  of an evening's observing, the level being frequently read and
+  recorded. It is necessary in most instruments to add a correction for
+  the difference in size of the pivots.
+
+  The transit instrument is also used in the prime vertical for the
+  determination of latitudes. In the preceding figure let q be the point
+  in which the northern extremity of the axis of the instrument produced
+  meets the celestial sphere. Let nZq be the azimuthal deviation = a,
+  and b being the level error, Zq = 90 deg. - b; let also nPq = [tau]
+  and Pq = [psi]. Let S' be the position of a star when observed on a
+  wire whose distance from the collimation centre is c, positive when to
+  the south, and let h be the observed hour angle of the star, viz.
+  ZPS'. Then the triangles qPS', gPZ give
+
+    -Sin c = sin [delta] cos [psi] - cos [delta] sin [psi] cos (h + [tau]),
+     Cos [psi] = sin b sin [phi] + cos b cos [phi] cos a,
+     Sin [psi] sin [tau] = cos b sin a.
+
+  Now when a and b are very small, we see from the last two equations
+  that [psi] = [phi] - b, a = [tau] sin [psi], and if we calculate
+  [phi]' by the formula cot [phi]' = cot [delta] cos h, the first
+  equation leads us to this result--
+
+    [phi] = [phi]' + (a sin z + b cos z + c)/cos z,
+
+  the correction for instrumental error being very similar to that
+  applied to the observed time of transit in the case of meridian
+  observations. When a is not very small and z is small, the formulae
+  required are more complicated.
+
+  [Illustration: FIG. 4.--Zenith Telescope constructed for the
+  International Stations at Mizusawa, Carloforte, Gaithersburg and
+  Ukiah, by Hermann Wanschaff, Berlin.]
+
+  The method of determining latitude by transits in the prime vertical
+  has the disadvantage of being a somewhat slow process, and of
+  requiring a very precise knowledge of the time, a disadvantage from
+  which the zenith telescope is free. In principle this instrument is
+  based on the proposition that when the meridian zenith distances of
+  two stars at their upper culminations--one being to the north and the
+  other to the south of the zenith--are equal, the latitude is the mean
+  of their declinations; or, if the zenith distance of a star
+  culminating to the south of the zenith be Z, its declination being
+  [delta], and that of another culminating to the north with zenith
+  distance Z' and declination [delta]', then clearly the latitude is
+  1/2([delta] + [delta]') + 1/2(Z - Z'). Now the zenith telescope does
+  away with the divided circle, and substitutes the measurement
+  micrometrically of the quantity Z' - Z.
+
+  In fig. 4 is shown a zenith telescope by H. Wanschaff of Berlin, which
+  is the type used (according to the Central Bureau at Potsdam) since
+  about 1890 for the determination of the variations of latitude due to
+  different, but as yet imperfectly understood, influences. The
+  instrument is supported on a strong tripod, fitted with levelling
+  screws; to this tripod is fixed the azimuth circle and a long vertical
+  steel axis. Fitting on this axis is a hollow axis which carries on its
+  upper end a short transverse horizontal axis with a level. This latter
+  carries the telescope, which, supported at the centre of its length,
+  is free to rotate in a vertical plane. The telescope is thus mounted
+  eccentrically with respect to the vertical axis around which it
+  revolves. Two extremely sensitive levels are attached to the
+  telescope, which latter carries a micrometer in its eye-piece, with a
+  screw of long range for measuring differences of zenith distance. Two
+  levels are employed for controlling and increasing the accuracy. For
+  this instrument stars are selected in pairs, passing north and south
+  of the zenith, culminating within a few minutes of time and within
+  about twenty minutes (angular) of zenith distance of each other. When
+  a pair of stars is to be observed, the telescope is set to the mean of
+  the zenith distances and in the plane of the meridian. The first star
+  on passing the central meridional wire is bisected by the micrometer;
+  then the telescope is rotated very carefully through 180 deg. round
+  the vertical axis, and the second star on passing through the field is
+  bisected by the micrometer on the centre wire. The micrometer has thus
+  measured the difference of the zenith distances, and the calculation
+  to get the latitude is most simple. Of course it is necessary to read
+  the level, and the observations are not necessarily confined to the
+  centre wire. In fact if n, s be the north and south readings of the
+  level for the south star, n', s' the same for the north star, l the
+  value of one division of the level, m the value of one division of the
+  micrometer, r, r' the refraction corrections, [mu], [mu]' the
+  micrometer readings of the south and north star, the micrometer being
+  supposed to read from the zenith, then, supposing the observation made
+  on the centre wire,--
+
+    [phi] = 1/2([delta] + [delta]') + 1/2([mu] - [mu]')m + 1/4(n + n' - s - s')l +
+      1/2(r - r').
+
+  It is of course of the highest importance that the value m of the
+  screw be well determined. This is done most effectually by observing
+  the vertical movement of a close circumpolar star when at its greatest
+  azimuth.
+
+  In a single night with this instrument a very accurate result, say
+  with a probable error of about 0".2, could be obtained for latitude
+  from, say, twenty pair of stars; but when the latitude is required to
+  be obtained with the highest possible precision, two nights at least
+  are necessary. The weak point of the zenith telescope lies in the
+  circumstance that its requirements prevent the selection of stars
+  whose positions are well fixed; very frequently it is necessary to
+  have the declinations of the stars selected for this instrument
+  specially observed at fixed observatories. The zenith telescope is
+  made in various sizes from 30 to 54 in. in focal length; a 30-in.
+  telescope is sufficient for the highest purposes and is very portable.
+  The net observation probable-error for one pair of stars is only
+  [+-]0".1.
+
+  The zenith telescope is a particularly pleasant instrument to work
+  with, and an observer has been known (a sergeant of Royal Engineers,
+  on one occasion) to take every star in his list during eleven hours on
+  a stretch, namely, from 6 o'clock P.M. until 5 A.M., and this on a
+  very cold November night on one of the highest points of the
+  Grampians. Observers accustomed to geodetic operations attain
+  considerable powers of endurance. Shortly after the commencement of
+  the observations on one of the hills in the Isle of Skye a storm
+  carried away the wooden houses of the men and left the observatory
+  roofless. Three observatory roofs were subsequently demolished, and
+  for some time the observatory was used without a roof, being filled
+  with snow every night and emptied every morning. Quite different,
+  however, was the experience of the same party when on the top of Ben
+  Nevis, 4406 ft. high. For about a fortnight the state of the
+  atmosphere was unusually calm, so much so, that a lighted candle could
+  often be carried between the tents of the men and the observatory,
+  whilst at the foot of the hill the weather was wild and stormy.
+
+  The determination of the difference of longitude between two stations
+  A and B resolves itself into the determination of the local time at
+  each of the stations, and the comparison by signals of the clocks at A
+  and B. Whenever telegraphic lines are available these comparisons are
+  made by telegraphy. A small and delicately-made apparatus introduced
+  into the mechanism of an astronomical clock or chronometer breaks or
+  closes by the action of the clock an electric circuit every second. In
+  order to record the minutes as well as seconds, one second in each
+  minute, namely that numbered 0 or 60, is omitted. The seconds are
+  recorded on a chronograph, which consists of a cylinder revolving
+  uniformly at the rate of one revolution per minute covered with white
+  paper, on which a pen having a slow movement in the direction of the
+  axis of the cylinder describes a continuous spiral. This pen is
+  deflected through the agency of an electromagnet every second, and
+  thus the seconds of the clock are recorded on the chronograph by
+  offsets from the spiral curve. An observer having his hand on a
+  contact key in the same circuit can record in the same manner his
+  observed times of transits of stars. The method of determination of
+  difference of longitude is, therefore, virtually as follows. After the
+  necessary observations for instrumental corrections, which are
+  recorded only at the station of observation, the clock at A is put in
+  connexion with the circuit so as to write on both chronographs,
+  namely, that at A and that at B. Then the clock at B is made to write
+  on both chronographs. It is clear that by this double operation one
+  can eliminate the effect of the small interval of time consumed in the
+  transmission of signals, for the difference of longitude obtained from
+  the one chronograph will be in excess by as much as that obtained from
+  the other will be in defect. The determination of the personal errors
+  of the observers in this delicate operation is a matter of the
+  greatest importance, as therein lies probably the chief source of
+  residual error.
+
+  These errors can nevertheless be almost entirely avoided by using the
+  impersonal micrometer of Dr Repsold (Hamburg, 1889). In this device
+  there is a movable micrometer wire which is brought by hand into
+  coincidence with the star and moved along with it; at fixed points
+  there are electrical contacts, which replace the fixed wires.
+  Experiments at the Geodetic Institute and Central Bureau at Potsdam in
+  1891 gave the following personal equations in the case of four
+  observers:--
+
+          Older Procedure.   New Procedure.
+
+    A-B      -0^s.108          -0^s.004
+    A-G      -0^s.314          -0^s.035
+    A-S      -0^s.184          -0^s.027
+    B-G      -0^s.225          +0^s.013
+    B-S      -0^s.086          -0^s.023
+    G-S      +0^s.109          -0^s.006
+
+  These results show that in the later method the personal equation is
+  small and not so variable; and consequently the repetition of
+  longitude determinations with exchanged observers and apparatus
+  entirely eliminates the constant errors, the probable error of such
+  determinations on ten nights being scarcely [+-]0^s.01.
+
+
+  _Calculation of Triangulation._
+
+  The surface of Great Britain and Ireland is uniformly covered by
+  triangulation, of which the sides are of various lengths from 10 to
+  111 miles. The largest triangle has one angle at Snowdon in Wales,
+  another on Slieve Donard in Ireland, and a third at Scaw Fell in
+  Cumberland; each side is over a hundred miles and the spherical excess
+  is 64". The more ordinary method of triangulation is, however, that of
+  chains of triangles, in the direction of the meridian and
+  perpendicular thereto. The principal triangulations of France, Spain,
+  Austria and India are so arranged. Oblique chains of triangles are
+  formed in Italy, Sweden and Norway, also in Germany and Russia, and in
+  the United States. Chains are composed sometimes merely of consecutive
+  plain triangles; sometimes, and more frequently in India, of
+  combinations of triangles forming consecutive polygonal figures. In
+  this method of triangulating, the sides of the triangles are generally
+  from 20 to 30 miles in length--seldom exceeding 40.
+
+  The inevitable errors of observation, which are inseparable from all
+  angular as well as other measurements, introduce a great difficulty
+  into the calculation of the sides of a triangulation. Starting from a
+  given base in order to get a required distance, it may generally be
+  obtained in several different ways--that is, by using different sets
+  of triangles. The results will certainly differ one from another, and
+  probably no two will agree. The experience of the computer will then
+  come to his aid, and enable him to say which is the most trustworthy
+  result; but no experience or ability will carry him through a large
+  network of triangles with anything like assurance. The only way to
+  obtain trustworthy results is to employ the method of least squares.
+  We cannot here give any illustration of this method as applied to
+  general triangulation, for it is most laborious, even for the simplest
+  cases.
+
+  Three stations, projected on the surface of the sea, give a spherical
+  or spheroidal triangle according to the adoption of the sphere or the
+  ellipsoid as the form of the surface. A spheroidal triangle differs
+  from a spherical triangle, not only in that the curvatures of the
+  sides are different one from another, but more especially in this
+  that, while in the spherical triangle the normals to the surface at
+  the angular points meet at the centre of the sphere, in the spheroidal
+  triangle the normals at the angles A, B, C meet the axis of revolution
+  of the spheroid in three different points, which we may designate
+  [alpha], [beta], [gamma] respectively. Now the angle A of the triangle
+  as measured by a theodolite is the inclination of the planes BA[alpha]
+  and CA[alpha], and the angle at B is that contained by the planes
+  AB[beta] and CB[beta]. But the planes AB[alpha] and AB[beta]
+  containing the line AB in common cut the surface in two distinct plane
+  curves. In order, therefore, that a spheroidal triangle may be exactly
+  defined, it is necessary that the nature of the lines joining the
+  three vertices be stated. In a mathematical point of view the most
+  natural definition is that the sides be geodetic or shortest lines.
+  C.C.G. Andrae, of Copenhagen, has also shown that other lines give a
+  less convenient computation.
+
+  K.F. Gauss, in his treatise, _Disquisitiones generales circa
+  superficies curvas_, entered fully into the subject of geodetic (or
+  geodesic) triangles, and investigated expressions for the angles of a
+  geodetic triangle whose sides are given, not certainly finite
+  expressions, but approximations inclusive of small quantities of the
+  fourth order, the side of the triangle or its ratio to the radius of
+  the nearly spherical surface being a small quantity of the first
+  order. The terms of the fourth order, as given by Gauss for any
+  surface in general, are very complicated even when the surface is a
+  spheroid. If we retain small quantities of the second order only, and
+  put [A], [B], [C] for the angles of the geodetic triangle, while A, B,
+  C are those of a plane triangle having sides equal respectively to
+  those of the geodetic triangle, then, [sigma] being the area of the
+  plane triangle and [a], [b], [c] the measures of curvature at the
+  angular points,
+
+    [A] = A + [sigma](2[a] + [b] + [c])/12,
+    [B] = B + [sigma]([a] + 2[b] + [c])/12,
+    [C] = C + [sigma]([a] + [b] + 2[c])/12.
+
+  For the sphere [a] = [b] = [r], and making this simplification, we
+  obtain the theorem previously given by A.M. Legendre. With the terms
+  of the fourth order, we have (after Andrae):
+
+              [epsilon]   [sigma]   /m^2 - a^2    [a] - k \
+    [A] - A = --------- + -------k ( ---------k + -------  ),
+                  3          3      \    20          4k   /
+
+              [epsilon]   [sigma]   /m^2 - b^2    [b] - k \
+    [B] - B = --------- + -------k ( ---------k + -------- ),
+                  3          3      \    20          4k   /
+
+              [epsilon]   [sigma]   /m^2 - c^2    [c] - k \
+    [C] - C = --------- + -------k ( ---------k + -------- ),
+                  3          3      \    20          4k   /
+
+  in which [epsilon] = [sigma] k {1 + (m^2k / 8)}, 3m^2 = a^2 + b^2 +
+  c^2, 3k = [a] + [b] + [c]. For the ellipsoid of rotation the measure
+  of curvature is equal to 1 / [rho]n, [rho] and n being the radii of
+  curvature of the meridian and perpendicular.
+
+  It is rarely that the terms of the fourth order are required. As a
+  rule spheroidal triangles are calculated as spherical (after
+  Legendre), i.e. like plane triangles with a decrease of each angle of
+  about [epsilon] / 3; [epsilon] must, however, be calculated for each
+  triangle separately with its mean measure of curvature k.
+
+  The geodetic line being the shortest that can be drawn on any surface
+  between two given points, we may be conducted to its most important
+  characteristics by the following considerations: let p, q be adjacent
+  points on a curved surface; through s the middle point of the chord pq
+  imagine a plane drawn perpendicular to pq, and let S be any point in
+  the intersection of this plane with the surface; then pS + Sq is
+  evidently least when sS is a minimum, which is when sS is a normal to
+  the surface; hence it follows that of all plane curves on the surface
+  joining p, q, when those points are indefinitely near to one another,
+  that is the shortest which is made by the normal plane. That is to
+  say, the osculating plane at any point of a geodetic line contains the
+  normal to the surface at that point. Imagine now three points in
+  space, A, B, C, such that AB = BC = c; let the direction cosines of AB
+  be l, m, n, those of BC l', m', n', then x, y, z being the
+  co-ordinates of B, those of A and C will be respectively--
+
+    x - cl : y - cm : z - cn
+    x + cl': y + cm': z + cn'.
+
+  Hence the co-ordinates of the middle point M of AC are x + 1/2c(l' - l),
+  y + 1/2c(m' - m), z + 1/2c(n' - n), and the direction cosines of BM are
+  therefore proportional to l' - l : m' - m : n' - n. If the angle made
+  by BC with AB be indefinitely small, the direction cosines of BM are
+  as [delta]l : [delta]m : [delta]n. Now if AB, BC be two contiguous
+  elements of a geodetic, then BM must be a normal to the surface, and
+  since [delta]l, [delta]m, [delta]n are in this case represented by
+  [delta](dx/ds), [delta](dy/ds), [delta](dz/ds), and if the equation of
+  the surface be u = 0, we have
+
+    d^2x   / du   d^2y   / du   d^2z   / du
+    ----  /  -- = ----  /  -- = ----  /  --,
+    ds^2 /   dx   ds^2 /   dy   ds^2 /   dz
+
+  which, however, are equivalent to only one equation. In the case of
+  the spheroid this equation becomes
+
+      d^2x     d^2y
+    y ---- - x ---- = 0,
+      ds^2     ds^2
+
+  which integrated gives ydx - xdy = Cds. This again may be put in the
+  form r sin a = C, where a is the azimuth of the geodetic at any
+  point--the angle between its direction and that of the meridian--and r
+  the distance of the point from the axis of revolution.
+
+  From this it may be shown that the azimuth at A of the geodetic
+  joining AB is not the same as the astronomical azimuth at A of B or
+  that determined by the vertical plane A[alpha]B. Generally speaking,
+  the geodetic lies between the two plane section curves joining A and B
+  which are formed by the two vertical planes, supposing these points
+  not far apart. If, however, A and B are nearly in the same latitude,
+  the geodetic may cross (between A and B) that plane curve which lies
+  nearest the adjacent pole of the spheroid. The condition of crossing
+  is this. Suppose that for a moment we drop the consideration of the
+  earth's non-sphericity, and draw a perpendicular from the pole C on
+  AB, meeting it in S between A and B. Then A being that point which is
+  nearest the pole, the geodetic will cross the plane curve if AS be
+  between 1/4AB and 3/8 AB. If AS lie between this last value and 1/2AB,
+  the geodetic will lie wholly to the north of both plane curves, that
+  is, supposing both points to be in the northern hemisphere.
+
+  The difference of the azimuths of the vertical section AB and of the
+  geodetic AB, i.e. the astronomical and geodetic azimuths, is very
+  small for all observable distances, being approximately:--
+
+  Geod. azimuth = Astr. azimuth -(1/12) [e^2/(1 - e^2)] (s^2/[rho]n)
+  (cos^2[phi] sin 2[alpha] + (s/4a)|sin 2[phi] sin [alpha]), in which: e
+  and a are the numerical eccentricity and semi-major axis respectively
+  of the meridian ellipse, [phi] and [alpha] are the latitude and
+  azimuth at A, s = AB, and [rho] and n are the radii of curvature of
+  the meridian and perpendicular at A. For s = 100 kilometres, only the
+  first term is of moment; its value is 0".028 cos^2 [phi] sin 2[alpha],
+  and it lies well within the errors of observation. If we imagine the
+  geodetic AB, it will generally trisect the angles between the vertical
+  sections at A and B, so that the geodetic at A is near the vertical
+  section AB, and at B near the section BA.[3] The greatest distance of
+  the vertical sections one from another is e^2s^3 cos^2 [phi]0 sin
+  2[alpha]0/16a^2, in which [phi]0 and [alpha]0 are the mean latitude
+  and azimuth respectively of the middle point of AB. For the value s =
+  64 kilometres, the maximum distance is 3 mm.
+
+  An idea of the course of a longer geodetic line may be gathered from
+  the following example. Let the line be that joining Cadiz and St
+  Petersburg, whose approximate positions are--
+
+        Cadiz.               St Petersburg.
+    Lat. 36 deg. 22' N.      59 deg. 56' N.
+    Long. 6 deg. 18' W.      30 deg. 17' E.
+
+  If G be the point on the geodetic corresponding to F on that one of
+  the plane curves which contains the normal at Cadiz (by
+  "corresponding" we mean that F and G are on a meridian) then G is to
+  the north of F; at a quarter of the whole distance from Cadiz GF is
+  458 ft., at half the distance it is 637 ft., and at three-quarters it
+  is 473 ft. The azimuth of the geodetic at Cadiz differs 20" from that
+  of the vertical plane, which is the astronomical azimuth.
+
+  The azimuth of a geodetic line cannot be observed, so that the line
+  does not enter of necessity into practical geodesy, although many
+  formulae connected with its use are of great simplicity and elegance.
+  The geodetic line has always held a more important place in the
+  science of geodesy among the mathematicians of France, Germany and
+  Russia than has been assigned to it in the operations of the English
+  and Indian triangulations. Although the observed angles of a
+  triangulation are not geodetic angles, yet in the calculation of the
+  distance and reciprocal bearings of two points which are far apart,
+  and are connected by a long chain of triangles, we may fall upon the
+  geodetic line in this manner:--
+
+  If A, Z be the points, then to start the calculation from A, we obtain
+  by some preliminary calculation the approximate azimuth of Z, or the
+  angle made by the direction of Z with the side AB or AC of the first
+  triangle. Let P1 be the point where this line intersects BC; then, to
+  find P2, where the line cuts the next triangle side CD, we make the
+  angle BP1P2 such that BP1P2 + BP1A = 180 deg. This fixes P2, and P3 is
+  fixed by a repetition of the same process; so for P4, P5 .... Now it
+  is clear that the points P1, P2, P3 so computed are those which would
+  be actually fixed by an observer with a theodolite, proceeding in the
+  following manner. Having set the instrument up at A, and turned the
+  telescope in the direction of the computed bearing, an assistant
+  places a mark P1 on the line BC, adjusting it till bisected by the
+  cross-hairs of the telescope at A. The theodolite is then placed over
+  P1, and the telescope turned to A; the horizontal circle is then moved
+  through 180 deg. The assistant then places a mark P2 on the line CD,
+  so as to be bisected by the telescope, which is then moved to P2, and
+  in the same manner P3 is fixed. Now it is clear that the series of
+  points P1, P2, P3 approaches to the geodetic line, for the plane of
+  any two consecutive elements P_(n-1) P_n, P_n P_(n+1) contains the
+  normal at P_n.
+
+  If the objection be raised that not the geodetic azimuths but the
+  astronomical azimuths are observed, it is necessary to consider that
+  the observed vertical sections do not correspond to points on the
+  sea-level but to elevated points. Since the normals of the ellipsoid
+  of rotation do not in general intersect, there consequently arises an
+  influence of the height on the azimuth. In the case of the measurement
+  of the azimuth from A to B, the instrument is set to a point A' over
+  the surface of the ellipsoid (the sea-level), and it is then adjusted
+  to a point B', also over the surface, say at a height h'. The vertical
+  plane containing A' and B' also contains A but not B: it must
+  therefore be rotated through a small azimuth in order to contain B.
+  The correction amounts approximately to -e^2h' cos^2[phi] sin
+  2[alpha]/2a; in the case of h' = 1000 m., its value is 0".108
+  cos^2[phi] sin 2[alpha].
+
+  This correction is therefore of greater importance in the case of
+  observed azimuths and horizontal angles than in the previously
+  considered case of the astronomical and the geodetic azimuths. The
+  observed azimuths and horizontal angles must therefore also be
+  corrected in the case, where it is required to dispense with geodetic
+  lines.
+
+  When the angles of a triangulation have been adjusted by the method of
+  least squares, and the sides are calculated, the next process is to
+  calculate the latitudes and longitudes of all the stations starting
+  from one given point. The calculated latitudes, longitudes and
+  azimuths, which are designated geodetic latitudes, longitudes and
+  azimuths, are not to be confounded with the observed latitudes,
+  longitudes and azimuths, for these last are subject to somewhat large
+  errors. Supposing the latitudes of a number of stations in the
+  triangulation to be observed, practically the mean of these determines
+  the position in latitude of the network, taken as a whole. So the
+  orientation or general azimuth of the whole is inferred from all the
+  azimuth observations. The triangulation is then supposed to be
+  projected on a spheroid of given elements, representing as nearly as
+  one knows the real figure of the earth. Then, taking the latitude of
+  one point and the direction of the meridian there as given--obtained,
+  namely, from the astronomical observations there--one can compute the
+  latitudes of all the other points with any degree of precision that
+  may be considered desirable. It is necessary to employ for this
+  purpose formulae which will give results true even for the longest
+  distances to the second place of decimals of seconds, otherwise there
+  will arise an accumulation of errors from imperfect calculation which
+  should always be avoided. For very long distances, eight places of
+  decimals should be employed in logarithmic calculations; if seven
+  places only are available very great care will be required to keep the
+  last place true. Now let [phi], [phi]' be the latitudes of two
+  stations A and B; [alpha], [alpha]^* their mutual azimuths counted
+  from north by east continuously from 0 deg. to 360 deg.; [omega] their
+  difference of longitude measured from west to east; and s the distance
+  AB.
+
+  First compute a latitude [phi]1 by means of the formula [phi]1 = [phi]
+  + (s cos [alpha]) / [rho], where [rho] is the radius of curvature of
+  the meridian at the latitude [phi]; this will require but four places
+  of logarithms. Then, in the first two of the following, five places
+  are sufficient--
+
+                  s^2                                  s^2
+    [epsilon] = ------- sin [alpha] cos a,   [eta] = ------- sin^2[alpha] tan[phi]1,
+                2[rho]n                              2[rho]n
+
+                      s
+    [phi]' - [phi] = ---- cos ([alpha] - 2/3[epsilon]) - [eta],
+                     rho0
+
+              s sin (alpha - 1/3[epsilon])
+    [omega] = ----------------------------,
+               n cos ([phi]' + 1/3[eta])
+
+    [alpha]^* - [alpha] = [omega] sin ([phi]' + 2/3[eta]) - [epsilon] + 180 deg.
+
+  Here n is the normal or radius of curvature perpendicular to the
+  meridian; both n and [rho] correspond to latitude [phi]1, and [rho]0
+  to latitude 1/2([phi] + [phi]'). For calculations of latitude and
+  longitude, tables of the logarithmic values of [rho] sin 1", n sin 1",
+  and 2 n [rho] sin 1" are necessary. The following table contains these
+  logarithms for every ten minutes of latitude from 52 deg. to 53 deg.
+  computed with the elements a = 20926060 and a : b = 295 : 294 :--
+
+    +------+------------------+--------------+--------------------+
+    |      |          1       |        1     |           1        |
+    | Lat. | Log.------------.| Log.--------.| Log.--------------.|
+    |      |     [rho] sin 1" |     n sin 1" |     2[rho]n sin 1" |
+    +------+------------------+--------------+--------------------+
+    |deg. '|                  |              |                    |
+    |52  0 |    7.9939434     |  7.9928231   |      0.37131       |
+    |   10 |         9309     |       8190   |           29       |
+    |   20 |         9185     |       8148   |           28       |
+    |   30 |         9060     |       8107   |           26       |
+    |   40 |         8936     |       8065   |           24       |
+    |   50 |         8812     |       8024   |           23       |
+    |53  0 |         8688     |       7982   |           22       |
+    +------+------------------+--------------+--------------------+
+
+  The logarithm in the last column is that required also for the
+  calculation of spherical excesses, the spherical excess of a triangle
+  being expressed by a b sin (C/2[rho]n) sin 1".
+
+  It is frequently necessary to obtain the co-ordinates of one point
+  with reference to another point; that is, let a perpendicular arc be
+  drawn from B to the meridian of A meeting it in P, then, [alpha] being
+  the azimuth of B at A, the co-ordinates of B with reference to A are
+
+    AP = s cos ([alpha] - 2/3[epsilon]), BP = s sin ([alpha] -
+      1/3[epsilon]),
+
+  where [epsilon] is the spherical excess of APB, viz. s^2 sin [alpha]
+  cos [alpha] multiplied by the quantity whose logarithm is in the
+  fourth column of the above table.
+
+  If it be necessary to determine the geographical latitude and
+  longitude as well as the azimuths to a greater degree of accuracy than
+  is given by the above formulae, we make use of the following formula:
+  given the latitude [phi] of A, and the azimuth [alpha] and the
+  distance s of B, to determine the latitude [phi]' and longitude
+  [omega] of B, and the back azimuth [alpha]'. Here it is understood
+  that [alpha]' is symmetrical to [alpha], so that [alpha]^* + [alpha]'
+  = 360 deg.
+
+  Let
+
+    [theta] = s [Delta] / a, where [Delta] = (1 - e^2 sin^2 [phi])^1/2
+
+  and
+
+           e^2 [theta]^2
+    [xi] = -------------  cos^2 [phi] sin 2[alpha],
+           (4 (1 - e^2)
+
+            e^2 [theta]^3
+    [xi]' = ------------- cos^2 [phi] cos^2 [alpha];
+            (6 (1 - e^2)
+
+  [xi], [xi]' are always very minute quantities even for the longest
+  distances; then, putting [kappa] = 90 deg. - [phi],
+
+       [alpha]' + [xi] - [omega]   sin 1/2([kappa] - [theta] - [xi]')     [alpha]
+    tan------------------------- = ---------------------------------- cot -------
+                   2               sin 1/2([kappa] + [theta] + [xi]')        2
+
+       [alpha]' + [xi] + [omega]   cos 1/2([kappa] - [theta] - [xi]')     [alpha]
+    tan------------------------- = ---------------------------------- cot -------
+                   2               cos 1/2([kappa] + [theta] + [xi]')        2
+
+                        s sin 1/2([alpha]' + [xi] - [alpha])    /    [theta]^2      [alpha]' - [alpha]\
+    [phi]' - [phi] = ----------------------------------------- ( 1 + ---------cos^2 ------------------ );
+                     [rho]0 sin 1/2([alpha]' + [xi] + [alpha])  \       12                   2        /
+
+  here [rho]0 is the radius of curvature of the meridian for the mean
+  latitude 1/2([phi] + [phi]'). These formulae are approximate only, but
+  they are sufficiently precise even for very long distances.
+
+  For lines of any length the formulae of F.W. Bessel (_Astr. Nach._,
+  1823, iv. 241) are suitable.
+
+  If the two points A and B be defined by their geographical
+  co-ordinates, we can accurately calculate the corresponding
+  astronomical azimuths, i.e. those of the vertical section, and then
+  proceed, in the case of not too great distances, to determine the
+  length and the azimuth of the shortest lines. For _any_ distances
+  recourse must again be made to Bessel's formula.[4]
+
+  Let [alpha], [alpha]' be the mutual azimuths of two points A, B on a
+  spheroid, k the chord line joining them, [mu], [mu]' the angles made
+  by the chord with the normals at A and B, [phi], [phi]', [omega] their
+  latitudes and difference of longitude, and (x^2 + y^2)/a^2 + z^2 b^2 =
+  1 the equation of the surface; then if the plane xz passes through A
+  the co-ordinates of A and B will be
+
+    x = (a/[Delta]) cos [phi], x' = (a/[Delta]') cos [phi]' cos [omega],
+
+    y = 0                      y' = (a/[Delta]') cos [phi]' sin [omega],
+
+    z = (a/[Delta]) (1 - e^2) sin [phi], z' = (a/[Delta]') (1 - e^2) sin [phi]',
+
+  where [Delta] = (1 - e^2 sin^2 [phi])^1/2, [Delta]' = (1 - e^2 sin^2
+  [phi]')^1/2, and e is the eccentricity. Let f, g, h be the direction
+  cosines of the normal to that plane which contains the normal at A and
+  the point B, and whose inclinations to the meridian plane of A is =
+  [alpha]; let also l, m, n and l', m', n' be the direction cosines of
+  the normal at A, and of the tangent to the surface at A which lies in
+  the plane passing through B, then since the first line is
+  perpendicular to each of the other two and to the chord k, whose
+  direction cosines are proportional to x' - x, y' - y, z' - z, we have
+  these three equations
+
+    f(x' - x) + gy' + h(z' - z) = 0
+
+                fl + gm + hn    = 0
+
+                fl' + gm' + hn' = 0.
+
+  Eliminate f, g, h from these equations, and substitute
+
+    l = cos [phi]   l' = - sin [phi] cos [alpha]
+
+    m = 0           m' = sin [alpha]
+
+    n = sin [phi]   n' = cos [phi] cos [alpha],
+
+  and we get
+
+    (x' - x) sin [phi] + y' cot [alpha] - (z' - z) cos [phi] = 0.
+
+  The substitution of the values of x, z, x', y', z' in this equation
+  will give immediately the value of cot [alpha]; and if we put [zeta],
+  [zeta]' for the corresponding azimuths on a sphere, or on the
+  supposition e = 0, the following relations exist
+
+                                      cos [phi] Q
+    cot [alpha] - cot [zeta] = e^2 ------------------
+                                   cos [phi]' [Delta]
+
+                                        cos [phi]' Q
+    cot [alpha]' - cot [zeta]' = e^2 ------------------
+                                     cos [phi] [Delta]'
+
+    [Delta]' sin [phi] - [Delta] sin [phi]' = Q sin [omega].
+
+  If from B we let fall a perpendicular on the meridian plane of A, and
+  from A let fall a perpendicular on the meridian plane of B, then the
+  following equations become geometrically evident:
+
+    k sin [mu] sin [alpha] = (a/[Delta]') cos [phi]' sin [omega]
+
+    k sin [mu]' sin [alpha]' = (a/[Delta]) cos [phi] sin [omega].
+
+  Now in any surface u = 0 we have
+
+    k^2 = (x' - x)^2 + (y' - y)^2 + (z' - z)^2
+                  _                                      _
+                 |         du            du            du |  /   / du^2   du^2   du^2 \ 1/2
+    -cos [mu] =  |(x' - x) -- + (y' - y) -- + (z' - z) -- | / k (  ---- + ---- + ----  )
+                 |_        dx            dy            dz_|/     \ dx^2   dy^2   dz^2 /
+                  _                                         _
+                 |         du             du             du  |  /   / du^2    du^2    du^2  \ 1/2
+    -cos [mu]' = |(x' - x) --- + (y' - y) --- + (z' - z) --- | / k (  ----- + ----- + -----  ).
+                 |_        dx'            dy'            dz'_|/     \ dx'^2   dy'^2   dz'^2 /
+
+  In the present case, if we put
+
+        xx'   zz'
+    1 - --- - --- = U,
+        a^2   b^2
+
+  then
+
+    k^2             /z' - z \ ^2
+    --- = 2U - e^2 ( ------  )
+    a^2             \   b   /
+
+    cos [mu] = (a/k) [Delta]U; cos [mu]' = (a/k) [Delta]'U.
+
+  Let u be such an angle that
+
+    (1 - e^2)^1/2 sin [phi] = [Delta] sin u
+
+               cos [phi] = [Delta] cos u,
+
+  then on expressing x, x', z, z' in terms of u and u',
+
+    U = 1 - cos u cos u' cos [omega] - sin u sin u';
+
+  also, if v be the third side of a spherical triangle, of which two
+  sides are 1/2[pi] - u and 1/2[pi] - u' and the included angle [omega],
+  using a subsidiary angle [psi] such that
+
+    sin [psi] sin 1/2v = e sin 1/2(u' - u) cos 1/2(u' + u),
+
+  we obtain finally the following equations:--
+
+                      k = 2a cos [psi] sin 1/2v
+
+                  cos [mu] = [Delta] sec [psi] sin 1/2v
+
+                 cos [mu]' = [Delta]' sec [psi] sin 1/2v
+
+      sin [mu] sin [alpha] = (a/k) cos u' sin [omega]
+
+    sin [mu]' sin [alpha]' = (a/k) cos u sin [omega].
+
+  These determine rigorously the distance, and the mutual zenith
+  distances and azimuths, of any two points on a spheroid whose
+  latitudes and difference of longitude are given.
+
+  By a series of reductions from the equations containing [zeta],
+  [zeta]' it may be shown that
+
+    [alpha] + [alpha]' = [zeta] + [zeta]' + 1/4e^4[omega]([phi]' - [phi])^2
+      cos^4 [phi]0 sin [phi]0 + ...,
+
+  where [phi]0 is the mean of [phi] and [phi]', and the higher powers of
+  e are neglected. A short computation will show that the small quantity
+  on the right-hand side of this equation cannot amount even to the
+  thousandth part of a second for k < 0.1a, which is, practically
+  speaking, zero; consequently the sum of the azimuths [alpha] +
+  [alpha]' on the spheroid is equal to the sum of the spherical
+  azimuths, whence follows this very important theorem (known as Dalby's
+  theorem). If [phi], [phi]' be the latitudes of two points on the
+  surface of a spheroid, [omega] their difference of longitude, [alpha],
+  [alpha]' their reciprocal azimuths,
+
+    tan 1/2[omega] = cot 1/2([alpha] + [alpha]') {cos 1/2([phi]' - [phi])/
+      sin 1/2([phi]' + [phi])}.
+
+  The computation of the geodetic from the astronomical azimuths has
+  been given above. From k we can now compute the length s of the
+  vertical section, and from this the shortest length. The difference of
+  length of the geodetic line and either of the plane curves is
+
+    e^4 s^5 cos^4 [phi]0 sin^2 2[alpha]0/360 a^4.
+
+  At least this is an approximate expression. Supposing s = 0.1a, this
+  quantity would be less than one-hundredth of a millimetre. The line s
+  is now to be calculated as a circular arc with a mean radius r along
+  AB. If [phi]0 = 1/2([phi] + [phi]'), [alpha]0 = 1/2(180 deg. + [alpha]
+  - [alpha]'), [Delta]0 = (1 - e^2 sin^2 [phi]0)^1/2, then 1/r =
+  [Delta]0/a [1 + e^2/(1 - e^2) (cos^2 [phi]0 cos^2 [alpha]0)], and
+  approximately sin (s/2r) = k/2r. These formulae give, in the case of k
+  = 0.1a, values certain to eight logarithmic decimal places. An
+  excellent series of formulae for the solution of the problem, to
+  determine the azimuths, chord and distance along the surface from the
+  geographical co-ordinates, was given in 1882 by Ch. M. Schols
+  (_Archives Neerlandaises_, vol. xvii.).
+
+
+  _Irregularities of the Earth's Surface._
+
+  In considering the effect of unequal distribution of matter in the
+  earth's crust on the form of the surface, we may simplify the matter
+  by disregarding the considerations of rotation and eccentricity. In
+  the first place, supposing the earth a sphere covered with a film of
+  water, let the density [rho] be a function of the distance from the
+  centre so that surfaces of equal density are concentric spheres. Let
+  now a disturbance of the arrangement of matter take place, so that the
+  density is no longer to be expressed by [rho], a function of r only,
+  but is expressed by [rho] + [rho]', where [rho]' is a function of
+  three co-ordinates [theta], [phi], r. Then [rho]' is the density of
+  what may be designated disturbing matter; it is positive in some
+  places and negative in others, and the whole quantity of matter whose
+  density is [rho]' is zero. The previously spherical surface of the sea
+  of radius a now takes a new form. Let P be a point on the disturbed
+  surface, P' the corresponding point vertically below it on the
+  undisturbed surface, PP' = N. The knowledge of N over the whole
+  surface gives us the form of the disturbed or actual surface of the
+  sea; it is an equipotential surface, and if V be the potential at P of
+  the disturbing matter [rho]', M the mass of the earth (the
+  attraction-constant is assumed equal to unity)
+
+      M             M     M
+    ----- + V = C = -- - --- N + V.
+    a + N           a    a^2
+
+  As far as we know, N is always a very small quantity, and we have with
+  sufficient approximation N = 3V/4[pi][delta]a, where [delta] is the
+  mean density of the earth. Thus we have the disturbance in elevation
+  of the sea-level expressed in terms of the potential of the disturbing
+  matter. If at any point P the value of N remain constant when we pass
+  to any adjacent point, then the actual surface is there parallel to
+  the ideal spherical surface; as a rule, however, the normal at P is
+  inclined to that at P', and astronomical observations have shown that
+  this inclination, the deflection or deviation, amounting ordinarily to
+  one or two seconds, may in some cases exceed 10", or, as at the foot
+  of the Himalayas, even 60". By the expression "mathematical figure of
+  the earth" we mean the surface of the sea produced in imagination so
+  as to percolate the continents. We see then that the effect of the
+  uneven distribution of matter in the crust of the earth is to produce
+  small elevations and depressions on the mathematical surface which
+  would be otherwise spheroidal. No geodesist can proceed far in his
+  work without encountering the irregularities of the mathematical
+  surface, and it is necessary that he should know how they affect his
+  astronomical observations. The whole of this subject is dealt with in
+  his usual elegant manner by Bessel in the _Astronomische Nachrichten_,
+  Nos. 329, 330, 331, in a paper entitled "Ueber den Einfluss der
+  Unregelmassigkeiten der Figur der Erde auf geodatische Arbeiten, &c."
+  But without entering into further details it is not difficult to see
+  how local attraction at any station affects the determinations of
+  latitude, longitude and azimuth there.
+
+  Let there be at the station an attraction to the north-east throwing
+  the zenith to the south-west, so that it takes in the celestial sphere
+  a position Z', its undisturbed position being Z. Let the rectangular
+  components of the displacement ZZ' be [xi] measured southwards and
+  [eta] measured westwards. Now the great circle joining Z' with the
+  pole of the heavens P makes there an angle with the meridian PZ =
+  [eta] cosec PZ' = [eta] sec [phi], where [phi] is the latitude of the
+  station. Also this great circle meets the horizon in a point whose
+  distance from the great circle PZ is [eta] sec [phi] sin [phi] = [eta]
+  tan [phi]. That is, a meridian mark, fixed by observations of the pole
+  star, will be placed that amount to the east of north. Hence the
+  observed latitude requires the correction [xi]; the observed longitude
+  a correction [eta] sec [phi]; and any observed azimuth a correction
+  [eta] tan [phi]. Here it is supposed that azimuths are measured from
+  north by east, and longitudes eastwards. The horizontal angles are
+  also influenced by the deflections of the plumb-line, in fact, just as
+  if the direction of the vertical axis of the theodolite varied by the
+  same amount. This influence, however, is slight, so long as the sights
+  point almost horizontally at the objects, which is always the case in
+  the observation of distant points.
+
+  The expression given for N enables one to form an approximate estimate
+  of the effect of a compact mountain in raising the sea-level. Take,
+  for instance, Ben Nevis, which contains about a couple of cubic miles;
+  a simple calculation shows that the elevation produced would only
+  amount to about 3 in. In the case of a mountain mass like the
+  Himalayas, stretching over some 1500 miles of country with a breadth
+  of 300 and an average height of 3 miles, although it is difficult or
+  impossible to find an expression for V, yet we may ascertain that an
+  elevation amounting to several hundred feet may exist near their base.
+  The geodetical operations, however, rather negative this idea, for it
+  was shown by Colonel Clarke (_Phil. Mag._, 1878) that the form of the
+  sea-level along the Indian arc departs but slightly from that of the
+  mean figure of the earth. If this be so, the action of the Himalayas
+  must be counteracted by subterranean tenuity.
+
+  Suppose now that A, B, C, ... are the stations of a network of
+  triangulation projected on or lying on a spheroid of semiaxis major
+  and eccentricity a, e, this spheroid having its axis parallel to the
+  axis of rotation of the earth, and its surface coinciding with the
+  mathematical surface of the earth at A. Then basing the calculations
+  on the observed elements at A, the calculated latitudes, longitudes
+  and directions of the meridian at the other points will be the true
+  latitudes, &c., of the points as projected on the spheroid. On
+  comparing these geodetic elements with the corresponding astronomical
+  determinations, there will appear a system of differences which
+  represent the inclinations, at the various points, of the actual
+  irregular surface to the surface of the spheroid of reference. These
+  differences will suggest two things,--first, that we may improve the
+  agreement of the two surfaces, by not restricting the spheroid of
+  reference by the condition of making its surface coincide with the
+  mathematical surface of the earth at A; and secondly, by altering the
+  form and dimensions of the spheroid. With respect to the first
+  circumstance, we may allow the spheroid two degrees of freedom, that
+  is, the normals of the surfaces at A may be allowed to separate a
+  small quantity, compounded of a meridional difference and a difference
+  perpendicular to the same. Let the spheroid be so placed that its
+  normal at A lies to the north of the normal to the earth's surface by
+  the small quantity [xi] and to the east by the quantity [eta]. Then in
+  starting the calculation of geodetic latitudes, longitudes and
+  azimuths from A, we must take, not the observed elements [phi],
+  [alpha], but for [phi], [phi] + [xi], and for [alpha], [alpha] + [eta]
+  tan [phi], and zero longitude must be replaced by [eta] sec [phi]. At
+  the same time suppose the elements of the spheroid to be altered from
+  a, e to a + da, e + de. Confining our attention at first to the two
+  points A, B, let ([phi]'), ([alpha]'), ([omega]) be the numerical
+  elements at B as obtained in the first calculation, viz. before the
+  shifting and alteration of the spheroid; they will now take the form
+
+    ([phi]') + f[xi] + g[eta] + hda + kde,
+
+    ([alpha]') + f'[xi] + g'[eta] + h'da + k'de,
+
+    [omega] + f"[xi] + g"[eta] + h"da + k"de,
+
+  where the coefficients f, g, ... &c. can be numerically calculated.
+  Now these elements, corresponding to the projection of B on the
+  spheroid of reference, must be equal severally to the astronomically
+  determined elements at B, corrected for the inclination of the
+  surfaces there. If [xi]', [eta]' be the components of the inclination
+  at that point, then we have
+
+    [xi]' = ([phi]') - [phi]' + f[xi] + g[eta] + hda + kde,
+
+    [eta]' tan [phi]' = ([alpha]') - [alpha]' + f'[xi] + g'[eta] + h'da + k'de,
+
+    [eta]' sec [phi]' = ([omega]) - [omega] + f"[xi] + g"[eta] + h"da + k"de,
+
+  where [phi]', [alpha]', [omega] are the observed elements at B. Here
+  it appears that the observation of longitude gives no additional
+  information, but is available as a check upon the azimuthal
+  observations.
+
+  If now there be a number of astronomical stations in the
+  triangulation, and we form equations such as the above for each point,
+  then we can from them determine those values of [xi], [eta], da, de,
+  which make the quantity [xi]^2 + [eta]^2 + [xi]'^2 + [eta]'^2 + ... a
+  minimum. Thus we obtain that spheroid which best represents the
+  surface covered by the triangulation.
+
+  In the _Account of the Principal Triangulation of Great Britain and
+  Ireland_ will be found the determination, from 75 equations, of the
+  spheroid best representing the surface of the British Isles. Its
+  elements are a = 20927005 [+-] 295 ft., b : a - b = 280 [+-] 8; and it
+  is so placed that at Greenwich Observatory [xi] = 1".864, [eta] =
+  -0".546.
+
+  Taking Durham Observatory as the origin, and the tangent plane to the
+  surface (determined by [xi] = -0".664, [eta] = -4".117) as the plane
+  of x and y, the former measured northwards, and z measured vertically
+  downwards, the equation to the surface is
+
+    .99524953 x^2 + .99288005 y^2 + .99763052 z^2 - 0.00671003xz - 41655070z = 0.
+
+
+  _Altitudes._
+
+  The precise determination of the altitude of his station is a matter
+  of secondary importance to the geodesist; nevertheless it is usual to
+  observe the zenith distances of all trigonometrical points. Of great
+  importance is a knowledge of the height of the base for its reduction
+  to the sea-level. Again the height of a station does influence a
+  little the observation of terrestrial angles, for a vertical line at B
+  does not lie generally in the vertical plane of A (see above). The
+  height above the sea-level also influences the geographical latitude,
+  inasmuch as the centrifugal force is increased and the magnitude and
+  direction of the attraction of the earth are altered, and the effect
+  upon the latitude is a very small term expressed by the formula h (g'-
+  g) sin 2 [phi] / ag, where g, g' are the values of gravity at the
+  equator and at the pole. This is h sin 2 [phi] / 5820 seconds, h being
+  in metres, a quantity which may be neglected, since for ordinary
+  mountain heights it amounts to only a few hundredths of a second. We
+  can assume this amount as joined with the northern component of the
+  plumb-line perturbations.
+
+  The uncertainties of terrestrial refraction render it impossible to
+  determine accurately by vertical angles the heights of distant points.
+  Generally speaking, refraction is greatest at about daybreak; from
+  that time it diminishes, being at a minimum for a couple of hours
+  before and after mid-day; later in the afternoon it again increases.
+  This at least is the general march of the phenomenon, but it is by no
+  means regular. The vertical angles measured at the station on Hart
+  Fell showed on one occasion in the month of September a refraction of
+  double the average amount, lasting from 1 P.M. to 5 P.M. The mean
+  value of the coefficient of refraction k determined from a very large
+  number of observations of terrestrial zenith distances in Great
+  Britain is .0792 [+-] .0047; and if we separate those rays which for a
+  considerable portion of their length cross the sea from those which do
+  not, the former give k = .0813 and the latter k = .0753. These values
+  are determined from high stations and long distances; when the
+  distance is short, and the rays graze the ground, the amount of
+  refraction is extremely uncertain and variable. A case is noted in the
+  Indian survey where the zenith distance of a station 10.5 miles off
+  varied from a depression of 4' 52".6 at 4.30 P.M. to an elevation of
+  2' 24".0 at 10.50 P.M.
+
+  If h, h' be the heights above the level of the sea of two stations, 90
+  deg. + [delta], 90 deg. + [delta]' their mutual zenith distances
+  ([delta] being that observed at h), s their distance apart, the earth
+  being regarded as a sphere of radius = a, then, with sufficient
+  precision,
+
+                    /   1 - 2k           \                   / 1 - 2k            \
+    h' - h = s tan ( s -------- - [delta] ), h - h' = s tan ( -------- - [delta]' ).
+                    \     2a             /                   \   2a              /
+
+  If from a station whose height is h the horizon of the sea be observed
+  to have a zenith distance 90 deg. + [delta], then the above formula
+  gives for h the value
+
+        a  tan^2 [delta]
+    h = -- -------------.
+        2     1 - 2k
+
+  Suppose the depression [delta] to be n minutes, then h = 1.054n^2 if
+  the ray be for the greater part of its length crossing the sea; if
+  otherwise, h = 1.040n^2. To take an example: the mean of eight
+  observations of the zenith distance of the sea horizon at the top of
+  Ben Nevis is 91 deg. 4' 48", or [delta] = 64.8; the ray is pretty
+  equally disposed over land and water, and hence h = 1.047n^2 = 4396
+  ft. The actual height of the hill by spirit-levelling is 4406 ft., so
+  that the error of the height thus obtained is only 10 ft.
+
+  The determination of altitudes by means of spirit-levelling is
+  undoubtedly the most exact method, particularly in its present
+  development as precise-levelling, by which there have been determined
+  in all civilized countries close-meshed nets of elevated points
+  covering the entire land.     (A. R. C; F. R. H.)
+
+
+FOOTNOTES:
+
+  [1] An arrangement acting similarly had been previously introduced by
+    Borda.
+
+  [2] _Geodetic Survey of South Africa_, vol. iii. (1905), p. viii;
+    _Les Nouveaux Appareils pour la mesure rapide des bases geod._, par
+    J. Rene Benoit et Ch. Ed. Guillaume (1906).
+
+  [3] See a paper "On the Course of Geodetic Lines on the Earth's
+    Surface" in the _Phil. Mag._ 1870; Helmert, _Theorien der hoheren
+    Geodasie_, 1. 321.
+
+  [4] Helmert, Theorien der hoheren Geodasie, 1. 232, 247.
+
+
+
+
+GEOFFREY, surnamed MARTEL (1006-1060), count of Anjou, son of the count
+Fulk Nerra (q.v.) and of the countess Hildegarde or Audegarde, was born
+on the 14th of October 1006. During his father's lifetime he was
+recognized as suzerain by Fulk l'Oison ("the Gosling"), count of
+Vendome, the son of his half-sister Adela. Fulk having revolted, he
+confiscated the countship, which he did not restore till 1050. On the
+1st of January 1032 he married Agnes, widow of William the Great, duke
+of Aquitaine, and taking arms against William the Fat, eldest son and
+successor of William the Great, defeated him and took him prisoner at
+Mont-Couer near Saint-Jouin-de-Marnes on the 20th of September 1033. He
+then tried to win recognition as dukes of Aquitaine for the sons of his
+wife Agnes by William the Great, who were still minors, but Fulk Nerra
+promptly took up arms to defend his suzerain William the Fat, from whom
+he held the Loudunois and Saintonge in fief against his son. In 1036
+Geoffrey Martel had to liberate William the Fat, on payment of a heavy
+ransom, but the latter having died in 1038, and the second son of
+William the Great, Odo, duke of Gascony, having fallen in his turn at
+the siege of Mauze (10th of March 1039) Geoffrey made peace with his
+father in the autumn of 1039, and had his wife's two sons recognized as
+dukes. About this time, also, he had interfered in the affairs of Maine,
+though without much result, for having sided against Gervais, bishop of
+Le Mans, who was trying to make himself guardian of the young count of
+Maine, Hugh, he had been beaten and forced to make terms with Gervais in
+1038. In 1040 he succeeded his father in Anjou and was able to conquer
+Touraine (1044) and assert his authority over Maine (see ANJOU). About
+1050 he repudiated Agnes, his first wife, and married Grecie, the widow
+of Bellay, lord of Montreuil-Bellay (before August 1052), whom he
+subsequently left in order to marry Adela, daughter of a certain Count
+Odo. Later he returned to Grecie, but again left her to marry Adelaide
+the German. When, however, he died on the 14th of November 1060, at the
+monastery of St Nicholas at Angers, he left no children, and transmitted
+the countship to Geoffrey the Bearded, the eldest of his nephews (see
+ANJOU).
+
+  See Louis Halphen, _Le Comte d'Anjou au XI^e siecle_ (Paris, 1906). A
+  summary biography is given by Celestin Port, _Dictionnaire historique,
+  geographique et biographique de Maine-et-Loire_ (3 vols.,
+  Paris-Angers, 1874-1878), vol. ii. pp. 252-253, and a sketch of the
+  wars by Kate Norgate, _England under the Angevin Kings_ (2 vols.,
+  London, 1887), vol. i. chs. iii. iv.     (L. H.*)
+
+
+
+
+GEOFFREY, surnamed PLANTAGENET [or PLANTEGENET] (1113-1151), count of
+Anjou, was the son of Count Fulk the Young and of Eremburge (or
+Arembourg of La Fleche); he was born on the 24th of August 1113. He is
+also called "le bel" or "the handsome," and received the surname of
+Plantagenet from the habit which he is said to have had of wearing in
+his cap a sprig of broom (_genet_). In 1127 he was made a knight, and on
+the 2nd of June 1129 married Matilda, daughter of Henry I. of England,
+and widow of the emperor Henry V. Some months afterwards he succeeded to
+his father, who gave up the countship when he definitively went to the
+kingdom of Jerusalem. The years of his government were spent in subduing
+the Angevin barons and in conquering Normandy (see ANJOU). In 1151,
+while returning from the siege of Montreuil-Bellay, he took cold, in
+consequence of bathing in the Loir at Chateau-du-Loir, and died on the
+7th of September. He was buried in the cathedral of Le Mans. By his wife
+Matilda he had three sons: Henry Plantagenet, born at Le Mans on Sunday,
+the 5th of March 1133; Geoffrey, born at Argentan on the 1st of June
+1134; and William Long-Sword, born on the 22nd of July 1136.
+
+  See Kate Norgate, _England under the Angevin Kings_ (2 vols., London,
+  1887), vol. i. chs. v.-viii.; Celestin Port, _Dictionnaire historique,
+  geographique et biographique de Maine-et-Loire_ (3 vols.,
+  Paris-Angers, 1874-1878), vol. ii. pp. 254-256. A history of Geoffrey
+  le Bel has yet to be written; there is a biography of him written in
+  the 12th century by Jean, a monk of Marmoutier, _Historia Gaufredi,
+  ducis Normannorum et comitis Andegavorum_, published by Marchegay et
+  Salmon; "Chroniques des comtes d'Anjou" (_Societe de l'histoire de
+  France_, Paris, 1856), pp. 229-310.     (L. H.*)
+
+
+
+
+GEOFFREY (1158-1186), duke of Brittany, fourth son of the English king
+Henry II. and his wife Eleanor of Aquitaine, was born on the 23rd of
+September 1158. In 1167 Henry suggested a marriage between Geoffrey and
+Constance (d. 1201), daughter and heiress of Conan IV., duke of Brittany
+(d. 1171); and Conan not only assented, perhaps under compulsion, to
+this proposal, but surrendered the greater part of his unruly duchy to
+the English king. Having received the homage of the Breton nobles,
+Geoffrey joined his brothers, Henry and Richard, who, in alliance with
+Louis VII. of France, were in revolt against their father; but he made
+his peace in 1174, afterwards helping to restore order in Brittany and
+Normandy, and aiding the new French king, Philip Augustus, to crush some
+rebellious vassals. In July 1181 his marriage with Constance was
+celebrated, and practically the whole of his subsequent life was spent
+in warfare with his brother Richard. In 1183 he made peace with his
+father, who had come to Richard's assistance; but a fresh struggle soon
+broke out for the possession of Anjou, and Geoffrey was in Paris
+treating for aid with Philip Augustus, when he died on the 19th of
+August 1186. He left a daughter, Eleanor, and his wife bore a
+posthumous son, the unfortunate Arthur.
+
+
+
+
+GEOFFREY (c. 1152-1212), archbishop of York, was a bastard son of Henry
+II., king of England. He was distinguished from his legitimate
+half-brothers by his consistent attachment and fidelity to his father.
+He was made bishop of Lincoln at the age of twenty-one (1173); but
+though he enjoyed the temporalities he was never consecrated and
+resigned the see in 1183. He then became his father's chancellor,
+holding a large number of lucrative benefices in plurality. Richard
+nominated him archbishop of York in 1189, but he was not consecrated
+till 1191, or enthroned till 1194. Geoffrey, though of high character,
+was a man of uneven temper; his history in chiefly one of quarrels, with
+the see of Canterbury, with the chancellor William Longchamp, with his
+half-brothers Richard and John, and especially with his canons at York.
+This last dispute kept him in litigation before Richard and the pope for
+many years. He led the clergy in their refusal to be taxed by John and
+was forced to fly the kingdom in 1207. He died in Normandy on the 12th
+of December 1212.
+
+  See Giraldus Cambrensis, _Vita Galfridi_; Stubbs's prefaces to _Roger
+  de Hoveden_, vols. iii. and iv. (Rolls Series).     (H. W. C. D.)
+
+
+
+
+GEOFFREY DE MONTBRAY (d. 1093), bishop of Coutances (_Constantiensis_),
+a right-hand man of William the Conqueror, was a type of the great
+feudal prelate, warrior and administrator at need. He knew, says
+Orderic, more about marshalling mailed knights than edifying
+psalm-singing clerks. Obtaining, as a young man, in 1048, the see of
+Coutances, by his brother's influence (see MOWBRAY), he raised from his
+fellow nobles and from their Sicilian spoils funds for completing his
+cathedral, which was consecrated in 1056. With bishop Odo, a warrior
+like himself, he was on the battle-field of Hastings, exhorting the
+Normans to victory; and at William's coronation it was he who called on
+them to acclaim their duke as king. His reward in England was a mighty
+fief scattered over twelve counties. He accompanied William on his visit
+to Normandy (1067), but, returning, led a royal force to the relief of
+Montacute in September 1069. In 1075 he again took the field, leading
+with Bishop Odo a vast host against the rebel earl of Norfolk, whose
+stronghold at Norwich they besieged and captured.
+
+Meanwhile the Conqueror had invested him with important judicial
+functions. In 1072 he had presided over the great Kentish suit between
+the primate and Bishop Odo, and about the same time over those between
+the abbot of Ely and his despoilers, and between the bishop of Worcester
+and the abbot of Ely, and there is some reason to think that he acted as
+a Domesday commissioner (1086), and was placed about the same time in
+charge of Northumberland. The bishop, who attended the Conqueror's
+funeral, joined in the great rising against William Rufus next year
+(1088), making Bristol, with which (as Domesday shows) he was closely
+connected and where he had built a strong castle, his base of
+operations. He burned Bath and ravaged Somerset, but had submitted to
+the king before the end of the year. He appears to have been at Dover
+with William in January 1090, but, withdrawing to Normandy, died at
+Coutances three years later. In his fidelity to Duke Robert he seems to
+have there held out for him against his brother Henry, when the latter
+obtained the Cotentin.
+
+  See E.A. Freeman, _Norman Conquest_ and _William Rufus_; J.H. Round,
+  _Feudal England_; and, for original authorities, the works of Orderic
+  Vitalis and William of Poitiers, and of Florence of Worcester; the
+  Anglo-Saxon Chronicle; William of Malmesbury's _Gesta pontificum_, and
+  Lanfranc's works, ed. Giles; Domesday Book.     (J. H. R.)
+
+
+
+
+GEOFFREY OF MONMOUTH (d. 1154), bishop of St Asaph and writer on early
+British history, was born about the year 1100. Of his early life little
+is known, except that he received a liberal education under the eye of
+his paternal uncle, Uchtryd, who was at that time archdeacon, and
+subsequently bishop, of Llandaff. In 1129 Geoffrey appears at Oxford
+among the witnesses of an Oseney charter. He subscribes himself Geoffrey
+Arturus; from this we may perhaps infer that he had already begun his
+experiments in the manufacture of Celtic mythology. A first edition of
+his _Historia Britonum_ was in circulation by the year 1139, although
+the text which we possess appears to date from 1147. This famous work,
+which the author has the audacity to place on the same level with the
+histories of William of Malmesbury and Henry of Huntingdon, professes to
+be a translation from a Celtic source; "a very old book in the British
+tongue" which Walter, archdeacon of Oxford, had brought from Brittany.
+Walter the archdeacon is a historical personage; whether his book has
+any real existence may be fairly questioned. There is nothing in the
+matter or the style of the _Historia_ to preclude us from supposing that
+Geoffrey drew partly upon confused traditions, partly on his own powers
+of invention, and to a very slight degree upon the accepted authorities
+for early British history. His chronology is fantastic and incredible;
+William of Newburgh justly remarks that, if we accepted the events which
+Geoffrey relates, we should have to suppose that they had happened in
+another world. William of Newburgh wrote, however, in the reign of
+Richard I. when the reputation of Geoffrey's work was too well
+established to be shaken by such criticisms. The fearless romancer had
+achieved an immediate success. He was patronized by Robert, earl of
+Gloucester, and by two bishops of Lincoln; he obtained, about 1140, the
+archdeaconry of Llandaff "on account of his learning"; and in 1151 was
+promoted to the see of St Asaph.
+
+Before his death the _Historia Britonum_ had already become a model and
+a quarry for poets and chroniclers. The list of imitators begins with
+Geoffrey Gaimar, the author of the _Estorie des Engles_ (c. 1147), and
+Wace, whose _Roman de Brut_ (1155) is partly a translation and partly a
+free paraphrase of the _Historia_. In the next century the influence of
+Geoffrey is unmistakably attested by the _Brut_ of Layamon, and the
+rhyming English chronicle of Robert of Gloucester. Among later
+historians who were deceived by the _Historia Britonum_ it is only
+needful to mention Higdon, Hardyng, Fabyan (1512), Holinshed (1580) and
+John Milton. Still greater was the influence of Geoffrey upon those
+writers who, like Warner in _Albion's England_ (1586), and Drayton in
+_Polyolbion_ (1613), deliberately made their accounts of English history
+as poetical as possible. The stories which Geoffrey preserved or
+invented were not infrequently a source of inspiration to literary
+artists. The earliest English tragedy, _Gorboduc_ (1565), the _Mirror
+for Magistrates_ (1587), and Shakespeare's Lear, are instances in point.
+It was, however, the Arthurian legend which of all his fabrications
+attained the greatest vogue. In the work of expanding and elaborating
+this theme the successors of Geoffrey went as far beyond him as he had
+gone beyond Nennius; but he retains the credit due to the founder of a
+great school. Marie de France, who wrote at the court of Henry II., and
+Chretien de Troyes, her French contemporary, were the earliest of the
+avowed romancers to take up the theme. The succeeding age saw the
+Arthurian story popularized, through translations of the French
+romances, as far afield as Germany and Scandinavia. It produced in
+England the _Roman du Saint Graal_ and the _Roman de Merlin_, both from
+the pen of Robert de Borron; the _Roman de Lancelot_; the _Roman de
+Tristan_, which is attributed to a fictitious Lucas de Gast. In the
+reign of Edward IV. Sir Thomas Malory paraphrased and arranged the best
+episodes of these romances in English prose. His _Morte d'Arthur_,
+printed by Caxton in 1485, epitomizes the rich mythology which
+Geoffrey's work had first called into life, and gave the Arthurian story
+a lasting place in the English imagination. The influence of the
+_Historia Britonum_ may be illustrated in another way, by enumerating
+the more familiar of the legends to which it first gave popularity. Of
+the twelve books into which it is divided only three (Bks. IX., X., XI.)
+are concerned with Arthur. Earlier in the work, however, we have the
+adventures of Brutus; of his follower Corineus, the vanquisher of the
+Cornish giant Goemagol (Gogmagog); of Locrinus and his daughter Sabre
+(immortalized in Milton's _Comus_); of Bladud the builder of Bath; of
+Lear and his daughters; of the three pairs of brothers, Ferrex and
+Porrex, Brennius and Belinus, Elidure and Peridure. The story of
+Vortigern and Rowena takes its final form in the _Historia Britonum_;
+and Merlin makes his first appearance in the prelude to the Arthur
+legend. Besides the _Historia Britonum_ Geoffrey is also credited with
+a _Life of Merlin_ composed in Latin verse. The authorship of this work
+has, however, been disputed, on the ground that the style is distinctly
+superior to that of the _Historia_. A minor composition, the _Prophecies
+of Merlin_, was written before 1136, and afterwards incorporated with
+the _Historia_, of which it forms the seventh book.
+
+  For a discussion of the manuscripts of Geoffrey's work, see Sir T.D.
+  Hardy's _Descriptive Catalogue_ (Rolls Series), i. pp. 341 ff. The
+  _Historia Britonum_ has been critically edited by San Marte (Halle,
+  1854). There is an English translation by J.A. Giles (London, 1842).
+  The _Vita Merlini_ has been edited by F. Michel and T. Wright (Paris,
+  1837). See also the _Dublin Univ. Magazine_ for April 1876, for an
+  article by T. Gilray on the literary influence of Geoffrey; G.
+  Heeger's _Trojanersage der Britten_ (1889); and La Borderie's _Etudes
+  historiques bretonnes_ (1883).     (H. W. C. D.)
+
+
+
+
+GEOFFREY OF PARIS (d. c. 1320), French chronicler, was probably the
+author of the _Chronique metrique de Philippe le Bel, or Chronique rimee
+de Geoffroi de Paris_. This work, which deals with the history of France
+from 1300 to 1316, contains 7918 verses, and is valuable as that of a
+writer who had a personal knowledge of many of the events which he
+relates. Various short historical poems have also been attributed to
+Geoffrey, but there is no certain information about either his life or
+his writings.
+
+  The _Chronique_ was published by J.A. Buchon in his _Collection des
+  chroniques_, tome ix. (Paris, 1827), and it has also been printed in
+  tome xxii. of the _Recueil des historiens des Gaules et de la France_
+  (Paris, 1865). See G. Paris, _Histoire de la litterature francaise au
+  moyen age_ (Paris, 1890); and A. Molinier, _Les Sources de l'histoire
+  de France_, tome iii. (Paris, 1903).
+
+
+
+
+GEOFFREY THE BAKER (d. c. 1360), English chronicler, is also called
+Walter of Swinbroke, and was probably a secular clerk at Swinbrook in
+Oxfordshire. He wrote a _Chronicon Angliae temporibus Edwardi II. et
+Edwardi III._, which deals with the history of England from 1303 to
+1356. From the beginning until about 1324 this work is based upon Adam
+Murimuth's _Continuatio chronicarum_, but after this date it is valuable
+and interesting, containing information not found elsewhere, and closing
+with a good account of the battle of Poitiers. The author obtained his
+knowledge about the last days of Edward II. from William Bisschop, a
+companion of the king's murderers, Thomas Gurney and John Maltravers.
+Geoffrey also wrote a _Chroniculum_ from the creation of the world until
+1336, the value of which is very slight. His writings have been edited
+with notes by Sir E.M. Thompson as the _Chronicon Galfridi le Baker de
+Swynebroke_ (Oxford, 1889). Some doubt exists concerning Geoffrey's
+share in the compilation of the _Vita et mors Edwardi II._, usually
+attributed to Sir Thomas de la More, or Moor, and printed by Camden in
+his _Anglica scripta_. It has been maintained by Camden and others that
+More wrote an account of Edward's reign in French, and that this was
+translated into Latin by Geoffrey and used by him in compiling his
+_Chronicon_. Recent scholarship, however, asserts that More was no
+writer, and that the _Vita et mors_ is an extract from Geoffrey's
+_Chronicon_, and was attributed to More, who was the author's patron. In
+the main this conclusion substantiates the verdict of Stubbs, who has
+published the _Vita et mors_ in his _Chronicles of the reigns of Edward
+I. and Edward II._ (London, 1883). The manuscripts of Geoffrey's works
+are in the Bodleian library at Oxford.
+
+
+
+
+GEOFFRIN, MARIE THERESE RODET (1699-1777), a Frenchwoman who played an
+interesting part in French literary and artistic life, was born in Paris
+in 1699. She married, on the 19th of July 1713, Pierre Francois
+Geoffrin, a rich manufacturer and lieutenant-colonel of the National
+Guard, who died in 1750. It was not till Mme Geoffrin was nearly fifty
+years of age that we begin to hear of her as a power in Parisian
+society. She had learned much from Mme de Tencin, and about 1748 began
+to gather round her a literary and artistic circle. She had every week
+two dinners, on Monday for artists, and on Wednesday for her friends the
+Encyclopaedists and other men of letters. She received many foreigners
+of distinction, Hume and Horace Walpole among others. Walpole spent much
+time in her society before he was finally attached to Mme du Deffand,
+and speaks of her in his letters as a model of common sense. She was
+indeed somewhat of a small tyrant in her circle. She had adopted the
+pose of an old woman earlier than necessary, and her coquetry, if such
+it can be called, took the form of being mother and mentor to her
+guests, many of whom were indebted to her generosity for substantial
+help. Although her aim appears to have been to have the _Encyclopedie_
+in conversation and action around her, she was extremely displeased with
+any of her friends who were so rash as to incur open disgrace. Marmontel
+lost her favour after the official censure of _Belisaire_, and her
+advanced views did not prevent her from observing the forms of religion.
+A devoted Parisian, Mme Geoffrin rarely left the city, so that her
+journey to Poland in 1766 to visit the king, Stanislas Poniatowski, whom
+she had known in his early days in Paris, was a great event in her life.
+Her experiences induced a sensible gratitude that she had been born
+"_Francaise_" and "_particuliere_." In her last illness her daughter,
+Therese, marquise de la Ferte Imbault, excluded her mother's old friends
+so that she might die as a good Christian, a proceeding wittily
+described by the old lady: "My daughter is like Godfrey de Bouillon, she
+wished to defend my tomb from the infidels." Mme Geoffrin died in Paris
+on the 6th of October 1777.
+
+  See _Correspondance inedite du roi Stanislas Auguste Poniatowski et de
+  Madame Geoffrin_, edited by the comte de Mouy (1875); P. de Segur, _Le
+  Royaume de la rue Saint-Honore, Madame Geoffrin et sa fille_ (1897);
+  A. Tornezy, _Un Bureau d'esprit au XVIII^e siecle: le salon de Madame
+  Geoffrin_ (1895); and Janet Aldis, _Madame Geoffrin, her Salon and her
+  Times, 1750-1777_ (1905).
+
+
+
+
+GEOFFROY, ETIENNE FRANCOIS (1672-1731), French chemist, born in Paris on
+the 13th of February 1672, was first an apothecary and then practised
+medicine. After studying at Montpellier he accompanied Marshal Tallard
+on his embassy to London in 1698 and thence travelled to Holland and
+Italy. Returning to Paris he became professor of chemistry at the Jardin
+du Roi and of pharmacy and medicine at the College de France, and dean
+of the faculty of medicine. He died in Paris on the 6th of January 1731.
+His name is best known in connexion with his tables of affinities
+(_tables des rapports_), which he presented to the French Academy in
+1718 and 1720. These were lists, prepared by collating observations on
+the actions of substances one upon another, showing the varying degrees
+of affinity exhibited by analogous bodies for different reagents, and
+they retained their vogue for the rest of the century, until displaced
+by the profounder conceptions introduced by C.L. Berthollet. Another of
+his papers dealt with the delusions of the philosopher's stone, but
+nevertheless he believed that iron could be artificially formed in the
+combustion of vegetable matter. His _Tractatus de materia medica_,
+published posthumously in 1741, was long celebrated.
+
+His brother CLAUDE JOSEPH, known as Geoffroy the younger (1685-1752),
+was also an apothecary and chemist who, having a considerable knowledge
+of botany, devoted himself especially to the study of the essential oils
+in plants.
+
+
+
+
+GEOFFROY, JULIEN LOUIS (1743-1814), French critic, was born at Rennes in
+1743. He studied in the school of his native town and at the College
+Louis le Grand in Paris. He took orders and fulfilled for some time the
+humble functions of an usher, eventually becoming professor of rhetoric
+at the _College Mazarin_. A bad tragedy, Caton, was accepted at the
+_Theatre Francais_, but was never acted. On the death of Elie Freron in
+1776 the other collaborators in the _Annee litteraire_ asked Geoffroy to
+succeed him, and he conducted the journal until in 1792 it ceased to
+appear. Geoffroy was a bitter critic of Voltaire and his followers, and
+made for himself many enemies. An enthusiastic royalist, he published
+with Freron's brother-in-law, the abbe Thomas Royou (1741-1792), a
+journal, _L'Ami du roi_ (1790-1792), which possibly did more harm than
+good to the king's cause by its ill-advised partisanship. During the
+Terror Geoffroy hid in the neighbourhood of Paris, only returning in
+1799. An attempt to revive the _Annee litteraire_ failed, and Geoffroy
+undertook the dramatic feuilleton of the _Journal des debats_. His
+scathing criticisms had a success of notoriety, but their popularity was
+ephemeral, and the publication of them (5 vols., 1819-1820) as _Cours de
+litterature dramatique_ proved a failure. He was also the author of a
+perfunctory _Commentaire_ on the works of Racine prefixed to Lenormant's
+edition (1808). He died in Paris on the 27th of February 1814.
+
+
+
+
+GEOFFROY SAINT-HILAIRE, ETIENNE (1772-1844), French naturalist, was the
+son of Jean Gerard Geoffroy, procurator and magistrate of Etampes,
+Seine-et-Oise, where he was born on the 15th of April 1772. Destined for
+the church he entered the college of Navarre, in Paris, where he studied
+natural philosophy under M.J. Brisson; and in 1788 he obtained one of
+the canonicates of the chapter of Sainte Croix at Etampes, and also a
+benefice. Science, however, offered him a more congenial career, and he
+gained from his father permission to remain in Paris, and to attend the
+lectures at the College de France and the Jardin des Plantes, on the
+condition that he should also read law. He accordingly took up his
+residence at Cardinal Lemoine's college, and there became the pupil and
+soon the esteemed associate of Brisson's friend, the abbe Hauy, the
+mineralogist. Having, before the close of the year 1790, taken the
+degree of bachelor in law, he became a student of medicine, and attended
+the lectures of A.F. de Fourcroy at the Jardin des Plantes, and of
+L.J.M. Daubenton at the College de France. His studies at Paris were at
+length suddenly interrupted, for, in August 1792, Hauy and the other
+professors of Lemoine's college, as also those of the college of
+Navarre, were arrested by the revolutionists as priests, and confined in
+the prison of St Firmin. Through the influence of Daubenton and others
+Geoffroy on the 14th of August obtained an order for the release of Hauy
+in the name of the Academy; still the other professors of the two
+colleges, save C.F. Lhomond, who had been rescued by his pupil J.L.
+Tallien, remained in confinement. Geoffroy, foreseeing their certain
+destruction if they remained in the hands of the revolutionists,
+determined if possible to secure their liberty by stratagem. By bribing
+one of the officials at St Firmin, and disguising himself as a
+commissioner of prisons, he gained admission to his friends, and
+entreated them to effect their escape by following him. All, however,
+dreading lest their deliverance should render the doom of their
+fellow-captives the more certain, refused the offer, and one priest
+only, who was unknown to Geoffroy, left the prison. Already on the night
+of the 2nd of September the massacre of the proscribed had begun, when
+Geoffroy, yet intent on saving the life of his friends and teachers,
+repaired to St Firmin. At 4 o'clock on the morning of the 3rd of
+September, after eight hours' waiting, he by means of a ladder assisted
+the escape of twelve ecclesiastics, not of the number of his
+acquaintance, and then the approach of dawn and the discharge of a gun
+directed at him warned him, his chief purpose unaccomplished, to return
+to his lodgings. Leaving Paris he retired to Etampes, where, in
+consequence of the anxieties of which he had lately been the prey, and
+the horrors which he had witnessed, he was for some time seriously ill.
+At the beginning of the winter of 1792 he returned to his studies in
+Paris, and in March of the following year Daubenton, through the
+interest of Bernardin de Saint Pierre, procured him the office of
+sub-keeper and assistant demonstrator of the cabinet of natural history,
+vacant by the resignation of B.G.E. Lacepede. By a law passed in June
+1793, Geoffroy was appointed one of the twelve professors of the newly
+constituted museum of natural history, being assigned the chair of
+zoology. In the same year he busied himself with the formation of a
+menagerie at that institution.
+
+In 1794 through the introduction of A.H. Tessier he entered into
+correspondence with Georges Cuvier, to whom, after the perusal of some
+of his manuscripts, he wrote: "Venez jouer parmi nous le role de Linne,
+d'un autre legislateur de l'histoire naturelle." Shortly after the
+appointment of Cuvier as assistant at the Museum d'Histoire Naturelle,
+Geoffroy received him into his house. The two friends wrote together
+five memoirs on natural history, one of which, on the classification of
+mammals, puts forward the idea of the subordination of characters upon
+which Cuvier based his zoological system. It was in a paper entitled
+"Histoire des Makis, ou singes de Madagascar," written in 1795, that
+Geoffroy first gave expression to his views on "the unity of organic
+composition," the influence of which is perceptible in all his
+subsequent writings; nature, he observes, presents us with only one plan
+of construction, the same in principle, but varied in its accessory
+parts.
+
+In 1798 Geoffroy was chosen a member of the great scientific expedition
+to Egypt, and on the capitulation of Alexandria in August 1801, he took
+part in resisting the claim made by the British general to the
+collections of the expedition, declaring that, were that demand
+persisted in, history would have to record that he also had burnt a
+library in Alexandria. Early in January 1802 Geoffroy returned to his
+accustomed labours in Paris. He was elected a member of the academy of
+sciences of that city in September 1807. In March of the following year
+the emperor, who had already recognized his national services by the
+award of the cross of the legion of honour, selected him to visit the
+museums of Portugal, for the purpose of procuring collections from them,
+and in the face of considerable opposition from the British he
+eventually was successful in retaining them as a permanent possession
+for his country. In 1809, the year after his return to France, he was
+made professor of zoology at the faculty of sciences at Paris, and from
+that period he devoted himself more exclusively than before to
+anatomical study. In 1818 he gave to the world the first part of his
+celebrated _Philosophie anatomique_, the second volume of which,
+published in 1822, and subsequent memoirs account for the formation of
+monstrosities on the principle of arrest of development, and of the
+attraction of similar parts. When, in 1830, Geoffroy proceeded to apply
+to the invertebrata his views as to the unity of animal composition, he
+found a vigorous opponent in Georges Cuvier, and the discussion between
+them, continued up to the time of the death of the latter, soon
+attracted the attention of the scientific throughout Europe. Geoffroy, a
+synthesist, contended, in accordance with his theory of unity of plan in
+organic composition, that all animals are formed of the same elements,
+in the same number, and with the same connexions: homologous parts,
+however they differ in form and size, must remain associated in the same
+invariable order. With Goethe he held that there is in nature a law of
+compensation or balancing of growth, so that if one organ take on an
+excess of development, it is at the expense of some other part; and he
+maintained that, since nature takes no sudden leaps, even organs which
+are superfluous in any given species, if they have played an important
+part in other species of the same family, are retained as rudiments,
+which testify to the permanence of the general plan of creation. It was
+his conviction that, owing to the conditions of life, the same forms had
+not been perpetuated since the origin of all things, although it was not
+his belief that existing species are becoming modified. Cuvier, who was
+an analytical observer of facts, admitted only the prevalence of "laws
+of co-existence" or "harmony" in animal organs, and maintained the
+absolute invariability of species, which he declared had been created
+with a regard to the circumstances in which they were placed, each organ
+contrived with a view to the function it had to fulfil, thus putting, in
+Geoffroy's considerations, the effect for the cause.
+
+In July 1840 Geoffroy became blind, and some months later he had a
+paralytic attack. From that time his strength gradually failed him. He
+resigned his chair at the museum in 1841, and died at Paris on the 19th
+of June 1844.
+
+  Geoffroy wrote: _Catalogue des mammiferes du Museum National
+  d'Histoire Naturelle_ (1813), not quite completed; _Philosophie
+  anatomique_--t. i., _Des organes respiratoires_ (1818), and t. ii.,
+  _Des monstruosites humaines_ (1822); _Systeme dentaire des mammiferes
+  et des oiseaux_ (1st pt., 1824); _Sur le principe de l'unite de
+  composition organique_ (1828); _Cours de l'histoire naturelle des
+  mammiferes_ (1829); _Principes de philosophie zoologique_ (1830);
+  _Etudes progressives d'un naturaliste_ (1835); _Fragments
+  biographiques_ (1832); _Notions synthetiques, historiques et
+  physiologiques de philosophie naturelle_ (1838), and other works; also
+  part of the _Description de l'Egypte par la commission des sciences_
+  (1821-1830); and, with Frederic Cuvier (1773-1838), a younger brother
+  of G. Cuvier, _Histoire naturelle des mammiferes_ (4 vols.,
+  1820-1842); besides numerous papers on such subjects as the anatomy of
+  marsupials, ruminants and electrical fishes, the vertebrate theory of
+  the skull, the opercula of fishes, teratology, palaeontology and the
+  influence of surrounding conditions in modifying animal forms.
+
+  See _Vie, travaux, et doctrine scientifique d'Etienne Geoffroy
+  Saint-Hilaire, par son fils M. Isidore Geoffroy Saint-Hilaire_ (Paris
+  and Strasburg, 1847), to which is appended a list of Geoffroy's works;
+  and Joly, in _Biog. universelle_, t. xvi. (1856).
+
+
+
+
+
+GEOFFROY SAINT-HILAIRE, ISIDORE (1805-1861), French zoologist, son of
+the preceding, was born at Paris on the 16th of December 1805. In his
+earlier years he showed an aptitude for mathematics, but eventually he
+devoted himself to the study of natural history and of medicine, and in
+1824 he was appointed assistant naturalist to his father. On the
+occasion of his taking the degree of doctor of medicine in September
+1829, he read a thesis entitled _Propositions sur la monstruosite,
+consideree chez l'homme et les animaux_; and in 1832-1837 was published
+his great teratological work, _Histoire generale et particuliere des
+anomalies de l'organisation chez l'homme et les animaux_, 3 vols. 8vo.
+with 20 plates. In 1829 he delivered for his father the second part of a
+course of lectures on ornithology, and during the three following years
+he taught zoology at the Athenee, and teratology at the Ecole pratique.
+He was elected a member of the academy of sciences at Paris in 1833, was
+in 1837 appointed to act as deputy for his father at the faculty of
+sciences in Paris, and in the following year was sent to Bordeaux to
+organize a similar faculty there. He became successively inspector of
+the academy of Paris (1840), professor of the museum on the retirement
+of his father (1841), inspector-general of the university (1844), a
+member of the royal council for public instruction (1845), and on the
+death of H.M.D. de Blainville, professor of zoology at the faculty of
+sciences (1850). In 1854 he founded the Acclimatization Society of
+Paris, of which he was president. He died at Paris on the 10th of
+November 1861.
+
+  Besides the above-mentioned works, he wrote: _Essais de zoologie
+  generale_ (1841); _Vie ... d'Etienne Geoffroy Saint-Hilaire_ (1847);
+  _Acclimatation et domestication des animaux utiles_ (1849; 4th ed.,
+  1861); _Lettres sur les substances alimentaires et particulierement
+  sur la viande de cheval_ (1856); and _Histoire naturelle generale des
+  regnes organiques_ (3 vols., 1854-1862), which was not quite
+  completed. He was the author also of various papers on zoology,
+  comparative anatomy and palaeontology.
+
+
+
+
+GEOGRAPHY (Gr. [Greek: ge], earth, and [Greek: graphein], to write), the
+exact and organized knowledge of the distribution of phenomena on the
+surface of the earth. The fundamental basis of geography is the vertical
+relief of the earth's crust, which controls all mobile distributions.
+The grander features of the relief of the lithosphere or stony crust of
+the earth control the distribution of the hydrosphere or collected
+waters which gather into the hollows, filling them up to a height
+corresponding to the volume, and thus producing the important practical
+division of the surface into land and water. The distribution of the
+mass of the atmosphere over the surface of the earth is also controlled
+by the relief of the crust, its greater or lesser density at the surface
+corresponding to the lesser or greater elevation of the surface. The
+simplicity of the zonal distribution of solar energy on the earth's
+surface, which would characterize a uniform globe, is entirely destroyed
+by the dissimilar action of land and water with regard to radiant heat,
+and by the influence of crust-forms on the direction of the resulting
+circulation. The influence of physical environment becomes clearer and
+stronger when the distribution of plant and animal life is considered,
+and if it is less distinct in the case of man, the reason is found in
+the modifications of environment consciously produced by human effort.
+Geography is a synthetic science, dependent for the data with which it
+deals on the results of specialized sciences such as astronomy, geology,
+oceanography, meteorology, biology and anthropology, as well as on
+topographical description. The physical and natural sciences are
+concerned in geography only so far as they deal with the forms of the
+earth's surface, or as regards the distribution of phenomena. The
+distinctive task of geography as a science is to investigate the control
+exercised by the crust-forms directly or indirectly upon the various
+mobile distributions. This gives to it unity and definiteness, and
+renders superfluous the attempts that have been made from time to time
+to define the limits which divide geography from geology on the one hand
+and from history on the other. It is essential to classify the
+subject-matter of geography in such a manner as to give prominence not
+only to facts, but to their mutual relations and their natural and
+inevitable order.
+
+The fundamental conception of geography is form, including the figure of
+the earth and the varieties of crustal relief. Hence mathematical
+geography (see MAP), including cartography as a practical application,
+comes first. It merges into physical geography, which takes account of the
+forms of the lithosphere (geomorphology), and also of the distribution of
+the hydrosphere and the rearrangements resulting from the workings of
+solar energy throughout the hydrosphere and atmosphere (oceanography and
+climatology). Next follows the distribution of plants and animals
+(biogeography), and finally the distribution of mankind and the various
+artificial boundaries and redistributions (anthropogeography). The
+applications of anthropogeography to human uses give rise to political and
+commercial geography, in the elucidation of which all the earlier
+departments or stages have to be considered, together with historical and
+other purely human conditions. The evolutionary idea has revolutionized
+and unified geography as it did biology, breaking down the old
+hard-and-fast partitions between the various departments, and substituting
+the study of the nature and influence of actual terrestrial environments
+for the earlier motive, the discovery and exploration of new lands.
+
+
+  HISTORY OF GEOGRAPHICAL THEORY
+
+  The earliest conceptions of the earth, like those held by the
+  primitive peoples of the present day, are difficult to discover and
+  almost impossible fully to grasp. Early generalizations, as far as
+  they were made from known facts, were usually expressed in symbolic
+  language, and for our present purpose it is not profitable to
+  speculate on the underlying truths which may sometimes be suspected in
+  the old mythological cosmogonies.
+
+
+    Early Greek ideas.
+
+    Flat earth of Homer.
+
+    Hecataeus.
+
+    Herodotus.
+
+    The idea of symmetry.
+
+  The first definite geographical theories to affect the western world
+  were those evolved, or at least first expressed, by the Greeks.[1] The
+  earliest theoretical problem of geography was the form of the earth.
+  The natural supposition that the earth is a flat disk, circular or
+  elliptical in outline, had in the time of Homer acquired a special
+  definiteness by the introduction of the idea of the ocean river
+  bounding the whole, an application of imperfectly understood
+  observations. Thales of Miletus is claimed as the first exponent of
+  the idea of a spherical earth; but, although this does not appear to
+  be warranted, his disciple Anaximander (c. 580 B.C.) put forward the
+  theory that the earth had the figure of a solid body hanging freely in
+  the centre of the hollow sphere of the starry heavens. The Pythagorean
+  school of philosophers adopted the theory of a spherical earth, but
+  from metaphysical rather than scientific reasons; their convincing
+  argument was that a sphere being the most perfect solid figure was the
+  only one worthy to circumscribe the dwelling-place of man. The
+  division of the sphere into parallel zones and some of the
+  consequences of this generalization seem to have presented themselves
+  to Parmenides (c. 450 B.C.); but these ideas did not influence the
+  Ionian school of philosophers, who in their treatment of geography
+  preferred to deal with facts demonstrable by travel rather than with
+  speculations. Thus Hecataeus, claimed by H.F. Tozer[2] as the father
+  of geography on account of his _Periodos_, or general treatise on the
+  earth, did not advance beyond the primitive conception of a circular
+  disk. He systematized the form of the land within the ring of
+  ocean--the [Greek: oikoumene], or habitable world--by recognizing two
+  continents: Europe to the north, and Asia to the south of the midland
+  sea. Herodotus, equally oblivious of the sphere, criticized and
+  ridiculed the circular outline of the _oekumene_, which he knew to be
+  longer from east to west than it was broad from north to south. He
+  also pointed out reasons for accepting a division of the land into
+  three continents--Europe, Asia and Africa. Beyond the limits of his
+  personal travels Herodotus applied the characteristically Greek theory
+  of symmetry to complete, in the unknown, outlines of lands and rivers
+  analogous to those which had been explored. Symmetry was in fact the
+  first geographical theory, and the effect of Herodotus's hypothesis
+  that the Nile must flow from west to east before turning north in
+  order to balance the Danube running from west to east before turning
+  south lingered in the maps of Africa down to the time of Mungo
+  Park.[3]
+
+
+    Aristotle and the sphere.
+
+  To Aristotle (384-322 B.C.) must be given the distinction of founding
+  scientific geography. He demonstrated the sphericity of the earth by
+  three arguments, two of which could be tested by observation. These
+  were: (1) that the earth must be spherical, because of the tendency of
+  matter to fall together towards a common centre; (2) that only a
+  sphere could always throw a circular shadow on the moon during an
+  eclipse; and (3) that the shifting of the horizon and the appearance
+  of new constellations, or the disappearance of familiar stars, as one
+  travelled from north to south, could only be explained on the
+  hypothesis that the earth was a sphere. Aristotle, too, gave greater
+  definiteness to the idea of zones conceived by Parmenides, who had
+  pictured a torrid zone uninhabitable by reason of heat, two frigid
+  zones uninhabitable by reason of cold, and two intermediate temperate
+  zones fit for human occupation. Aristotle defined the temperate zone
+  as extending from the tropic to the arctic circle, but there is some
+  uncertainty as to the precise meaning he gave to the term "arctic
+  circle." Soon after his time, however, this conception was clearly
+  established, and with so large a generalization the mental horizon was
+  widened to conceive of a geography which was a science. Aristotle had
+  himself shown that in the southern temperate zone winds similar to
+  those of the northern temperate zone should blow, but from the
+  opposite direction.
+
+
+    Fitting the oekumene to the sphere.
+
+  While the theory of the sphere was being elaborated the efforts of
+  practical geographers were steadily directed towards ascertaining the
+  outline and configuration of the _oekumene_, or habitable world, the
+  only portion of the terrestrial surface known to the ancients and to
+  the medieval peoples, and still retaining a shadow of its old monopoly
+  of geographical attention in its modern name of the "Old World." The
+  fitting of the _oekumene_ to the sphere was the second theoretical
+  problem. The circular outline had given way in geographical opinion to
+  the elliptical with the long axis lying east and west, and Aristotle
+  was inclined to view it as a very long and relatively narrow band
+  almost encircling the globe in the temperate zone. His argument as to
+  the narrowness of the sea between West Africa and East Asia, from the
+  occurrence of elephants at both extremities, is difficult to
+  understand, although it shows that he looked on the distribution of
+  animals as a problem of geography.
+
+
+    Problem of the Antipodes.
+
+  Pythagoras had speculated as to the existence of antipodes, but it was
+  not until the first approximately accurate measurements of the globe
+  and estimates of the length and breadth of the _oekumene_ were made by
+  Eratosthenes (c. 250 B.C.) that the fact that, as then known, it
+  occupied less than a quarter of the surface of the sphere was clearly
+  recognized. It was natural, if not strictly logical, that the ocean
+  river should be extended from a narrow stream to a world-embracing
+  sea, and here again Greek theory, or rather fancy, gave its modern
+  name to the greatest feature of the globe. The old instinctive idea of
+  symmetry must often have suggested other _oekumene_ balancing the
+  known world in the other quarters of the globe. The Stoic
+  philosophers, especially Crates of Mallus, arguing from the love of
+  nature for life, placed an _oekumene_ in each quarter of the sphere,
+  the three unknown world-islands being those of the Antoeci, Perioeci
+  and Antipodes. This was a theory not only attractive to the
+  philosophical mind, but eminently adapted to promote exploration. It
+  had its opponents, however, for Herodotus showed that sea-basins
+  existed cut off from the ocean, and it is still a matter of
+  controversy how far the pre-Ptolemaic geographers believed in a
+  water-connexion between the Atlantic and Indian oceans. It is quite
+  clear that Pomponius Mela (c. A.D. 40), following Strabo, held that
+  the southern temperate zone contained a habitable land, which he
+  designated by the name _Antichthones_.
+
+
+    Aristotle's geographical views.
+
+  Aristotle left no work on geography, so that it is impossible to know
+  what facts he associated with the science of the earth's surface. The
+  word geography did not appear before Aristotle, the first use of it
+  being in the [Greek: Peri kosmon], which is one of the writings
+  doubtfully ascribed to him, and H. Berger considers that the
+  expression was introduced by Eratosthenes.[4] Aristotle was certainly
+  conversant with many facts, such as the formation of deltas,
+  coast-erosion, and to a certain extent the dependence of plants and
+  animals on their physical surroundings. He formed a comprehensive
+  theory of the variations of climate with latitude and season, and was
+  convinced of the necessity of a circulation of water between the sea
+  and rivers, though, like Plato, he held that this took place by water
+  rising from the sea through crevices in the rocks, losing its
+  dissolved salts in the process. He speculated on the differences in
+  the character of races of mankind living in different climates, and
+  correlated the political forms of communities with their situation on
+  a seashore, or in the neighbourhood of natural strongholds.
+
+
+    Strabo.
+
+  Strabo (c. 50 B.C.-A.D. 24) followed Eratosthenes rather than
+  Aristotle, but with sympathies which went out more to the human
+  interests than the mathematical basis of geography. He compiled a very
+  remarkable work dealing, in large measure from personal travel, with
+  the countries surrounding the Mediterranean. He may be said to have
+  set the pattern which was followed in succeeding ages by the compilers
+  of "political geographies" dealing less with theories than with
+  facts, and illustrating rather than formulating the principles of the
+  science.
+
+
+    Ptolemy.
+
+  Claudius Ptolemaeus (c. A.D. 150) concentrated in his writings the
+  final outcome of all Greek geographical learning, and passed it across
+  the gulf of the middle ages by the hands of the Arabs, to form the
+  starting-point of the science in modern times. His geography was based
+  more immediately on the work of his predecessor, Marinus of Tyre, and
+  on that of Hipparchus, the follower and critic of Eratosthenes. It was
+  the ambition of Ptolemy to describe and represent accurately the
+  surface of the _oekumene_, for which purpose he took immense trouble
+  to collect all existing determinations of the latitude of places, all
+  estimates of longitude, and to make every possible rectification in
+  the estimates of distances by land or sea. His work was mainly
+  cartographical in its aim, and theory was as far as possible excluded.
+  The symmetrically placed hypothetical islands in the great continuous
+  ocean disappeared, and the _oekumene_ acquired a new form by the
+  representation of the Indian Ocean as a larger Mediterranean
+  completely cut off by land from the Atlantic. The _terra incognita_
+  uniting Africa and Farther Asia was an unfortunate hypothesis which
+  helped to retard exploration. Ptolemy used the word _geography_ to
+  signify the description of the whole _oekumene_ on mathematical
+  principles, while _chorography_ signified the fuller description of a
+  particular region, and _topography_ the very detailed description of a
+  smaller locality. He introduced the simile that geography represented
+  an artist's sketch of a whole portrait, while chorography corresponded
+  to the careful and detailed drawing of an eye or an ear.[5]
+
+  The Caliph al-Mam[ = u]n (c. A.D. 815), the son and successor of H[ =
+  a]r[ = u]n al-Rash[ = i]d, caused an Arabic version of Ptolemy's great
+  astronomical work ([Greek: Suntaxis megiste]) to be made, which is
+  known as the _Almagest_, the word being nothing more than the Gr.
+  [Greek: megiste] with the Arabic article _al_ prefixed. The geography
+  of Ptolemy was also known and is constantly referred to by Arab
+  writers. The Arab astronomers measured a degree on the plains of
+  Mesopotamia, thereby deducing a fair approximation to the size of the
+  earth. The caliph's librarian, Abu Jafar Muhammad Ben Musa, wrote a
+  geographical work, now unfortunately lost, entitled _Rasm el Arsi_ ("A
+  Description of the World"), which is often referred to by subsequent
+  writers as having been composed on the model of that of Ptolemy.
+
+
+    Geography in the middle ages.
+
+  The middle ages saw geographical knowledge die out in Christendom,
+  although it retained, through the Arabic translations of Ptolemy, a
+  certain vitality in Islam. The verbal interpretation of Scripture led
+  Lactantius (c. A.D. 320) and other ecclesiastics to denounce the
+  spherical theory of the earth as heretical. The wretched subterfuge of
+  Cosmas (c. A.D. 550) to explain the phenomena of the apparent
+  movements of the sun by means of an earth modelled on the plan of the
+  Jewish Tabernacle gave place ultimately to the wheel-maps--the T in an
+  O--which reverted to the primitive ignorance of the times of Homer and
+  Hecataeus.[6]
+
+  The journey of Marco Polo, the increasing trade to the East and the
+  voyages of the Arabs in the Indian Ocean prepared the way for the
+  reacceptance of Ptolemy's ideas when the sealed books of the Greek
+  original were translated into Latin by Angelus in 1410.
+
+
+    Revival of geography.
+
+  The old arguments of Aristotle and the old measurements of Ptolemy
+  were used by Toscanelli and Columbus in urging a westward voyage to
+  India; and mainly on this account did the crossing of the Atlantic
+  rank higher in the history of scientific geography than the laborious
+  feeling out of the coast-line of Africa. But not until the voyage of
+  Magellan shook the scales from the eyes of Europe did modern geography
+  begin to advance. Discovery had outrun theory; the rush of new facts
+  made Ptolemy practically obsolete in a generation, after having been
+  the fount and origin of all geography for a millennium.
+
+
+    Apianus.
+
+  The earliest evidence of the reincarnation of a sound theoretical
+  geography is to be found in the text-books by Peter Apian and
+  Sebastian Munster. Apian in his _Cosmographicus liber_, published in
+  1524, and subsequently edited and added to by Gemma Frisius under the
+  title of _Cosmographia_, based the whole science on mathematics and
+  measurement. He followed Ptolemy closely, enlarging on his distinction
+  between geography and chorography, and expressing the artistic analogy
+  in a rough diagram. This slender distinction was made much of by most
+  subsequent writers until Nathanael Carpenter in 1625 pointed out that
+  the difference between geography and chorography was simply one of
+  degree, not of kind.
+
+
+    Munster.
+
+  Sebastian Munster, on the other hand, in his _Cosmographia
+  universalis_ of 1544, paid no regard to the mathematical basis of
+  geography, but, following the model of Strabo, described the world
+  according to its different political divisions, and entered with great
+  zest into the question of the productions of countries, and into the
+  manners and costumes of the various peoples. Thus early commenced the
+  separation between what were long called mathematical and political
+  geography, the one subject appealing mainly to mathematicians, the
+  other to historians.
+
+  Throughout the 16th and 17th centuries the rapidly accumulating store
+  of facts as to the extent, outline and mountain and river systems of
+  the lands of the earth were put in order by the generation of
+  cartographers of which Mercator was the chief; but the writings of
+  Apian and Munster held the field for a hundred years without a serious
+  rival, unless the many annotated editions of Ptolemy might be so
+  considered. Meanwhile the new facts were the subject of original study
+  by philosophers and by practical men without reference to classical
+  traditions. Bacon argued keenly on geographical matters and was a
+  lover of maps, in which he observed and reasoned upon such
+  resemblances as that between the outlines of South America and Africa.
+
+
+    Cluverius.
+
+  Philip Cluver's _Introductio in geographiam universam tam veterem quam
+  novam_ was published in 1624. Geography he defined as "the description
+  of the whole earth, so far as it is known to us." It is distinguished
+  from cosmography by dealing with the earth alone, not with the
+  universe, and from chorography and topography by dealing with the
+  whole earth, not with a country or a place. The first book, of
+  fourteen short chapters, is concerned with the general properties of
+  the globe; the remaining six books treat in considerable detail of the
+  countries of Europe and of the other continents. Each country is
+  described with particular regard to its people as well as to its
+  surface, and the prominence given to the human element is of special
+  interest.
+
+
+    Carpenter.
+
+  A little-known book which appears to have escaped the attention of
+  most writers on the history of modern geography was published at
+  Oxford in 1625 by Nathanael Carpenter, fellow of Exeter College, with
+  the title _Geographie delineated forth in Two Bookes, containing the
+  Sphericall and Topicall parts thereof_. It is discursive in its style
+  and verbose; but, considering the period at which it appeared, it is
+  remarkable for the strong common sense displayed by the author, his
+  comparative freedom from prejudice, and his firm application of the
+  methods of scientific reasoning to the interpretation of phenomena.
+  Basing his work on the principles of Ptolemy, he brings together
+  illustrations from the most recent travellers, and does not hesitate
+  to take as illustrative examples the familiar city of Oxford and his
+  native county of Devon. He divides geography into _The Spherical
+  Part_, or that for the study of which mathematics alone is required,
+  and _The Topical Part_, or the description of the physical relations
+  of parts of the earth's surface, preferring this division to that
+  favoured by the ancient geographers--into general and special. It is
+  distinguished from other English geographical books of the period by
+  confining attention to the principles of geography, and not describing
+  the countries of the world.
+
+
+    Varenius.
+
+  A much more important work in the history of geographical method is
+  the _Geographia generalis_ of Bernhard Varenius, a German medical
+  doctor of Leiden, who died at the age of twenty-eight in 1650, the
+  year of the publication of his book. Although for a time it was lost
+  sight of on the continent, Sir Isaac Newton thought so highly of this
+  book that he prepared an annotated edition which was published in
+  Cambridge in 1672, with the addition of the plates which had been
+  planned by Varenius, but not produced by the original publishers. "The
+  reason why this great man took so much care in correcting and
+  publishing our author was, because he thought him necessary to be read
+  by his audience, the young gentlemen of Cambridge, while he was
+  delivering lectures on the same subject from the Lucasian Chair."[7]
+  The treatise of Varenius is a model of logical arrangement and terse
+  expression; it is a work of science and of genius; one of the few of
+  that age which can still be studied with profit. The English
+  translation renders the definition thus: "Geography is that part of
+  _mixed mathematics_ which explains the state of the earth and of its
+  parts, depending on quantity, viz. its figure, place, magnitude and
+  motion, with the celestial appearances, &c. By some it is taken in too
+  limited a sense, for a bare description of the several countries; and
+  by others too extensively, who along with such a description would
+  have their political constitution."
+
+  Varenius was reluctant to include the human side of geography in his
+  system, and only allowed it as a concession to custom, and in order to
+  attract readers by imparting interest to the sterner details of the
+  science. His division of geography was into two parts--(i.) General or
+  universal, dealing with the earth in general, and explaining its
+  properties without regard to particular countries; and (ii.) Special
+  or particular, dealing with each country in turn from the
+  chorographical or topographical point of view. General geography was
+  divided into--(1) the _Absolute_ part, dealing with the form,
+  dimensions, position and substance of the earth, the distribution of
+  land and water, mountains, woods and deserts, hydrography (including
+  all the waters of the earth) and the atmosphere; (2) the _Relative_
+  part, including the celestial properties, i.e. latitude, climate
+  zones, longitude, &c.; and (3) the _Comparative_ part, which
+  "considers the particulars arising from comparing one part with
+  another"; but under this head the questions discussed were longitude,
+  the situation and distances of places, and navigation. Varenius does
+  not treat of special geography, but gives a scheme for it under three
+  heads--(1) _Terrestrial_, including position, outline, boundaries,
+  mountains, mines, woods and deserts, waters, fertility and fruits, and
+  living creatures; (2) _Celestial_, including appearance of the heavens
+  and the climate; (3) _Human_, but this was added out of deference to
+  popular usage.
+
+  This system of geography founded a new epoch, and the book--translated
+  into English, Dutch and French--was the unchallenged standard for more
+  than a century. The framework was capable of accommodating itself to
+  new facts, and was indeed far in advance of the knowledge of the
+  period. The method included a recognition of the causes and effects of
+  phenomena as well as the mere fact of their occurrence, and for the
+  first time the importance of the vertical relief of the land was
+  fairly recognized.
+
+  The physical side of geography continued to be elaborated after
+  Varenius's methods, while the historical side was developed
+  separately. Both branches, although enriched by new facts, remained
+  stationary so far as method is concerned until nearly the end of the
+  18th century. The compilation of "geography books" by uninstructed
+  writers led to the pernicious habit, which is not yet wholly overcome,
+  of reducing the general or "physical" part to a few pages of
+  concentrated information, and expanding the particular or "political"
+  part by including unrevised travellers' stories and uncritical
+  descriptions of the various countries of the world. Such books were in
+  fact not geography, but merely compressed travel.
+
+
+    Bergman.
+
+  The next marked advance in the theory of geography may be taken as the
+  nearly simultaneous studies of the physical earth carried out by the
+  Swedish chemist, Torbern Bergman, acting under the impulse of
+  Linnaeus, and by the German philosopher, Immanuel Kant. Bergman's
+  _Physical Description of the Earth_ was published in Swedish in 1766,
+  and translated into English in 1772 and into German in 1774. It is a
+  plain, straightforward description of the globe, and of the various
+  phenomena of the surface, dealing only with definitely ascertained
+  facts in the natural order of their relationships, but avoiding any
+  systematic classification or even definitions of terms.
+
+
+    Kant.
+
+  The problems of geography had been lightened by the destructive
+  criticism of the French cartographer D'Anville (who had purged the map
+  of the world of the last remnants of traditional fact unverified by
+  modern observations) and rendered richer by the dawn of the new era of
+  scientific travel, when Kant brought his logical powers to bear upon
+  them. Kant's lectures on physical geography were delivered in the
+  university of Konigsberg from 1765 onwards.[8] Geography appealed to
+  him as a valuable educational discipline, the joint foundation with
+  anthropology of that "knowledge of the world" which was the result of
+  reason and experience. In this connexion he divided the communication
+  of experience from one person to another into two categories--the
+  narrative or historical and the descriptive or geographical; both
+  history and geography being viewed as descriptions, the former a
+  description in order of time, the latter a description in order of
+  space.
+
+  Physical geography he viewed as a summary of nature, the basis not
+  only of history but also of "all the other possible geographies," of
+  which he enumerates five, viz. (1) _Mathematical geography_, which
+  deals with the form, size and movements of the earth and its place in
+  the solar system; (2) _Moral geography_, or an account of the
+  different customs and characters of mankind according to the region
+  they inhabit; (3) _Political geography_, the divisions according to
+  their organized governments; (4) _Mercantile geography_, dealing with
+  the trade in the surplus products of countries; (5) _Theological
+  geography_, or the distribution of religions. Here there is a clear
+  and formal statement of the interaction and causal relation of all the
+  phenomena of distribution on the earth's surface, including the
+  influence of physical geography upon the various activities of mankind
+  from the lowest to the highest. Notwithstanding the form of this
+  classification, Kant himself treats mathematical geography as
+  preliminary to, and therefore not dependent on, physical geography.
+  Physical geography itself is divided into two parts: a general, which
+  has to do with the earth and all that belongs to it--water, air and
+  land; and a particular, which deals with special products of the
+  earth--mankind, animals, plants and minerals. Particular importance is
+  given to the vertical relief of the land, on which the various
+  branches of human geography are shown to depend.
+
+
+    Humboldt.
+
+  Alexander von Humboldt (1769-1859) was the first modern geographer to
+  become a great traveller, and thus to acquire an extensive stock of
+  first-hand information on which an improved system of geography might
+  be founded. The impulse given to the study of natural history by the
+  example of Linnaeus; the results brought back by Sir Joseph Banks, Dr
+  Solander and the two Forsters, who accompanied Cook in his voyages of
+  discovery; the studies of De Saussure in the Alps, and the lists of
+  desiderata in physical geography drawn up by that investigator,
+  combined to prepare the way for Humboldt. The theory of geography was
+  advanced by Humboldt mainly by his insistence on the great principle
+  of the unity of nature. He brought all the "observable things," which
+  the eager collectors of the previous century had been heaping together
+  regardless of order or system, into relation with the vertical relief
+  and the horizontal forms of the earth's surface. Thus he demonstrated
+  that the forms of the land exercise a directive and determining
+  influence on climate, plant life, animal life and on man himself. This
+  was no new idea; it had been familiar for centuries in a less definite
+  form, deduced from a priori considerations, and so far as regards the
+  influence of surrounding circumstances upon man, Kant had already
+  given it full expression. Humboldt's concrete illustrations and the
+  remarkable power of his personality enabled him to enforce these
+  principles in a way that produced an immediate and lasting effect. The
+  treatises on physical geography by Mrs Mary Somerville and Sir John
+  Herschel (the latter written for the eighth edition of the
+  _Encyclopaedia Britannica_) showed the effect produced in Great
+  Britain by the stimulus of Humboldt's work.
+
+
+    Ritter.
+
+  Humboldt's contemporary, Carl Ritter (1779-1859), extended and
+  disseminated the same views, and in his interpretation of "Comparative
+  Geography" he laid stress on the importance of forming conclusions,
+  not from the study of one region by itself, but from the comparison of
+  the phenomena of many places. Impressed by the influence of
+  terrestrial relief and climate on human movements, Ritter was led
+  deeper and deeper into the study of history and archaeology. His
+  monumental _Vergleichende Geographie_, which was to have made the
+  whole world its theme, died out in a wilderness of detail in
+  twenty-one volumes before it had covered more of the earth's surface
+  than Asia and a portion of Africa. Some of his followers showed a
+  tendency to look on geography rather as an auxiliary to history than
+  as a study of intrinsic worth.
+
+
+    Geography as a natural science.
+
+  During the rapid development of physical geography many branches of
+  the study of nature, which had been included in the cosmography of the
+  early writers, the physiography of Linnaeus and even the _Erdkunde_ of
+  Ritter, had been so much advanced by the labours of specialists that
+  their connexion was apt to be forgotten. Thus geology, meteorology,
+  oceanography and anthropology developed into distinct sciences. The
+  absurd attempt was, and sometimes is still, made by geographers to
+  include all natural science in geography; but it is more common for
+  specialists in the various detailed sciences to think, and sometimes
+  to assert, that the ground of physical geography is now fully occupied
+  by these sciences. Political geography has been too often looked on
+  from both sides as a mere summary of guide-book knowledge, useful in
+  the schoolroom, a poor relation of physical geography that it was
+  rarely necessary to recognize.
+
+  The science of geography, passed on from antiquity by Ptolemy,
+  re-established by Varenius and Newton, and systematized by Kant,
+  included within itself definite aspects of all those terrestrial
+  phenomena which are now treated exhaustively under the heads of
+  geology, meteorology, oceanography and anthropology; and the inclusion
+  of the requisite portions of the perfected results of these sciences
+  in geography is simply the gathering in of fruit matured from the seed
+  scattered by geography itself.
+
+  The study of geography was advanced by improvements in cartography
+  (see MAP), not only in the methods of survey and projection, but in
+  the representation of the third dimension by means of contour lines
+  introduced by Philippe Buache in 1737, and the more remarkable because
+  less obvious invention of isotherms introduced by Humboldt in 1817.
+
+
+    The teleological argument in geography.
+
+  The "argument from design" had been a favourite form of reasoning
+  amongst Christian theologians, and, as worked out by Paley in his
+  _Natural Theology_, it served the useful purpose of emphasizing the
+  fitness which exists between all the inhabitants of the earth and
+  their physical environment. It was held that the earth had been
+  created so as to fit the wants of man in every particular. This
+  argument was tacitly accepted or explicitly avowed by almost every
+  writer on the theory of geography, and Carl Ritter distinctly
+  recognized and adopted it as the unifying principle of his system. As
+  a student of nature, however, he did not fail to see, and as professor
+  of geography he always taught, that man was in very large measure
+  conditioned by his physical environment. The apparent opposition of
+  the observed fact to the assigned theory he overcame by looking upon
+  the forms of the land and the arrangement of land and sea as
+  instruments of Divine Providence for guiding the destiny as well as
+  for supplying the requirements of man. This was the central theme of
+  Ritter's philosophy; his religion and his geography were one, and the
+  consequent fervour with which he pursued his mission goes far to
+  account for the immense influence he acquired in Germany.
+
+
+    The theory of evolution in geography.
+
+  The evolutionary theory, more than hinted at in Kant's "Physical
+  Geography," has, since the writings of Charles Darwin, become the
+  unifying principle in geography. The conception of the development of
+  the plan of the earth from the first cooling of the surface of the
+  planet throughout the long geological periods, the guiding power of
+  environment on the circulation of water and of air, on the
+  distribution of plants and animals, and finally on the movements of
+  man, give to geography a philosophical dignity and a scientific
+  completeness which it never previously possessed. The influence of
+  environment on the organism may not be quite so potent as it was once
+  believed to be, in the writings of Buckle, for instance,[9] and
+  certainly man, the ultimate term in the series, reacts upon and
+  greatly modifies his environment; yet the fact that environment does
+  influence all distributions is established beyond the possibility of
+  doubt. In this way also the position of geography, at the point where
+  physical science meets and mingles with mental science, is explained
+  and justified. The change which took place during the 19th century in
+  the substance and style of geography may be well seen by comparing the
+  eight volumes of Malte-Brun's _Geographie universelle_ (Paris,
+  1812-1829) with the twenty-one volumes of Reclus's _Geographie
+  universelle_ (Paris, 1876-1895).
+
+  In estimating the influence of recent writers on geography it is usual
+  to assign to Oscar Peschel (1826-1875) the credit of having corrected
+  the preponderance which Ritter gave to the historical element, and of
+  restoring physical geography to its old pre-eminence.[10] As a matter
+  of fact, each of the leading modern exponents of theoretical
+  geography--such as Ferdinand von Richthofen, Hermann Wagner, Friedrich
+  Ratzel, William M. Davis, A. Penck, A. de Lapparent and Elisee
+  Reclus--has his individual point of view, one devoting more attention
+  to the results of geological processes, another to anthropological
+  conditions, and the rest viewing the subject in various blendings of
+  the extreme lights.
+
+  The two conceptions which may now be said to animate the theory of
+  geography are the genetic, which depends upon processes of origin, and
+  the morphological, which depends on facts of form and distribution.
+
+
+  PROGRESS OF GEOGRAPHICAL DISCOVERY
+
+  Exploration and geographical discovery must have started from more
+  than one centre, and to deal justly with the matter one ought to treat
+  of these separately in the early ages before the whole civilized world
+  was bound together by the bonds of modern intercommunication. At the
+  least there should be some consideration of four separate systems of
+  discovery--the Eastern, in which Chinese and Japanese explorers
+  acquired knowledge of the geography of Asia, and felt their way
+  towards Europe and America; the Western, in which the dominant races
+  of the Mexican and South American plateaus extended their knowledge of
+  the American continent before Columbus; the Polynesian, in which the
+  conquering races of the Pacific Islands found their way from group to
+  group; and the Mediterranean. For some of these we have no certain
+  information, and regarding others the tales narrated in the early
+  records are so hard to reconcile with present knowledge that they are
+  better fitted to be the battle-ground of scholars championing rival
+  theories than the basis of definite history. So it has come about that
+  the only practicable history of geographical exploration starts from
+  the Mediterranean centre, the first home of that civilization which
+  has come to be known as European, though its field of activity has
+  long since overspread the habitable land of both temperate zones,
+  eastern Asia alone in part excepted.
+
+  From all centres the leading motives of exploration were probably the
+  same--commercial intercourse, warlike operations, whether resulting in
+  conquest or in flight, religious zeal expressed in pilgrimages or
+  missionary journeys, or, from the other side, the avoidance of
+  persecution, and, more particularly in later years, the advancement of
+  knowledge for its own sake. At different times one or the other motive
+  predominated.
+
+  Before the 14th century B.C. the warrior kings of Egypt had carried
+  the power of their arms southward from the delta of the Nile well-nigh
+  to its source, and eastward to the confines of Assyria. The
+  hieroglyphic inscriptions of Egypt and the cuneiform inscriptions of
+  Assyria are rich in records of the movements and achievements of
+  armies, the conquest of towns and the subjugation of peoples; but
+  though many of the recorded sites have been identified, their
+  discovery by wandering armies was isolated from their subsequent
+  history and need not concern us here.
+
+
+    The Phoenicians.
+
+  The Phoenicians are the earliest Mediterranean people in the
+  consecutive chain of geographical discovery which joins pre-historic
+  time with the present. From Sidon, and later from its more famous
+  rival Tyre, the merchant adventurers of Phoenicia explored and
+  colonized the coasts of the Mediterranean and fared forth into the
+  ocean beyond. They traded also on the Red sea, and opened up regular
+  traffic with India as well as with the ports of the south and west, so
+  that it was natural for Solomon to employ the merchant navies of Tyre
+  in his oversea trade. The western emporium known in the scriptures as
+  Tarshish was probably situated in the south of Spain, possibly at
+  Cadiz, although some writers contend that it was Carthage in North
+  Africa. Still more diversity of opinion prevails as to the southern
+  gold-exporting port of Ophir, which some scholars place in Arabia,
+  others at one or another point on the east coast of Africa. Whether
+  associated with the exploitation of Ophir (q.v.) or not the first
+  great voyage of African discovery appears to have been accomplished by
+  the Phoenicians sailing the Red Sea. Herodotus (himself a notable
+  traveller in the 5th century B.C.) relates that the Egyptian king
+  Necho of the XXVIth Dynasty (c. 600 B.C.) built a fleet on the Red
+  Sea, and confided it to Phoenician sailors with the orders to sail
+  southward and return to Egypt by the Pillars of Hercules and the
+  Mediterranean sea. According to the tradition, which Herodotus quotes
+  sceptically, this was accomplished; but the story is too vague to be
+  accepted as more than a possibility.
+
+  The great Phoenician colony of Carthage, founded before 800 B.C.,
+  perpetuated the commercial enterprise of the parent state, and
+  extended the sphere of practical trade to the ocean shores of Africa
+  and Europe. The most celebrated voyage of antiquity undertaken for the
+  express purpose of discovery was that fitted out by the senate of
+  Carthage under the command of Hanno, with the intention of founding
+  new colonies along the west coast of Africa. According to Pliny, the
+  only authority on this point, the period of the voyage was that of the
+  greatest prosperity of Carthage, which may be taken as somewhere
+  between 570 and 480 B.C. The extent of this voyage is doubtful, but it
+  seems probable that the farthest point reached was on the east-running
+  coast which bounds the Gulf of Guinea on the north. Himilco, a
+  contemporary of Hanno, was charged with an expedition along the west
+  coast of Iberia northward, and as far as the uncertain references to
+  this voyage can be understood, he seems to have passed the Bay of
+  Biscay and possibly sighted the coast of England.
+
+
+    The Greeks.
+
+  The sea power of the Greek communities on the coast of Asia Minor and
+  in the Archipelago began to be a formidable rival to the Phoenician
+  soon after the time of Hanno and Himilco, and peculiar interest
+  attaches to the first recorded Greek voyage beyond the Pillars of
+  Hercules. Pytheas, a navigator of the Phocean colony of Massilia
+  (Marseilles), determined the latitude of that port with considerable
+  precision by the somewhat clumsy method of ascertaining the length of
+  the longest day, and when, about 330 B.C., he set out on exploration
+  to the northward in search of the lands whence came gold, tin and
+  amber, he followed this system of ascertaining his position from time
+  to time. If on each occasion he himself made the observations his
+  voyage must have extended over six years; but it is not impossible
+  that he ascertained the approximate length of the longest day in some
+  cases by questioning the natives. Pytheas, whose own narrative is not
+  preserved, coasted the Bay of Biscay, sailed up the English Channel
+  and followed the coast of Britain to its most northerly point. Beyond
+  this he spoke of a land called _Thule_, which, if his estimate of the
+  length of the longest day is correct, may have been Shetland, but was
+  possibly Iceland; and from some confused statements as to a sea which
+  could not be sailed through, it has been assumed that Pytheas was the
+  first of the Greeks to obtain direct knowledge of the Arctic regions.
+  During this or a second voyage Pytheas entered the Baltic, discovered
+  the coasts where amber is obtained and returned to the Mediterranean.
+  It does not seem that any maritime trade followed these discoveries,
+  and indeed it is doubtful whether his contemporaries accepted the
+  truth of Pytheas's narrative; Strabo four hundred years later
+  certainly did not, but the critical studies of modern scholars have
+  rehabilitated the Massilian explorer.
+
+
+    Alexander the Great.
+
+  The Greco-Persian wars had made the remoter parts of Asia Minor more
+  than a name to the Greek geographers before the time of Alexander the
+  Great, but the campaigns of that conqueror from 329 to 325 B.C. opened
+  up the greater Asia to the knowledge of Europe. His armies crossed the
+  plains beyond the Caspian, penetrated the wild mountain passes
+  north-west of India, and did not turn back until they had entered on
+  the Indo-Gangetic plain. This was one of the few great epochs of
+  geographical discovery.
+
+  The world was henceforth viewed as a very large place stretching far
+  on every side beyond the Midland or Mediterranean Sea, and the land
+  journey of Alexander resulted in a voyage of discovery in the outer
+  ocean from the mouth of the Indus to that of the Tigris, thus opening
+  direct intercourse between Grecian and Hindu civilization. The Greeks
+  who accompanied Alexander described with care the towns and villages,
+  the products and the aspect of the country. The conqueror also
+  intended to open up trade by sea between Europe and India, and the
+  narrative of his general Nearchus records this famous voyage of
+  discovery, the detailed accounts of the chief pilot Onesicritus being
+  lost. At the beginning of October 326 B.C. Nearchus left the Indus
+  with his fleet, and the anchorages sought for each night are carefully
+  recorded. He entered the Persian Gulf, and rejoined Alexander at Susa,
+  when he was ordered to prepare another expedition for the
+  circumnavigation of Arabia. Alexander died at Babylon in 323 B.C., and
+  the fleet was dispersed without making the voyage.
+
+  The dynasties founded by Alexander's generals, Seleucus, Antiochus and
+  Ptolemy, encouraged the same spirit of enterprise which their master
+  had fostered, and extended geographical knowledge in several
+  directions. Seleucus Nicator established the Greco-Bactrian empire and
+  continued the intercourse with India. Authentic information respecting
+  the great valley of the Ganges was supplied by Megasthenes, an
+  ambassador sent by Seleucus, who reached the remote city of
+  Patali-putra, the modern Patna.
+
+
+    The Ptolemies.
+
+  The Ptolemies in Egypt showed equal anxiety to extend the bounds of
+  geographical knowledge. Ptolemy Euergetes (247-222 B.C.) rendered the
+  greatest service to geography by the protection and encouragement of
+  Eratosthenes, whose labours gave the first approximate knowledge of
+  the true size of the spherical earth. The second Euergetes and his
+  successor Ptolemy Lathyrus (118-115 B.C.) furnished Eudoxus with a
+  fleet to explore the Arabian sea. After two successful voyages,
+  Eudoxus, impressed with the idea that Africa was surrounded by ocean
+  on the south, left the Egyptian service, and proceeded to Cadiz and
+  other Mediterranean centres of trade seeking a patron who would
+  finance an expedition for the purpose of African discovery; and we
+  learn from Strabo that the veteran explorer made at least two voyages
+  southward along the coast of Africa. The Ptolemies continued to send
+  fleets annually from their Red Sea ports of Berenice and Myos Hormus
+  to Arabia, as well as to ports on the coasts of Africa and India.
+
+
+    The Romans.
+
+  The Romans did not encourage navigation and commerce with the same
+  ardour as their predecessors; still the luxury of Rome, which gave
+  rise to demands for the varied products of all the countries of the
+  known world, led to an active trade both by ships and caravans. But it
+  was the military genius of Rome, and the ambition for universal
+  empire, which led, not only to the discovery, but also to the survey
+  of nearly all Europe, and of large tracts in Asia and Africa. Every
+  new war produced a new survey and itinerary of the countries which
+  were conquered, and added one more to the imperishable roads that led
+  from every quarter of the known world to Rome. In the height of their
+  power the Romans had surveyed and explored all the coasts of the
+  Mediterranean, Italy, Greece, the Balkan Peninsula, Spain, Gaul,
+  western Germany and southern Britain. In Africa their empire included
+  Egypt, Carthage, Numidia and Mauritania. In Asia they held Asia Minor
+  and Syria, had sent expeditions into Arabia, and were acquainted with
+  the more distant countries formerly invaded by Alexander, including
+  Persia, Scythia, Bactria and India. Roman intercourse with India
+  especially led to the extension of geographical knowledge.
+
+  Before the Roman legions were sent into a new region to extend the
+  limits of the empire, it was usual to send out exploring expeditions
+  to report as to the nature of the country. It is narrated by Pliny and
+  Seneca that the emperor Nero sent out two centurions on such a mission
+  towards the source of the Nile (probably about A.D. 60), and that the
+  travellers pushed southwards until they reached vast marshes through
+  which they could not make their way either on foot or in boats. This
+  seems to indicate that they had penetrated to about 9 deg. N. Shortly
+  before A.D. 79 Hippalus took advantage of the regular alternation of
+  the monsoons to make the voyage from the Red Sea to India across the
+  open ocean out of sight of land. Even though this sea-route was known,
+  the author of the _Periplus of the Erythraean Sea_, published after
+  the time of Pliny, recites the old itinerary around the coast of the
+  Arabian Gulf. It was, however, in the reigns of Severus and his
+  immediate successors that Roman intercourse with India was at its
+  height, and from the writings of Pausanias (c. 174) it appears that
+  direct communication between Rome and China had already taken place.
+
+  After the division of the Roman empire, Constantinople became the last
+  refuge of learning, arts and taste; while Alexandria continued to be
+  the emporium whence were imported the commodities of the East. The
+  emperor Justinian (483-565), in whose reign the greatness of the
+  Eastern empire culminated, sent two Nestorian monks to China, who
+  returned with eggs of the silkworm concealed in a hollow cane, and
+  thus silk manufactures were established in the Peloponnesus and the
+  Greek islands. It was also in the reign of Justinian that Cosmas
+  Indicopleustes, an Egyptian merchant, made several voyages, and
+  afterwards composed his [Greek: Christianike topographia] (Christian
+  Topography), containing, in addition to his absurd cosmogony, a
+  tolerable description of India.
+
+
+    The Arabs.
+
+  The great outburst of Mahommedan conquest in the 7th century was
+  followed by the Arab civilization, having its centres at Bagdad and
+  Cordova, in connexion with which geography again received a share of
+  attention. The works of the ancient Greek geographers were translated
+  into Arabic, and starting with a sound basis of theoretical knowledge,
+  exploration once more made progress. From the 9th to the 13th century
+  intelligent Arab travellers wrote accounts of what they had seen and
+  heard in distant lands. The earliest Arabian traveller whose
+  observations have come down to us is the merchant Sulaiman, who
+  embarked in the Persian Gulf and made several voyages to India and
+  China, in the middle of the 9th century. Abu Zaid also wrote on India,
+  and his work is the most important that we possess before the
+  epoch-making discoveries of Marco Polo. Masudi, a great traveller who
+  knew from personal experience all the countries between Spain and
+  China, described the plains, mountains and seas, the dynasties and
+  peoples, in his _Meadows of Gold_, an abstract made by himself of his
+  larger work _News of the Time_. He died in 956, and was known, from
+  the comprehensiveness of his survey, as the Pliny of the East. Amongst
+  his contemporaries were Istakhri, who travelled through all the
+  Mahommedan countries and wrote his _Book of Climates_ in 950, and Ibn
+  Haukal, whose _Book of Roads and Kingdoms_, based on the work of
+  Istakhri, was written in 976. Idrisi, the best known of the Arabian
+  geographical authors, after travelling far and wide in the first half
+  of the 12th century, settled in Sicily, where he wrote a treatise
+  descriptive of an armillary sphere which he had constructed for Roger
+  II., the Norman king, and in this work he incorporated all accessible
+  results of contemporary travel.
+
+
+    The Northmen.
+
+  The Northmen of Denmark and Norway, whose piratical adventures were
+  the terror of all the coasts of Europe, and who established themselves
+  in Great Britain and Ireland, in France and Sicily, were also
+  geographical explorers in their rough but practical way during the
+  darkest period of the middle ages. All Northmen were not bent on
+  rapine and plunder; many were peaceful merchants. Alfred the Great,
+  king of the Saxons in England, not only educated his people in the
+  learning of the past ages; he inserted in the geographical works he
+  translated many narratives of the travel of his own time. Thus he
+  placed on record the voyages of the merchant Ulfsten in the Baltic,
+  including particulars of the geography of Germany. And in particular
+  he told of the remarkable voyage of Other, a Norwegian of Helgeland,
+  who was the first authentic Arctic explorer, the first to tell of the
+  rounding of the North Cape and the sight of the midnight sun. This
+  voyage of the middle of the 9th century deserves to be held in happy
+  memory, for it unites the first Norwegian polar explorer with the
+  first English collector of travels. Scandinavian merchants brought the
+  products of India to England and Ireland. From the 8th to the 11th
+  century a commercial route from India passed through Novgorod to the
+  Baltic, and Arabian coins found in Sweden, and particularly in the
+  island of Gotland, prove how closely the enterprise of the Northmen
+  and of the Arabs intertwined. Five-sixths of these coins preserved at
+  Stockholm were from the mints of the Samanian dynasty, which reigned
+  in Khorasan and Transoxiana from about A.D. 900 to 1000. It was the
+  trade with the East that originally gave importance to the city of
+  Visby in Gotland.
+
+  In the end of the 9th century Iceland was colonized from Norway; and
+  about 985 the intrepid viking, Eric the Red, discovered Greenland, and
+  induced some of his Icelandic countrymen to settle on its inhospitable
+  shores. His son, Leif Ericsson, and others of his followers were
+  concerned in the discovery of the North American coast (see VINLAND),
+  which, but for the isolation of Iceland from the centres of European
+  awakening, would have had momentous consequences. As things were, the
+  importance of this discovery passed unrecognized. The story of two
+  Venetians, Nicolo and Antonio Zeno, who gave a vague account of
+  voyages in the northern seas in the end of the 13th century, is no
+  longer to be accepted as history.
+
+
+    Close of the dark ages.
+
+  At length the long period of barbarism which accompanied and followed
+  the fall of the Roman empire drew to a close in Europe. The Crusades
+  had a favourable influence on the intellectual state of the Western
+  nations. Interesting regions, known only by the scant reports of
+  pilgrims, were made the objects of attention and study; while
+  religious zeal, and the hope of gain, combined with motives of mere
+  curiosity, induced several persons to travel by land into remote
+  regions of the East, far beyond the countries to which the operations
+  of the crusaders extended. Among these was Benjamin of Tudela, who set
+  out from Spain in 1160, travelled by land to Constantinople, and
+  having visited India and some of the eastern islands, returned to
+  Europe by way of Egypt after an absence of thirteen years.
+
+
+    Asiatic journeys.
+
+  Joannes de Plano Carpini, a Franciscan monk, was the head of one of
+  the missions despatched by Pope Innocent to call the chief and people
+  of the Tatars to a better mind. He reached the headquarters of Batu,
+  on the Volga, in February 1246; and, after some stay, went on to the
+  camp of the great khan near Karakorum in central Asia, and returned
+  safely in the autumn of 1247. A few years afterwards, a Fleming named
+  Rubruquis was sent on a similar mission, and had the merit of being
+  the first traveller of this era who gave a correct account of the
+  Caspian Sea. He ascertained that it had no outlet. At nearly the same
+  time Hayton, king of Armenia, made a journey to Karakorum in 1254, by
+  a route far to the north of that followed by Carpini and Rubruquis. He
+  was treated with honour and hospitality, and returned by way of
+  Samarkand and Tabriz, to his own territory. The curious narrative of
+  King Hayton was translated by Klaproth.
+
+  While the republics of Italy, and above all the state of Venice, were
+  engaged in distributing the rich products of India and the Far East
+  over the Western world, it was impossible that motives of curiosity,
+  as well as a desire of commercial advantage, should not be awakened to
+  such a degree as to impel some of the merchants to visit those remote
+  lands. Among these were the brothers Polo, who traded with the East
+  and themselves visited Tatary. The recital of their travels fired the
+  youthful imagination of young Marco Polo, son of Nicolo, and he set
+  out for the court of Kublai Khan, with his father and uncle, in 1265.
+  Marco remained for seventeen years in the service of the Great Khan,
+  and was employed on many important missions. Besides what he learnt
+  from his own observation, he collected much information from others
+  concerning countries which he did not visit. He returned to Europe
+  possessed of a vast store of knowledge respecting the eastern parts of
+  the world, and, being afterwards made a prisoner by the Genoese, he
+  dictated the narrative of his travels during his captivity. The work
+  of Marco Polo is the most valuable narrative of travels that appeared
+  during the middle ages, and despite a cold reception and many denials
+  of the accuracy of the record, its substantial truthfulness has been
+  abundantly proved.
+
+  Missionaries continued to do useful geographical work. Among them were
+  John of Monte Corvino, a Franciscan monk, Andrew of Perugia, John
+  Marignioli and Friar Jordanus, who visited the west coast of India,
+  and above all Friar Odoric of Pordenone. Odoric set out on his travels
+  about 1318, and his journeys embraced parts of India, the Malay
+  Archipelago, China and even Tibet, where he was the first European to
+  enter Lhasa, not yet a forbidden city.
+
+  Ibn Batuta, the great Arab traveller, is separated by a wide space of
+  time from his countrymen already mentioned, and he finds his proper
+  place in a chronological notice after the days of Marco Polo, for he
+  did not begin his wanderings until 1325, his career thus coinciding in
+  time with the fabled journeyings of Sir John Mandeville. While Arab
+  learning flourished during the darkest ages of European ignorance, the
+  last of the Arab geographers lived to see the dawn of the great period
+  of the European awakening. Ibn Batuta went by land from Tangier to
+  Cairo, then visited Syria, and performed the pilgrimages to Medina and
+  Mecca. After exploring Persia, and again residing for some time at
+  Mecca, he made a voyage down the Red sea to Yemen, and travelled
+  through that country to Aden. Thence he visited the African coast,
+  touching at Mombasa and Quiloa, and then sailed across to Ormuz and
+  the Persian Gulf. He crossed Arabia from Bahrein to Jidda, traversed
+  the Red sea and the desert to Syene, and descended the Nile to Cairo.
+  After this he revisited Syria and Asia Minor, and crossed the Black
+  sea, the desert from Astrakhan to Bokhara, and the Hindu Kush. He was
+  in the service of Muhammad Tughluk, ruler of Delhi, about eight years,
+  and was sent on an embassy to China, in the course of which the
+  ambassadors sailed down the west coast of India to Calicut, and then
+  visited the Maldive Islands and Ceylon. Ibn Batuta made the voyage
+  through the Malay Archipelago to China, and on his return he proceeded
+  from Malabar to Bagdad and Damascus, ultimately reaching Fez, the
+  capital of his native country, in November 1349. After a journey into
+  Spain he set out once more for Central Africa in 1352, and reached
+  Timbuktu and the Niger, returning to Fez in 1353. His narrative was
+  committed to writing from his dictation.
+
+
+    Spanish exploration.
+
+  The European country which had come the most completely under the
+  influence of Arab culture now began to send forth explorers to distant
+  lands, though the impulse came not from the Moors but from Italian
+  merchant navigators in Spanish service. The peaceful reign of Henry
+  III. of Castile is famous for the attempts of that prince to extend
+  the diplomatic relations of Spain to the remotest parts of the earth.
+  He sent embassies to all the princes of Christendom and to the Moors.
+  In 1403 the Spanish king sent a knight of Madrid, Ruy Gonzalez de
+  Clavijo, to the distant court of Timur, at Samarkand. He returned in
+  1406, and wrote a valuable narrative of his travels.
+
+  Italians continued to make important journeys in the East during the
+  15th century. Among them was Nicolo Conti, who passed through Persia,
+  sailed along the coast of Malabar, visited Sumatra, Java and the south
+  of China, returned by the Red sea, and got home to Venice in 1444
+  after an absence of twenty-five years. He related his adventures to
+  Poggio Bracciolini, secretary to Pope Eugenius IV.; and the narrative
+  contains much interesting information. One of the most remarkable of
+  the Italian travellers was Ludovico di Varthema, who left his native
+  land in 1502. He went to Egypt and Syria, and for the sake of visiting
+  the holy cities became a Mahommedan. He was the first European who
+  gave an account of the interior of Yemen. He afterwards visited and
+  described many places in Persia, India and the Malay Archipelago,
+  returning to Europe in a Portuguese ship after an absence of five
+  years.
+
+
+    Portuguese exploration--Prince Henry the Navigator.
+
+  In the 15th century the time was approaching when the discovery of the
+  Cape of Good Hope was to widen the scope of geographical enterprise.
+  This great event was preceded by the general utilization in Europe of
+  the polarity of the magnetic needle in the construction of the
+  mariner's compass. Portugal took the lead along this new path, and
+  foremost among her pioneers stands Prince Henry the Navigator
+  (1394-1460), who was a patron both of exploration and of the study of
+  geographical theory. The great westward projection of the coast of
+  Africa, and the islands to the north-west of that continent, were the
+  principal scene of the work of the mariners sent out at his expense;
+  but his object was to push onward and reach India from the Atlantic.
+  The progress of discovery received a check on his death, but only for
+  a time. In 1462 Pedro de Cintra extended Portuguese exploration along
+  the African coast and discovered Sierra Leone. Fernan Gomez followed
+  in 1469, and opened trade with the Gold Coast; and in 1484 Diogo Cao
+  discovered the mouth of the Congo. The king of Portugal next
+  despatched Bartolomeu Diaz in 1486 to continue discoveries southwards;
+  while, in the following year, he sent Pedro de Covilhao and Affonso de
+  Payva to discover the country of Prester John. Diaz succeeded in
+  rounding the southern point of Africa, which he named Cabo
+  Tormentoso--the Cape of Storms--but King Joao II., foreseeing the
+  realization of the long-sought passage to India, gave it the
+  stimulating and enduring name of the Cape of Good Hope. Payva died at
+  Cairo; but Covilhao, having heard that a Christian ruler reigned in
+  the mountains of Ethiopia, penetrated into Abyssinia in 1490. He
+  delivered the letter which Joao II. had addressed to Prester John to
+  the Negus Alexander of Abyssinia, but he was detained by that prince
+  and never allowed to leave the country.
+
+
+    Columbus.
+
+  The Portuguese, following the lead of Prince Henry, continued to look
+  for the road to India by the Cape of Good Hope. The same end was
+  sought by Christopher Columbus, following the suggestion of
+  Toscanelli, and under-estimating the diameter of the globe, by sailing
+  due west. The voyages of Columbus (1492-1498) resulted in the
+  discovery of the West Indies and North America which barred the way to
+  the Far East. In 1493 the pope, Alexander VI., issued a bull
+  instituting the famous "line of demarcation" running from N. to S. 100
+  leagues W. of the Azores, to the west of which the Spaniards were
+  authorized to explore and to the east of which the Portuguese received
+  the monopoly of discovery. The direct line of Portuguese exploration
+  resulted in the discovery of the Cape route to India by Vasco da Gama
+  (1498), and in 1500 to the independent discovery of South America by
+  Pedro Alvarez Cabral. The voyages of Columbus and of Vasco da Gama
+  were so important that it is unnecessary to detail their results in
+  this place. See COLUMBUS, CHRISTOPHER; GAMA, VASCO DA.
+
+
+    Vasco da Gama.
+
+  The three voyages of Vasco da Gama (who died on the scene of his
+  labours, at Cochin, in 1524) revolutionized the commerce of the East.
+  Until then the Venetians held the carrying trade of India, which was
+  brought by the Persian Gulf and Red sea into Syria and Egypt, the
+  Venetians receiving the products of the East at Alexandria and Beirut
+  and distributing them over Europe. This commerce was a great source of
+  wealth to Venice; but after the discovery of the new passage round the
+  Cape, and the conquests of the Portuguese, the trade of the East
+  passed into other hands.
+
+
+    Spaniards in America.
+
+  The discoveries of Columbus awakened a spirit of enterprise in Spain
+  which continued in full force for a century; adventurers flocked
+  eagerly across the Atlantic, and discovery followed discovery in rapid
+  succession. Many of the companions of Columbus continued his work.
+  Vicente Yanez Pinzon in 1500 reached the mouth of the Amazon. In the
+  same year Alonso de Ojeda, accompanied by Juan de la Cosa, from whose
+  maps we learn much of the discoveries of the 16th century navigators,
+  and by a Florentine named Amerigo Vespucci, touched the coast of South
+  America somewhere near Surinam, following the shore as far as the Gulf
+  of Maracaibo. Vespucci afterwards made three voyages to the Brazilian
+  coast; and in 1504 he wrote an account of his four voyages, which was
+  widely circulated, and became the means of procuring for its author at
+  the hands of the cartographer Waldseemuller in 1507 the
+  disproportionate distinction of giving his name to the whole
+  continent. In 1508 Alonso de Ojeda obtained the government of the
+  coast of South America from Cabo de la Vela to the Gulf of Darien;
+  Ojeda landed at Cartagena in 1510, and sustained a defeat from the
+  natives, in which his lieutenant, Juan de la Cosa, was killed. After
+  another reverse on the east side of the Gulf of Darien Ojeda returned
+  to Hispaniola and died there. The Spaniards in the Gulf of Darien were
+  left by Ojeda under the command of Francisco Pizarro, the future
+  conqueror of Peru. After suffering much from famine and disease,
+  Pizarro resolved to leave, and embarked the survivors in small
+  vessels, but outside the harbour they met a ship which proved to be
+  that of Martin Fernandez Enciso, Ojeda's partner, coming with
+  provisions and reinforcements. One of the crew of Enciso's ship, Vasco
+  Nunez de Balboa, the future discoverer of the Pacific Ocean, induced
+  his commander to form a settlement on the other side of the Gulf of
+  Darien. The soldiers became discontented and deposed Enciso, who was a
+  man of learning and an accomplished cosmographer. His work _Suma de
+  Geografia_, which was printed in 1519, is the first Spanish book which
+  gives an account of America. Vasco Nunez, the new commander, entered
+  upon a career of conquest in the neighbourhood of Darien, which ended
+  in the discovery of the Pacific Ocean on the 25th of September 1513.
+  Vasco Nunez was beheaded in 1517 by Pedrarias de Avila, who was sent
+  out to supersede him. This was one of the greatest calamities that
+  could have happened to South America; for the discoverer of the South
+  sea was on the point of sailing with a little fleet into his unknown
+  ocean, and a humane and judicious man would probably have been the
+  conqueror of Peru, instead of the cruel and ignorant Pizarro. In the
+  year 1519 Panama was founded by Pedrarias; and the conquest of Peru by
+  Pizarro followed a few years afterwards. Hernan Cortes overran and
+  conquered Mexico from 1518 to 1521, and the discovery and conquest of
+  Guatemala by Alvarado, the invasion of Florida by De Soto, and of
+  Nueva Granada by Quesada, followed in rapid succession. The first
+  detailed account of the west coast of South America was written by a
+  keenly observant old soldier, Pedro de Cieza de Leon, who was
+  travelling in South America from 1533 to 1550, and published his story
+  at Seville in 1553.
+
+
+    Pacific Ocean.
+
+  The great desire of the Spanish government at that time was to find a
+  westward route to the Moluccas. For this purpose Juan Diaz de Solis
+  was despatched in October 1515, and in January 1516 he discovered the
+  mouth of the Rio de la Plata. He was, however, killed by the natives,
+  and his ships returned. In the following year the Portuguese
+  Ferdinando Magalhaes, familiarly known as Magellan, laid before
+  Charles V., at Valladolid, a scheme for reaching the Spice Islands by
+  sailing westward. He started on the 21st of September 1519, entered
+  the strait which now bears his name in October 1520, worked his way
+  through between Patagonia and Tierra del Fuego, and entered on the
+  vast Pacific which he crossed without sighting any of its innumerable
+  island groups. This was unquestionably the greatest of the voyages
+  which followed from the impulse of Prince Henry, and it was rendered
+  possible only by the magnificent courage of the commander in spite of
+  rebellion, mutiny and starvation. It was the 6th of March 1521 when he
+  reached the Ladrone Islands. Thence Magellan proceeded to the
+  Philippines, and there his career ended in an unimportant encounter
+  with hostile natives. Eventually a Biscayan named Sebastian del Cano,
+  sailing home by way of the Cape of Good Hope, reached San Lucar in
+  command of the "Victoria" on the 6th of September 1522, with eighteen
+  survivors; this one ship of the squadron which sailed on the quest
+  succeeded in accomplishing the first circumnavigation of the globe.
+  Del Cano was received with great distinction by the emperor, who
+  granted him a globe for his crest, and the motto _Primus circumdedisti
+  me_.
+
+
+    Portuguese in Africa and the East.
+
+  While the Spaniards were circumnavigating the world and completing
+  their knowledge of the coasts of Central and South America, the
+  Portuguese were actively engaged on similar work as regards Africa and
+  the East Indies.
+
+  With Abyssinia the mission of Covilhao led to further intercourse. In
+  April 1520 Vasco da Gama, as viceroy of the Indies, took a fleet into
+  the Red sea, and landed an embassy consisting of Dom Rodriguez de Lima
+  and Father Francisco Alvarez, a priest whose detailed narrative is the
+  earliest and not the least interesting account we possess of
+  Abyssinia. It was not until 1526 that the embassy was dismissed; and
+  not many years afterwards the negus entreated the help of the
+  Portuguese against Mahommedan invaders, and the viceroy sent an
+  expeditionary force, commanded by his brother Cristoforo da Gama, with
+  450 musketeers. Da Gama was taken prisoner and killed, but his
+  followers enabled the Christians of Abyssinia to regain their power,
+  and a Jesuit mission remained in the country. The Portuguese also
+  established a close connexion with the kingdom of Congo on the west
+  side of Africa, and obtained much information respecting the interior
+  of the continent. Duarte Lopez, a Portuguese settled in the country,
+  was sent on a mission to Rome by the king of Congo, and Pope Sixtus V.
+  caused him to recount to his chamberlain, Felipe Pigafetta, all he had
+  learned during the nine years he had been in Africa, from 1578 to
+  1587. This narrative, under the title of _Description of the Kingdom
+  of Congo_, was published at Rome by Pigafetta in 1591. A map was
+  attached on which several great equatorial lakes are shown, and the
+  empire of Monomwezi or Unyamwezi is laid down. The most valuable work
+  on Africa about this time is, however, that written by the Moor Leo
+  Africanus in the early part of the 16th century. Leo travelled
+  extensively in the north and west of Africa, and was eventually taken
+  by pirates and sold to a master who presented him to Pope Leo X. At
+  the pope's desire he translated his work on Africa into Italian.
+
+  In Further India and the Malay Archipelago the Portuguese acquired
+  predominating influence at sea, establishing factories on the Malabar
+  coast, in the Persian Gulf, at Malacca, and in the Spice Islands, and
+  extending their commercial enterprises from the Red sea to China.
+  Their missionaries were received at the court of Akbar, and Benedict
+  Goes, a native of the Azores, was despatched on a journey overland
+  from Agra to China. He started in 1603, and, after traversing the
+  least-known parts of Central Asia, he reached the confines of China.
+  He appears to have ascended from Kabul to the plateau of the Pamir,
+  and thence onwards by Yarkand, Khotan and Aksu. He died on the journey
+  in March 1607; and thus, as one of the brethren pronounced his
+  epitaph, "seeking Cathay he found heaven."
+
+
+    English, Dutch and French.
+
+  The activity and love of adventure, which became a passion for two or
+  three generations in Spain and Portugal, spread to other countries. It
+  was the spirit of the age; and England, Holland and France were fired
+  by it. English enterprise was first aroused by John and Sebastian
+  Cabot, father and son, who came from Venice and settled at Bristol in
+  the time of Henry VII. The Cabots received a patent in 1496,
+  empowering them to seek unknown lands; and John Cabot discovered
+  Newfoundland and part of the coast of America. Sebastian afterwards
+  made a voyage to Rio de la Plata in the service of Spain, but he
+  returned to England in 1548 and received a pension from Edward VI. At
+  his suggestion a voyage was undertaken for the discovery of a
+  north-east passage to Cathay, with Sir Hugh Willoughby as
+  captain-general of the fleet and Richard Chancellor as pilot-major.
+  They sailed in May 1553, but Willoughby and all his crew perished on
+  the Lapland coast. Chancellor, however, was more fortunate. He reached
+  the White Sea, performed the journey overland to Moscow, where he was
+  well received, and may be said to have been the founder of the trade
+  between Russia and England. He returned to Archangel and brought his
+  ship back in safety to England. On a second voyage, in 1556,
+  Chancellor was drowned; and three subsequent voyages, led by Stephen
+  Burrough, Arthur Pet and Charles Jackman, in small craft of 50 tons
+  and under, carried on an examination of the straits which lead into
+  the Kara sea.
+
+  The French followed closely on the track of John Cabot, and Norman and
+  Breton fishermen frequented the banks of Newfoundland at the beginning
+  of the 16th century. In 1524 Francis I. sent Giovanni da Verazzano of
+  Florence on an expedition of discovery to the coast of North America;
+  and the details of his voyage were embodied in a letter addressed by
+  him to the king of France from Dieppe, in July 1524. In 1534 Jacques
+  Cartier set out to continue the discoveries of Verazzano, and visited
+  Newfoundland and the Gulf of St Lawrence. In the following year he
+  made another voyage, discovered the island of Anticosti, and ascended
+  the St Lawrence to Hochelaga, now Montreal. He returned, after passing
+  two winters in Canada; and on another occasion he also failed to
+  establish a colony. Admiral de Coligny made several unsuccessful
+  endeavours to form a colony in Florida under Jean Ribault of Dieppe,
+  Rene de Laudonniere and others, but the settlers were furiously
+  assailed by the Spaniards and the attempt was abandoned.
+
+
+    The Elizabethan era.
+
+  The reign of Elizabeth is famous for the gallant enterprises that were
+  undertaken by sea and land to discover and bring to light the unknown
+  parts of the earth. The great promoter of geographical discovery in
+  the Elizabethan period was Richard Hakluyt (1553-1616), who was active
+  in the formation of the two companies for colonizing Virginia in 1606;
+  and devoted his life to encouraging and recording similar
+  undertakings. He published much, and left many valuable papers at his
+  death, most of which, together with many other narratives, were
+  published in 1622 in the great work of the Rev. Samuel Purchas,
+  entitled _Hakluytus Posthumus, or Purchas his Pilgrimes_.
+
+  It is from these works that our knowledge of the gallant deeds of the
+  English and other explorers of the Elizabethan age is mainly derived.
+  The great and splendidly illustrated collections of voyages and
+  travels of Theodorus de Bry and Hulsius served a similar useful
+  purpose on the continent of Europe. One important object of English
+  maritime adventurers of those days was to discover a route to Cathay
+  by the north-west, a second was to settle Virginia, and a third was to
+  raid the Spanish settlements in the West Indies. Nor was the trade to
+  Muscovy and Turkey neglected; while latterly a resolute and successful
+  attempt was made to establish direct commercial relations with India.
+
+  The conception of the north-western route to Cathay now leads the
+  story of exploration, for the first time as far as important and
+  sustained efforts are concerned, towards the Arctic seas. This part of
+  the story is fully told under the heading of POLAR REGIONS, and only
+  the names of Martin Frobisher (1576), John Davis (1585), Henry Hudson
+  (1607) and William Baffin (1616) need be mentioned here in order to
+  preserve the complete conspectus of the history of discovery. The
+  Dutch emulated the British in the Arctic seas during this period,
+  directing their efforts mainly towards the discovery of a north-east
+  passage round the northern end of Novaya Zemlya; and William Barents
+  or Barendsz (1594-1597) is the most famous name in this connexion, his
+  boat voyage along the coast of Novaya Zemlya after losing his ship and
+  wintering in a high latitude, being one of the most remarkable
+  achievements in polar annals.
+
+  Many English voyages were also made to Guinea and the West Indies, and
+  twice English vessels followed in the track of Magellan, and
+  circumnavigated the globe. In 1577 Francis Drake, who had previously
+  served with Hawkins in the West Indies, undertook his celebrated
+  voyage round the world. Reaching the Pacific through the Strait of
+  Magellan, Drake proceeded northward along the west coast of America,
+  resolved to attempt the discovery of a northern passage from the
+  Pacific to the Atlantic. The coast from the southern extremity of the
+  Californian peninsula to Cape Mendocino had been discovered by Juan
+  Rodriguez Cabrillo and Francisco de Ulloa in 1539. Drake's discoveries
+  extended from Cape Mendocino to 48 deg. N., in which latitude he gave
+  up his quest, sailed across the Pacific and reached the Philippine
+  Islands, returning home round the Cape of Good Hope in 1580.
+
+  Thomas Cavendish, emulous of Drake's example, fitted out three vessels
+  for an expedition to the South sea in 1586. He took the same route as
+  Drake along the west coast of America. From Cape San Lucas Cavendish
+  steered across the Pacific, seeing no land until he reached the
+  Ladrone Islands. He returned to England in 1588. The third English
+  voyage into the Pacific was not so fortunate. Sir Richard Hawkins
+  (1593) on reaching the bay of Atacames, in 1 deg.N. in 1594, was
+  attacked by a Spanish fleet, and, after a desperate naval engagement,
+  was forced to surrender. Hawkins declared his object to be discovery
+  and the survey of unknown lands, and his voyage, though terminating in
+  disaster, bore good fruit. _The Observations of Sir Richard Hawkins in
+  his Voyage into the South Sea_, published in 1622, are very valuable.
+  It was long before another British ship entered the Pacific Ocean. Sir
+  John Narborough took two ships through the Strait of Magellan in 1670
+  and touched on the coast of Chile, but it was not until 1685 that
+  Dampier sailed over the part of the Pacific where Hawkins met his
+  defeat.
+
+  The exploring enterprise of the Spanish nation did not wane after the
+  conquest of Peru and Mexico, and the acquisition of the vast empire of
+  the Indies. It was spurred into renewed activity by the audacity of
+  Sir John Hawkins in the West Indies, and by the appearance of Drake,
+  Cavendish and Richard Hawkins in the Pacific.
+
+  In the interior of South America the Spanish conquerors had explored
+  the region of the Andes from the isthmus of Panama to Chile. Pedro de
+  Valdivia in 1540 made an expedition into the country of the Araucanian
+  Indians of Chile, and was the first to explore the eastern base of
+  the Andes in what is now Argentine Patagonia. In 1541 Francisco de
+  Orellana discovered the whole course of the Amazon from its source in
+  the Andes to the Atlantic. A second voyage on the Amazon was made in
+  1561 by the mad pirate Lope de Aguirre; but it was not until 1639 that
+  a full account was written of the great river by Father Cristoval de
+  Acuna, who ascended it from its mouth and reached the city of Quito.
+
+
+    Spaniards in the Pacific.
+
+  The voyage of Drake across the Pacific was preceded by that of Alvaro
+  de Mendana, who was despatched from Peru in 1567 to discover the great
+  Antarctic continent which was believed to extend far northward into
+  the South sea, the search for which now became one of the leading
+  motives of exploration. After a voyage of eighty days across the
+  Pacific, Mendana discovered the Solomon Islands; and the expedition
+  returned in safety to Callao. The appearance of Drake on the Peruvian
+  coast led to an expedition being fitted out at Callao, to go in chase
+  of him, under the command of Pedro Sarmiento. He sailed from Callao in
+  October 1579, and made a careful survey of the Strait of Magellan,
+  with the object of fortifying that entrance to the South sea. The
+  colony which he afterwards took out from Spain was a complete failure,
+  and is only remembered now from the name of "Port Famine," which
+  Cavendish gave to the site at which he found the starving remnant of
+  Sarmiento's settlers. In June 1595 Mendana sailed from the coast of
+  Peru in command of a second expedition to colonize the Solomon
+  Islands. After discovering the Marquesas, he reached the island of
+  Santa Cruz of evil memory, where he and many of the settlers died. His
+  young widow took command of the survivors and brought them safely to
+  Manila. The viceroys of Peru still persevered in their attempts to
+  plant a colony in the hypothetical southern continent. Pedro Fernandez
+  de Quiros, who was pilot under Mendana and Luis Vaez de Torres, were
+  sent in command of two ships to continue the work of exploration. They
+  sailed from Callao in December 1605, and discovered several islands of
+  the New Hebrides group. They anchored in a bay of a large island which
+  Quiros named "Australia del Espiritu Santo." From this place Quiros
+  returned to America, but Torres continued the voyage, passed through
+  the strait between Australia and New Guinea which bears his name, and
+  explored and mapped the southern and eastern coasts of New Guinea.
+
+  The Portuguese, in the early part of the 17th century (1578-1640),
+  were under the dominion of Spain, and their enterprise was to some
+  extent damped; but their missionaries extended geographical knowledge
+  in Africa. Father Francisco Paez acquired great influence in
+  Abyssinia, and explored its highlands from 1600 to 1622. Fathers
+  Mendez and Lobo traversed the deserts between the coast of the Red sea
+  and the mountains, became acquainted with Lake Tsana, and discovered
+  the sources of the Blue Nile in 1624-1633.
+
+
+    Rivalry in the East.
+
+  But the attention of the Portuguese was mainly devoted to vain
+  attempts to maintain their monopoly of the trade of India against the
+  powerful rivalry of the English and Dutch. The English enterprises
+  were persevering, continuous and successful. James Lancaster made a
+  voyage to the Indian Ocean from 1591 to 1594; and in 1599 the
+  merchants and adventurers of London resolved to form a company, with
+  the object of establishing a trade with the East Indies. On the 31st
+  of December 1599 Queen Elizabeth granted the charter of incorporation
+  to the East India Company, and Sir James Lancaster, one of the
+  directors, was appointed general of their first fleet. He was
+  accompanied by John Davis, the great Arctic navigator, as pilot-major.
+  This voyage was eminently successful. The ships touched at Achin in
+  Sumatra and at Java, returning with full ladings of pepper in 1603.
+  The second voyage was commanded by Sir Henry Middleton; but it was in
+  the third voyage, under Keelinge and Hawkins, that the mainland of
+  India was first reached in 1607. Captain Hawkins landed at Surat and
+  travelled overland to Agra, passing some time at the court of the
+  Great Mogul. In the voyage of Sir Edward Michelborne in 1605, John
+  Davis lost his life in a fight with a Japanese junk. The eighth
+  voyage, led by Captain Saris, extended the operations of the company
+  to Japan; and in 1613 the Japanese government granted privileges to
+  the company; but the British retired in 1623, giving up their factory.
+  The chief result of this early intercourse between Great Britain and
+  Japan was the interesting series of letters written by William Adams
+  from 1611 to 1617. From the tenth voyage of the East India Company,
+  commanded by Captain Best, who left England in 1612, dates the
+  establishment of permanent British factories on the coast of India. It
+  was Captain Best who secured a regular _firman_ for trade from the
+  Great Mogul. From that time a fleet was despatched every year, and the
+  company's operations greatly increased geographical knowledge of India
+  and the Eastern Archipelago. British visits to Eastern countries, at
+  this time, were not confined to the voyages of the company. Journeys
+  were also made by land, and, among others, the entertaining author of
+  the _Crudities_, Thomas Coryate, of Odcombe in Somersetshire, wandered
+  on foot from France to India, and died (1617) in the company's factory
+  at Surat. In 1561 Anthony Jenkinson arrived in Persia with a letter
+  from Queen Elizabeth to the shah. He travelled through Russia to
+  Bokhara, and returned by the Caspian and Volga. In 1579 Christopher
+  Burroughs built a ship at Nizhniy Novgorod and traded across the
+  Caspian to Baku; and in 1598 Sir Anthony and Robert Shirley arrived in
+  Persia, and Robert was afterwards sent by the shah to Europe as his
+  ambassador. He was followed by a Spanish mission under Garcia de
+  Silva, who wrote an interesting account of his travels; and to Sir
+  Dormer Cotton's mission, in 1628, we are indebted for Sir Thomas
+  Herbert's charming narrative. In like manner Sir Thomas Roe's mission
+  to India resulted not only in a large collection of valuable reports
+  and letters of his own, but also in the detailed account of his
+  chaplain Terry. But the most learned and intelligent traveller in the
+  East, during the 17th century, was the German, Engelbrecht Kaempfer,
+  who accompanied an embassy to Persia, in 1684, and was afterwards a
+  surgeon in the service of the Dutch East India Company. He was in the
+  Persian Gulf, India and Java, and resided for more than two years in
+  Japan, of which he wrote a history.
+
+
+    Dutch exploration, 16th-17th centuries.
+
+  The Dutch nation, as soon as it was emancipated from Spanish tyranny,
+  displayed an amount of enterprise, which, for a long time, was fully
+  equal to that of the British. The Arctic voyages of Barents were
+  quickly followed by the establishment of a Dutch East India Company;
+  and the Dutch, ousting the Portuguese, not only established factories
+  on the mainland of India and in Japan, but acquired a preponderating
+  influence throughout the Malay Archipelago. In 1583 Jan Hugen van
+  Linschoten made a voyage to India with a Portuguese fleet, and his
+  full and graphic descriptions of India, Africa, China and the Malay
+  Archipelago must have been of no small use to his countrymen in their
+  distant voyages. The first of the Dutch Indian voyages was performed
+  by ships which sailed in April 1595, and rounded the Cape of Good
+  Hope. A second large Dutch fleet sailed in 1598; and, so eager was the
+  republic to extend her commerce over the world that another fleet,
+  consisting of five ships of Rotterdam, was sent in the same year by
+  way of Magellan's Strait, under Jacob Mahu as admiral, with William
+  Adams as pilot. Mahu died on the passage out, and was succeeded by
+  Simon de Cordes, who was killed on the coast of Chile. In September
+  1599 the fleet had entered the Pacific. The ships were then steered
+  direct for Japan, and anchored off Bungo in April 1600. In the same
+  year, 1598, a third expedition was despatched under Oliver van Noort,
+  a native of Utrecht, but the voyage contributed nothing to geography.
+  The Dutch Company in 1614 again resolved to send a fleet to the
+  Moluccas by the westward route, and Joris Spilbergen was appointed to
+  the command as admiral, with a commission from the States-General. He
+  was furnished with four ships of Amsterdam, two of Rotterdam and one
+  from Zeeland. On the 6th of May 1615 Spilbergen entered the Pacific
+  Ocean, and touched at several places on the coast of Chile and Peru,
+  defeating the Spanish fleet in a naval engagement off Chilca. After
+  plundering Payta and making requisitions at Acapulco, the Dutch fleet
+  crossed the Pacific and reached the Moluccas in March 1616.
+
+  The Dutch now resolved to discover a passage into the Pacific to the
+  south of Tierra del Fuego, the insular nature of which had been
+  ascertained by Sir Francis Drake. The vessels fitted out for this
+  purpose were the "Eendracht," of 360 tons, commanded by Jacob Lemaire,
+  and the "Hoorn," of 110 tons, under Willem Schouten. They sailed from
+  the Texel on the 14th of June 1615, and by the 20th of January 1616
+  they were south of the entrance of Magellan's Strait. Passing through
+  the strait of Lemaire they came to the southern extremity of Tierra
+  del Fuego, which was named Cape Horn, in honour of the town of Hoorn
+  in West Friesland, of which Schouten was a native. They passed the
+  cape on the 31st of January, encountering the usual westerly winds.
+  The great merit of this discovery of a second passage into the South
+  sea lies in the fact that it was not accidental or unforeseen, but was
+  due to the sagacity of those who designed the voyage. On the 1st of
+  March the Dutch fleet sighted the island of Juan Fernandez; and,
+  having crossed the Pacific, the explorers sailed along the north coast
+  of New Guinea and arrived at the Moluccas on the 17th of September
+  1616.
+
+  There were several early indications of the existence of the great
+  Australian continent, and the Dutch endeavoured to obtain further
+  knowledge concerning the country and its extent; but only its northern
+  and western coasts had been visited before the time of Governor van
+  Diemen. Dirk Hartog had been on the west coast in latitude 26 deg. 30'
+  S. in 1616. Pelsert struck on a reef called "Houtman's Abrolhos" on
+  the 4th of June 1629. In 1697 the Dutch captain Vlamingh landed on the
+  west coast of Australia, then called New Holland, in 31 deg. 43' S.,
+  and named the Swan river from the black swans he discovered there. In
+  1642 the governor and council of Batavia fitted out two ships to
+  prosecute the discovery of the south land, then believed to be part of
+  a vast Antarctic continent, and entrusted the command to Captain Abel
+  Jansen Tasman. This voyage proved to be the most important to
+  geography that had been undertaken since the first circumnavigation of
+  the globe. Tasman sailed from Batavia in 1642, and on the 24th of
+  November sighted high land in 42 deg. 30' S., which was named van
+  Diemen's Land, and after landing there proceeded to the discovery of
+  the western coast of New Zealand; at first called Staten Land, and
+  supposed to be connected with the Antarctic continent from which this
+  voyage proved New Holland to be separated. He then reached Tongatabu,
+  one of the Friendly Islands of Cook; and returned by the north coast
+  of New Guinea to Batavia. In 1644 Tasman made a second voyage to
+  effect a fuller discovery of New Guinea.
+
+
+    French in North America.
+
+  The French directed their enterprise more in the direction of North
+  America than of the Indies. One of their most distinguished explorers
+  was Samuel Champlain, a captain in the navy, who, after a remarkable
+  journey through Mexico and the West Indies from 1599 to 1602,
+  established his historic connexion with Canada, to the geographical
+  knowledge of which he made a very large addition.
+
+
+    Missionaries in the East.
+
+  The principles and methods of surveying and position finding had by
+  this time become well advanced, and the most remarkable example of the
+  early application of these improvements is to be found in the survey
+  of China by Jesuit missionaries. They first prepared a map of the
+  country round Peking, which was submitted to the emperor Kang-hi, and,
+  being satisfied with the accuracy of the European method of surveying,
+  he resolved to have a survey made of the whole empire on the same
+  principles. This great work was begun in July 1708, and the completed
+  maps were presented to the emperor in 1718. The records preserved in
+  each city were examined, topographical information was diligently
+  collected, and the Jesuit fathers checked their triangulation by
+  meridian altitudes of the sun and pole star and by a system of
+  remeasurements. The result was a more accurate map of China than
+  existed, at that time, of any country in Europe. Kang-hi next ordered
+  a similar map to be made of Tibet, the survey being executed by two
+  lamas who were carefully trained as surveyors by the Jesuits at
+  Peking. From these surveys were constructed the well-known maps which
+  were forwarded to Duhalde, and which D'Anville utilized for his atlas.
+
+
+    The 18th century.
+
+    Asia.
+
+  Several European missionaries had previously found their way from
+  India to Tibet. Antonio Andrada, in 1624, was the first European to
+  enter Tibet since the visit of Friar Odoric in 1325. The next journey
+  was that of Fathers Grueber and Dorville about 1660, who succeeded in
+  passing from China, through Tibet, into India. In 1715 Fathers
+  Desideri and Freyre made their way from Agra, across the Himalayas, to
+  Lhasa, and the Capuchin Friar Orazio della Penna resided in that city
+  from 1735 until 1747. But the most remarkable journey in this
+  direction was performed by a Dutch traveller named Samuel van de
+  Putte. He left Holland in 1718, went by land through Persia to India,
+  and eventually made his way to Lhasa, where he resided for a long
+  time. He went thence to China, returned to Lhasa, and was in India in
+  time to be an eye-witness of the sack of Delhi by Nadir Shah in 1737.
+  In 1743 he left India and died at Batavia on the 27th of September
+  1745. The premature death of this illustrious traveller is the more to
+  be lamented because his vast knowledge died with him. Two English
+  missions sent by Warren Hastings to Tibet, one led by George Bogle in
+  1774, and the other by Captain Turner in 1783, complete Tibetan
+  exploration in the 18th century.
+
+  From Persia much new information was supplied by Jean Chardin, Jean
+  Tavernier, Charles Hamilton, Jean de Thevenot and Father Jude
+  Krusinski, and by English traders on the Caspian. In 1738 John Elton
+  traded between Astrakhan and the Persian port of Enzeli on the
+  Caspian, and undertook to build a fleet for Nadir Shah. Another
+  English merchant, named Jonas Hanway, arrived at Astrabad from Russia,
+  and travelled to the camp of Nadir at Kazvin. One lasting and valuable
+  result of Hanway's wanderings was a charming book of travels. In 1700
+  Guillaume Delisle published his map of the continents of the Old
+  World; and his successor D'Anville produced his map of India in 1752.
+  D'Anville's map contained all that was then known, but ten years
+  afterwards Major Rennell began his surveying labours, which extended
+  over the period from 1763 to 1782. His survey covered an area 900 m.
+  long by 300 wide, from the eastern confines of Bengal to Agra, and
+  from the Himalayas to Calpi. Rennell was indefatigable in collecting
+  geographical information; his Bengal atlas appeared in 1781, his
+  famous map of India in 1788 and the memoir in 1792. Surveys were also
+  made along the Indian coasts.
+
+  Arabia received very careful attention, in the 18th century, from the
+  Danish scientific mission, which included Carsten Niebuhr among its
+  members. Niebuhr landed at Loheia, on the coast of Yemen, in December
+  1762, and went by land to Sana. All the other members of the mission
+  died, but he proceeded from Mokha to Bombay. He then made a journey
+  through Persia and Syria to Constantinople, returning to Copenhagen in
+  1767. His valuable work, the _Description of Arabia_, was published in
+  1772, and was followed in 1774-1778 by two volumes of travels in Asia.
+  The great traveller survived until 1815, when he died at the age of
+  eighty-two.
+
+
+    Africa.
+
+  James Bruce of Kinnaird, the contemporary of Niebuhr, was equally
+  devoted to Eastern travel; and his principal geographical work was the
+  tracing of the Blue Nile from its source to its junction with the
+  White Nile. Before the death of Bruce an African Association was
+  formed, in 1788, for collecting information respecting the interior of
+  that continent, with Major Rennell and Sir Joseph Banks as leading
+  members. The association first employed John Ledyard (who had
+  previously made an extraordinary journey into Siberia) to cross Africa
+  from east to west on the parallel of the Niger, and William Lucas to
+  cross the Sahara to Fezzan. Lucas went from Tripoli to Mesurata,
+  obtained some information respecting Fezzan and returned in 1789. One
+  of the chief problems the association wished to solve was that of the
+  existence and course of the river Niger, which was believed by some
+  authorities to be identical with the Congo. Mungo Park, then an
+  assistant surgeon of an Indiaman, volunteered his services, which were
+  accepted by the association, and in 1795 he succeeded in reaching the
+  town of Segu on the Niger, but was prevented from continuing his
+  journey to Timbuktu. Five years later he accepted an offer from the
+  government to command an expedition into the interior of Africa, the
+  plan being to cross from the Gambia to the Niger and descend the
+  latter river to the sea. After losing most of his companions he
+  himself and the rest perished in a rapid on the Niger at Busa, having
+  been attacked from the shore by order of a chief who thought he had
+  not received suitable presents. His work, however, had established the
+  fact that the Niger was not identical with the Congo.
+
+  While the British were at work in the direction of the Niger, the
+  Portuguese were not unmindful of their old exploring fame. In 1798 Dr
+  F.J.M. de Lacerda, an accomplished astronomer, was appointed to
+  command a scientific expedition of discovery to the north of the
+  Zambesi. He started in July, crossed the Muchenja Mountains, and
+  reached the capital of the Cazembe, where he died of fever. Lacerda
+  left a valuable record of his adventurous journey; but with Mungo Park
+  and Lacerda the history of African exploration in the 18th century
+  closes.
+
+
+    South America.
+
+  In South America scientific exploration was active during this period.
+  The great geographical event of the century, as regards that
+  continent, was the measurement of an arc of the meridian. The
+  undertaking was proposed by the French Academy as part of an
+  investigation with the object of ascertaining the length of the degree
+  near the equator and near the pole respectively so as to determine the
+  figure of the earth. A commission left Paris in 1735, consisting of
+  Charles Marie de la Condamine, Pierre Bouguer, Louis Godin and Joseph
+  de Jussieu the naturalist. Spain appointed two accomplished naval
+  officers, the brothers Ulloa, as coadjutors. The operations were
+  carried on during eight years on a plain to the south of Quito; and,
+  in addition to his memoir on this memorable measurement, La Condamine
+  collected much valuable geographical information during a voyage down
+  the Amazon. The arc measured was 3 deg. 7' 3" in length; and the work
+  consisted of two measured bases connected by a series of triangles,
+  one north and the other south of the equator, on the meridian of
+  Quito. Contemporaneously, in 1738, Pierre Louis Moreau de Maupertuis,
+  Alexis Claude Clairaut, Charles Etienne Louis Camus, Pierre Charles
+  Lemonnier and the Swedish physicist Celsius measured an arc of the
+  meridian in Lapland.
+
+
+    The Pacific Ocean.
+
+  The British and French governments despatched several expeditions of
+  discovery into the Pacific and round the world during the 18th
+  century. They were preceded by the wonderful and romantic voyages of
+  the buccaneers. The narratives of such men as Woodes Rogers, Edward
+  Davis, George Shelvocke, Clipperton and William Dampier, can never
+  fail to interest, while they are not without geographical value. The
+  works of Dampier are especially valuable, and the narratives of
+  William Funnell and Lionel Wafer furnished the best accounts then
+  extant of the Isthmus of Darien. Dampier's literary ability eventually
+  secured for him a commission in the king's service; and he was sent on
+  a voyage of discovery, during which he explored part of the coasts of
+  Australia and New Guinea, and discovered the strait which bears his
+  name between New Guinea and New Britain, returning in 1701. In 1721
+  Jacob Roggewein was despatched on a voyage of some importance across
+  the Pacific by the Dutch West India Company, during which he
+  discovered Easter Island on the 6th of April 1722.
+
+  The voyage of Lord Anson to the Pacific in 1740-1744 was of a
+  predatory character, and he lost more than half his men from scurvy;
+  while it is not pleasant to reflect that at the very time when the
+  French and Spaniards were measuring an arc of the meridian at Quito,
+  the British under Anson were pillaging along the coast of the Pacific
+  and burning the town of Payta. But a romantic interest attaches to the
+  wreck of the "Wager," one of Anson's fleet, on a desert island near
+  Chiloe, for it bore fruit in the charming narrative of Captain John
+  Byron, which will endure for all time. In 1764 Byron himself was sent
+  on a voyage of discovery round the world, which led immediately after
+  his return to the despatch of another to complete his work, under the
+  command of Captain Samuel Wallis.
+
+  The expedition, consisting of the "Dolphin" commanded by Wallis, and
+  the "Swallow" under Captain Philip Carteret, sailed in September 1766,
+  but the ships were separated on entering the Pacific from the Strait
+  of Magellan. Wallis discovered Tahiti on the 19th of June 1767, and he
+  gave a detailed account of that island. He returned to England in May
+  1768. Carteret discovered the Charlotte and Gloucester Islands, and
+  Pitcairn Island on the 2nd of July 1767; revisited the Santa Cruz
+  group, which was discovered by Mendana and Quiros; and discovered the
+  strait separating New Britain from New Ireland. He reached Spithead
+  again in February 1769. Wallis and Carteret were followed very closely
+  by the French expedition of Bougainville, which sailed from Nantes in
+  November 1766. Bougainville had first to perform the unpleasant task
+  of delivering up the Falkland Islands, where he had encouraged the
+  formation of a French settlement, to the Spaniards. He then entered
+  the Pacific, and reached Tahiti in April 1768. Passing through the New
+  Hebrides group he touched at Batavia, and arrived at St Malo after an
+  absence of two years and four months.
+
+
+    Captain Cook.
+
+  The three voyages of Captain James Cook form an era in the history of
+  geographical discovery. In 1767 he sailed for Tahiti, with the object
+  of observing the transit of Venus, accompanied by two naturalists, Sir
+  Joseph Banks and Dr Solander, a pupil of Linnaeus, as well as by two
+  astronomers. The transit was observed on the 3rd of June 1769. After
+  exploring Tahiti and the Society group, Cook spent six months
+  surveying New Zealand, which he discovered to be an island, and the
+  coast of New South Wales from latitude 38 deg. S. to the northern
+  extremity. The belief in a vast Antarctic continent stretching far
+  into the temperate zone had never been abandoned, and was vehemently
+  asserted by Charles Dalrymple, a disappointed candidate nominated by
+  the Royal Society for the command of the Transit expedition of 1769.
+  In 1772 the French explorer Yves Kerguelen de Tremarec had discovered
+  the land that bears his name in the South Indian Ocean without
+  recognizing it to be an island, and naturally believed it to be part
+  of the southern continent.
+
+  Cook's second voyage was mainly intended to settle the question of the
+  existence of such a continent once for all, and to define the limits
+  of any land that might exist in navigable seas towards the Antarctic
+  circle. James Cook at his first attempt reached a south latitude of 57
+  deg. 15'. On a second cruise from the Society Islands, in 1773, he,
+  first of all men, crossed the Antarctic circle, and was stopped by ice
+  in 71 deg. 10' S. During the second voyage Cook visited Easter Island,
+  discovered several islands of the New Hebrides and New Caledonia; and
+  on his way home by Cape Horn, in March 1774, he discovered the
+  Sandwich Island group and described South Georgia. He proved
+  conclusively that any southern continent that might exist lay under
+  the polar ice. The third voyage was intended to attempt the passage
+  from the Pacific to the Atlantic by the north-east. The "Resolution"
+  and "Discovery" sailed in 1776, and Cook again took the route by the
+  Cape of Good Hope. On reaching the North American coast, he proceeded
+  northward, fixed the position of the western extremity of America and
+  surveyed Bering Strait. He was stopped by the ice in 70 deg. 41' N.,
+  and named the farthest visible point on the American shore Icy Cape.
+  He then visited the Asiatic shore and discovered Cape North. Returning
+  to Hawaii, Cook was murdered by the natives. On the 14th of February
+  1779, his second, Captain Edward Clerke, took command, and proceeding
+  to Petropavlovsk in the following summer, he again examined the edge
+  of the ice, but only got as far as 70 deg. 33' N. The ships returned
+  to England in October 1780.
+
+  In 1785 the French government carefully fitted out an expedition of
+  discovery at Brest, which was placed under the command of Francois La
+  Perouse, an accomplished and experienced officer. After touching at
+  Concepcion in Chile and at Easter Island, La Perouse proceeded to
+  Hawaii and thence to the coast of California, of which he has given a
+  very interesting account. He then crossed the Pacific to Macao, and in
+  July 1787 he proceeded to explore the Gulf of Tartary and the shores
+  of Sakhalin, remaining some time at Castries Bay, so named after the
+  French minister of marine. Thence he went to the Kurile Islands and
+  Kamchatka, and sailed from the far north down the meridian to the
+  Navigator and Friendly Islands. He was in Botany Bay in January 1788;
+  and sailing thence, the explorer, his ship and crew were never seen
+  again. Their fate was long uncertain. In September 1791 Captain
+  Antoine d'Entrecasteaux sailed from Brest with two vessels to seek for
+  tidings. He visited the New Hebrides, Santa Cruz, New Caledonia and
+  Solomon Islands, and made careful though rough surveys of the
+  Louisiade Archipelago, islands north of New Britain and part of New
+  Guinea. D'Entrecasteaux died on board his ship on the 20th of July
+  1793, without ascertaining the fate of La Perouse. Captain Peter
+  Dillon at length ascertained, in 1828, that the ships of La Perouse
+  had been wrecked on the island of Vanikoro during a hurricane.
+
+  The work of Captain Cook bore fruit in many ways. His master, Captain
+  William Bligh, was sent in the "Bounty" to convey breadfruit plants
+  from Tahiti to the West Indies. He reached Tahiti in October 1788, and
+  in April 1789 a mutiny broke out, and he, with several officers and
+  men, was thrust into an open boat in mid-ocean. During the remarkable
+  voyage he then made to Timor, Bligh passed amongst the northern
+  islands of the New Hebrides, which he named the Banks Group, and made
+  several running surveys. He reached England in March 1790. The
+  "Pandora," under Captain Edwards, was sent out in search of the
+  "Bounty," and discovered the islands of Cherry and Mitre, east of the
+  Santa Cruz group, but she was eventually lost on a reef in Torres
+  Strait. In 1796-1797 Captain Wilson, in the missionary ship "Duff,"
+  discovered the Gambier and other islands, and rediscovered the islands
+  known to and seen by Quiros, but since called the Duff Group. Another
+  result of Captain Cook's work was the colonization of Australia. On
+  the 18th of January 1788 Admiral Phillip and Captain Hunter arrived in
+  Botany Bay in the "Supply" and "Sirius," followed by six transports,
+  and established a colony at Port Jackson. Surveys were then undertaken
+  in several directions. In 1795 and 1796 Matthew Flinders and George
+  Bass were engaged on exploring work in a small boat called the "Tom
+  Thumb." In 1797 Bass, who had been a surgeon, made an expedition
+  southwards, continued the work of Cook from Ram Head, and explored the
+  strait which bears his name, and in 1798 he and Flinders were
+  surveying on the east coast of Van Diemen's land.
+
+  Yet another outcome of Captain Cook's work was the voyage of George
+  Vancouver, who had served as a midshipman in Cook's second and third
+  voyages. The Spaniards under Quadra had begun a survey of
+  north-western America and occupied Nootka Sound, which their
+  government eventually agreed to surrender. Captain Vancouver was sent
+  out to receive the cession, and to survey the coast from Cape
+  Mendocino northwards. He commanded the old "Discovery," and was at
+  work during the seasons of 1792, 1793 and 1794, wintering at Hawaii.
+  Returning home in 1795, he completed his narrative and a valuable
+  series of charts.
+
+
+    Arctic regions.
+
+  The 18th century saw the Arctic coast of North America reached at two
+  points, as well as the first scientific attempt to reach the North
+  Pole. The Hudson Bay Company had been incorporated in 1670, and its
+  servants soon extended their operations over a wide area to the north
+  and west of Canada. In 1741 Captain Christopher Middleton was ordered
+  to solve the question of a passage from Hudson Bay to the westward.
+  Leaving Fort Churchill in July 1742, he discovered the Wager river and
+  Repulse Bay. He was followed by Captain W. Moor in 1746, and Captain
+  Coats in 1751, who examined the Wager Inlet up to the end. In November
+  1769 Samuel Hearne was sent by the Hudson Bay Company to discover the
+  sea on the north side of America, but was obliged to return. In
+  February 1770 he set out again from Fort Prince of Wales; but, after
+  great hardships, he was again forced to return to the fort. He started
+  once more in December 1771, and at length reached the Coppermine
+  river, which he surveyed to its mouth, but his observations are
+  unreliable. With the same object Alexander Mackenzie, with a party of
+  Canadians, set out from Fort Chippewyan on the 3rd of June 1789, and
+  descending the great river which now bears the explorer's name reached
+  the Arctic sea.
+
+  In February 1773 the Royal Society submitted a proposal to the king
+  for an expedition towards the North Pole. The expedition was fitted
+  out under Captains Constantine Phipps and Skeffington Lutwidge, and
+  the highest latitude reached was 80 deg. 48' N., but no opening was
+  discovered in the heavy Polar pack. The most important Arctic work in
+  the 18th century was performed by the Russians, for they succeeded in
+  delineating the whole of the northern coast of Siberia. Some of this
+  work was possibly done at a still earlier date. The Cossack Simon
+  Dezhneff is thought to have made a voyage, in the summer of 1648, from
+  the river Kolyma, through Bering Strait (which was rediscovered by
+  Vitus Bering in 1728) to Anadyr. Between 1738 and 1750 Manin and
+  Sterlegoff made their way in small sloops from the mouth of the
+  Yenesei as far north as 75 deg. 15' N. The land from Taimyr to Cape
+  Chelyuskin, the most northern extremity of Siberia, was mapped in many
+  years of patient exploration by Chelyuskin, who reached the extreme
+  point (77 deg. 34' N.) in May 1742. To the east of Cape Chelyuskin the
+  Russians encountered greater difficulties. They built small vessels at
+  Yakutsk on the Lena, 900 m. from its mouth, whence the first
+  expedition was despatched under Lieut. Prontschichev in 1735. He
+  sailed from the mouth of the Lena to the mouth of the Olonek, where he
+  wintered, and on the 1st of September 1736 he got as far as 77 deg.
+  29' N., within 5 m. of Cape Chelyuskin. Both he and his young wife
+  died of scurvy, and the vessel returned. A second expedition, under
+  Lieut. Laptyev, started from the Lena in 1739, but encountered masses
+  of drift ice in Chatanga bay, and with this ended the voyages to the
+  westward of the Lena. Several attempts were also made to navigate the
+  sea from the Lena to the Kolyma. In 1736 Lieut. Laptyev sailed, but
+  was stopped by the drift ice in August, and in 1739, during another
+  trial, he reached the mouth of the Indigirka, where he wintered. In
+  the season of 1740 he continued his voyage to beyond the Kolyma,
+  wintering at Nizhni Kolymsk. In September 1740 Vitus Bering sailed
+  from Okhotsk on a second Arctic voyage with George William Steller on
+  board as naturalist. In June 1741 he named the magnificent peak on the
+  coast of North America Mount St Elias and explored the Aleutian
+  Islands. In November the ship was wrecked on Bering Island; and the
+  gallant Dane, worn out with scurvy, died there on the 8th of December
+  1741. In March 1770 a merchant named Liakhov saw a large herd of
+  reindeer coming from the north to the Siberian coast, which induced
+  him to start in a sledge in the direction whence they came. Thus he
+  reached the New Siberian or Liakhov Islands, and for years afterwards
+  the seekers for fossil ivory resorted to them. The Russian Captain
+  Vassili Chitschakov in 1765 and 1766 made two persevering attempts to
+  penetrate the ice north of Spitsbergen, and reached 80 deg. 30' N.,
+  while Russian parties twice wintered at Bell Sound.
+
+
+    Geographical societies.
+
+  In reviewing the progress of geographical discovery thus far, it has
+  been possible to keep fairly closely to a chronological order. But in
+  the 19th century and after exploring work was so generally and
+  steadily maintained in all directions, and was in so many cases
+  narrowed down from long journeys to detailed surveys within relatively
+  small areas, that it becomes desirable to cover the whole period at
+  one view for certain great divisions of the world. (See AFRICA; ASIA;
+  AUSTRALIA; POLAR REGIONS; &c.) Here, however, may be noticed the
+  development of geographical societies devoted to the encouragement of
+  exploration and research. The first of the existing geographical
+  societies was that of Paris, founded in 1825 under the title of La
+  Societe de Geographie. The Berlin Geographical Society (Gesellschaft
+  fur Erdkunde) is second in order of seniority, having been founded in
+  1827. The Royal Geographical Society, which was founded in London in
+  1830, comes third on the list; but it may be viewed as a direct result
+  of the earlier African Association founded in 1788. Sir John Barrow,
+  Sir John Cam Hobhouse (Lord Broughton), Sir Roderick Murchison, Mr
+  Robert Brown and Mr Bartle Frere formed the foundation committee of
+  the Royal Geographical Society, and the first president was Lord
+  Goderich. The action of the society in supplying practical instruction
+  to intending travellers, in astronomy, surveying and the various
+  branches of science useful to collectors, has had much to do with
+  advancement of discovery. Since the war of 1870 many geographical
+  societies have been established on the continent of Europe. At the
+  close of the 19th century there were upwards of 100 such societies in
+  the world, with more than 50,000 members, and over 150 journals were
+  devoted entirely to geographical subjects.[11] The great development
+  of photography has been a notable aid to explorers, not only by
+  placing at their disposal a faithful and ready means of recording the
+  features of a country and the types of inhabitants, but by supplying a
+  method of quick and accurate topographical surveying.
+
+
+  THE PRINCIPLES OF GEOGRAPHY
+
+  As regards the scope of geography, the order of the various
+  departments and their inter-relation, there is little difference of
+  opinion, and the principles of geography[12] are now generally
+  accepted by modern geographers. The order in which the various
+  subjects are treated in the following sketch is the natural succession
+  from fundamental to dependent facts, which corresponds also to the
+  evolution of the diversities of the earth's crust and of its
+  inhabitants.
+
+
+    Mathematical geography.
+
+  The fundamental geographical conceptions are mathematical, the
+  relations of space and form. The figure and dimensions of the earth
+  are the first of these. They are ascertained by a combination of
+  actual measurement of the highest precision on the surface and angular
+  observations of the positions of the heavenly bodies. The science of
+  geodesy is part of mathematical geography, of which the arts of
+  surveying and cartography are applications. The motions of the earth
+  as a planet must be taken into account, as they render possible the
+  determination of position and direction by observations of the
+  heavenly bodies. The diurnal rotation of the earth furnishes two fixed
+  points or poles, the axis joining which is fixed or nearly so in its
+  direction in space. The rotation of the earth thus fixes the
+  directions of north and south and defines those of east and west. The
+  angle which the earth's axis makes with the plane in which the planet
+  revolves round the sun determines the varying seasonal distribution of
+  solar radiation over the surface and the mathematical zones of
+  climate. Another important consequence of rotation is the deviation
+  produced in moving bodies relatively to the surface. In the form known
+  as Ferrell's Law this runs: "If a body moves in any direction on the
+  earth's surface, there is a deflecting force which arises from the
+  earth's rotation which tends to deflect it to the right in the
+  northern hemisphere but to the left in the southern hemisphere." The
+  deviation is of importance in the movement of air, of ocean currents,
+  and to some extent of rivers.[13]
+
+
+    Physical geography.
+
+  In popular usage the words "physical geography" have come to mean
+  geography viewed from a particular standpoint rather than any special
+  department of the subject. The popular meaning is better conveyed by
+  the word physiography, a term which appears to have been introduced by
+  Linnaeus, and was reinvented as a substitute for the cosmography of
+  the middle ages by Professor Huxley. Although the term has since been
+  limited by some writers to one particular part of the subject, it
+  seems best to maintain the original and literal meaning. In the
+  stricter sense, physical geography is that part of geography which
+  involves the processes of contemporary change in the crust and the
+  circulation of the fluid envelopes. It thus draws upon physics for the
+  explanation of the phenomena with the space-relations of which it is
+  specially concerned. Physical geography naturally falls into three
+  divisions, dealing respectively with the surface of the
+  lithosphere--geomorphology; the hydrosphere--oceanography; and the
+  atmosphere--climatology. All these rest upon the facts of mathematical
+  geography, and the three are so closely inter-related that they cannot
+  be rigidly separated in any discussion.
+
+
+    Geomorphology.
+
+  Geomorphology is the part of geography which deals with terrestrial
+  relief, including the submarine as well as the subaerial portions of
+  the crust. The history of the origin of the various forms belongs to
+  geology, and can be completely studied only by geological methods. But
+  the relief of the crust is not a finished piece of sculpture; the
+  forms are for the most part transitional, owing their characteristic
+  outlines to the process by which they are produced; therefore the
+  geographer must, for strictly geographical purposes, take some account
+  of the processes which are now in action modifying the forms of the
+  crust. Opinion still differs as to the extent to which the
+  geographer's work should overlap that of the geologist.
+
+  The primary distinction of the forms of the crust is that between
+  elevations and depressions. Granting that the geoid or mean surface of
+  the ocean is a uniform spheroid, the distribution of land and water
+  approximately indicates a division of the surface of the globe into
+  two areas, one of elevation and one of depression. The increasing
+  number of measurements of the height of land in all continents and
+  islands, and the very detailed levellings in those countries which
+  have been thoroughly surveyed, enable the average elevation of the
+  land above sea-level to be fairly estimated, although many vast gaps
+  in accurate knowledge remain, and the estimate is not an exact one.
+  The only part of the sea-bed the configuration of which is at all well
+  known is the zone bordering the coasts where the depth is less than
+  about 100 fathoms or 200 metres, i.e. those parts which sailors speak
+  of as "in soundings." Actual or projected routes for telegraph cables
+  across the deep sea have also been sounded with extreme accuracy in
+  many cases; but beyond these lines of sounding the vast spaces of the
+  ocean remain unplumbed save for the rare researches of scientific
+  expeditions, such as those of the "Challenger," the "Valdivia," the
+  "Albatross" and the "Scotia." Thus the best approximation to the
+  average depth of the ocean is little more than an expert guess; yet a
+  fair approximation is probable for the features of sub-oceanic relief
+  are so much more uniform than those of the land that a smaller number
+  of fixed points is required to determine them.
+
+
+    Crustal relief.
+
+  The chief element of uncertainty as to the largest features of the
+  relief of the earth's crust is due to the unexplored area in the
+  Arctic region and the larger regions of the Antarctic, of which we
+  know nothing. We know that the earth's surface if unveiled of water
+  would exhibit a great region of elevation arranged with a certain
+  rough radiate symmetry round the north pole, and extending southwards
+  in three unequal arms which taper to points in the south. A depression
+  surrounds the little-known south polar region in a continuous ring and
+  extends northwards in three vast hollows lying between the arms of the
+  elevated area. So far only is it possible to speak with certainty, but
+  it is permissible to take a few steps into the twilight of dawning
+  knowledge and indicate the chief subdivisions which are likely to be
+  established in the great crust-hollow and the great crust-heap. The
+  boundary between these should obviously be the mean surface of the
+  sphere.
+
+  Sir John Murray deduced the mean height of the land of the globe as
+  about 2250 ft. above sea-level, and the mean depth of the oceans as
+  2080 fathoms or 12,480 ft. below sea-level.[14] Calculating the area
+  of the land at 55,000,000 sq. m. (or 28.6% of the surface), and that
+  of the oceans as 137,200,000 sq. m. (or 71.4% of the surface), he
+  found that the volume of the land above sea-level was 23,450,000 cub.
+  m., the volume of water below sea-level 323,800,000, and the total
+  volume of the water equal to about 1/666th of the volume of the whole
+  globe. From these data, as revised by A. Supan,[15] H.R. Mill
+  calculated the position of mean sphere-level at about 10,000 ft. or
+  1700 fathoms below sea-level. He showed that an imaginary spheroidal
+  shell, concentric with the earth and cutting the slope between the
+  elevated and depressed areas at the contour-line of 1700 fathoms,
+  would not only leave above it a volume of the crust equal to the
+  volume of the hollow left below it, but would also divide the surface
+  of the earth so that the area of the elevated region was equal to that
+  of the depressed region.[16]
+
+
+    Areas of the crust according to Murray.
+
+  A similar observation was made almost simultaneously by Romieux,[17]
+  who further speculated on the equilibrium between the weight of the
+  elevated land mass and that of the total waters of the ocean, and
+  deduced some interesting relations between them. Murray, as the result
+  of his study, divided the earth's surface into three zones--the
+  _continental area_ containing all dry land, the _transitional area_
+  including the submarine slopes down to 1000 fathoms, and the _abysmal
+  area_ consisting of the floor of the ocean beyond that depth; and Mill
+  proposed to take the line of mean-sphere level, instead of the
+  empirical depth of 1000 fathoms, as the boundary between the
+  transitional and abysmal areas.
+
+  An elaborate criticism of all the existing data regarding the volume
+  relations of the vertical relief of the globe was made in 1894 by
+  Professor Hermann Wagner, whose recalculations of volumes and mean
+  heights--the best results which have yet been obtained--led to the
+  following conclusions.[18]
+
+
+    Areas of the crust according to Wagner.
+
+  The area of the dry land was taken as 28.3% of the surface of the
+  globe, and that of the oceans as 71.7%. The mean height deduced for
+  the land was 2300 ft. above sea-level, the mean depth of the sea
+  11,500 ft. below, while the position of mean-sphere level comes out as
+  7500 ft. (1250 fathoms) below sea-level. From this it would appear
+  that 43% of the earth's surface was above and 57% below the mean
+  level. It must be noted, however, that since 1895 the soundings of
+  Nansen in the north polar area, of the "Valdivia," "Belgica," "Gauss"
+  and "Scotia" in the Southern Ocean, and of various surveying ships in
+  the North and South Pacific, have proved that the mean depth of the
+  ocean is considerably greater than had been supposed, and mean-sphere
+  level must therefore lie deeper than the calculations of 1895 show;
+  possibly not far from the position deduced from the freer estimate of
+  1888. The whole of the available data were utilized by the prince of
+  Monaco in 1905 in the preparation of a complete bathymetrical map of
+  the oceans on a uniform scale, which must long remain the standard
+  work for reference on ocean depths.
+
+  By the device of a hypsographic curve co-ordinating the vertical
+  relief and the areas of the earth's surface occupied by each zone of
+  elevation, according to the system introduced by Supan,[19] Wagner
+  showed his results graphically.
+
+  This curve with the values reduced from metres to feet is reproduced
+  below.
+
+  Wagner subdivides the earth's surface, according to elevation, into
+  the following five regions:
+
+
+    _Wagner's Divisions of the Earth's Crust:_
+
+    +---------------------+-----------+-------------+-------------+
+    |        Name.        |Per cent of|    From     |     To      |
+    |                     |  Surface. |             |             |
+    +---------------------+-----------+-------------+-------------+
+    | Depressed area      |     3     |   Deepest.  |-16,400 feet.|
+    | Oceanic plateau     |    54     |-16,400 feet.|- 7,400   "  |
+    | Continental slope   |     9     |- 7,400   "  |-   660   "  |
+    | Continental plateau |    28     |-   660   "  |+ 3,000   "  |
+    | Culminating area    |     6     |+ 3,300   "  |   Highest.  |
+    +---------------------+-----------+-------------+-------------+
+
+  [Illustration]
+
+  The continental plateau might for purposes of detailed study be
+  divided into the _continental shelf_ from -660 ft. to sea-level, and
+  _lowlands_ from sea-level to +660 ft. (corresponding to the mean level
+  of the whole globe).[20] _Uplands_ reaching from 660 ft. to 2300 (the
+  approximate mean level of the land), and _highlands_, from 2300
+  upwards, might also be distinguished.
+
+
+    Arrangement of world-ridges and hollows.
+
+  A striking fact in the configuration of the crust is that each
+  continent, or elevated mass of the crust, is diametrically opposite to
+  an ocean basin or great depression; the only partial exception being
+  in the case of southern South America, which is antipodal to eastern
+  Asia. Professor C. Lapworth has generalized the grand features of
+  crustal relief in a scheme of attractive simplicity. He sees
+  throughout all the chaos of irregular crust-forms the recurrence of a
+  certain harmony, a succession of folds or waves which build up all the
+  minor features.[21] One great series of crust waves from east to west
+  is crossed by a second great series of crust waves from north to
+  south, giving rise by their interference to six great elevated masses
+  (the continents), arranged in three groups, each consisting of a
+  northern and a southern member separated by a minor depression. These
+  elevated masses are divided from one another by similar great
+  depressions.
+
+
+    Lapworth's fold-theory.
+
+  He says: "The surface of each of our great continental masses of land
+  resembles that of a long and broad arch-like form, of which we see the
+  simplest type in the New World. The surface of the North American arch
+  is sagged downwards in the middle into a central depression which lies
+  between two long marginal plateaus, and these plateaus are finally
+  crowned by the wrinkled crests which form its two modern mountain
+  systems. The surface of each of our ocean floors exactly resembles
+  that of a continent turned upside down. Taking the Atlantic as our
+  simplest type, we may say that the surface of an ocean basin resembles
+  that of a mighty trough or syncline, buckled up more or less centrally
+  in a medial ridge, which is bounded by two long and deep marginal
+  hollows, in the cores of which still deeper grooves sink to the
+  profoundest depths. This complementary relationship descends even to
+  the minor features of the two. Where the great continental sag sinks
+  below the ocean level, we have our gulfs and our Mediterraneans, seen
+  in our type continent, as the Mexican Gulf and Hudson Bay. Where the
+  central oceanic buckle attains the water-line we have our oceanic
+  islands, seen in our type ocean, as St Helena and the Azores. Although
+  the apparent crust-waves are neither equal in size nor symmetrical in
+  form, this complementary relationship between them is always
+  discernible. The broad Pacific depression seems to answer to the broad
+  elevation of the Old World--the narrow trough of the Atlantic to the
+  narrow continent of America."
+
+
+    Suess's theory.
+
+  The most thorough discussion of the great features of terrestrial
+  relief in the light of their origin is that by Professor E. Suess,[22]
+  who points out that the plan of the earth is the result of two
+  movements of the crust--one, subsidence over wide areas, giving rise
+  to oceanic depressions and leaving the continents protuberant; the
+  other, folding along comparatively narrow belts, giving rise to
+  mountain ranges. This theory of crust blocks dropped by subsidence is
+  opposed to Lapworth's theory of vast crust-folds, but geology is the
+  science which has to decide between them.
+
+  Geomorphology is concerned, however, in the suggestions which have
+  been made as to the cause of the distribution of heap and hollow in
+  the larger features of the crust. Elie de Beaumont, in his
+  speculations on the relation between the direction of mountain ranges
+  and their geological age and character, was feeling towards a
+  comprehensive theory of the forms of crustal relief; but his ideas
+  were too geometrical, and his theory that the earth is a spheroid
+  built up on a rhombic dodecahedron, the pentagonal faces of which
+  determined the direction of mountain ranges, could not be proved.[23]
+  The "tetrahedral theory" brought forward by Lowthian Green,[24] that
+  the form of the earth is a spheroid based on a regular tetrahedron, is
+  more serviceable, because it accounts for three very interesting facts
+  of the terrestrial plan--(1) the antipodal position of continents and
+  ocean basins; (2) the triangular outline of the continents; and (3)
+  the excess of sea in the southern hemisphere. Recent investigations
+  have recalled attention to the work of Lowthian Green, but the
+  question is still in the controversial stage.[25] The study of tidal
+  strain in the earth's crust by Sir George Darwin has led that
+  physicist to indicate the possibility of the triangular form and
+  southerly direction of the continents being a result of the
+  differential or tidal attraction of the sun and moon. More recently
+  Professor A.E.H. Love has shown that the great features of the relief
+  of the lithosphere may be expressed by spherical harmonics of the
+  first, second and third degrees, and their formation related to
+  gravitational action in a sphere of unequal density.[26]
+
+  In any case it is fully recognized that the plan of the earth is so
+  clear as to leave no doubt as to its being due to some general cause
+  which should be capable of detection.
+
+
+    The continents.
+
+  If the level of the sea were to become coincident with the mean level
+  of the lithosphere, there would result one tri-radiate land-mass of
+  nearly uniform outline and one continuous sheet of water broken by
+  few islands. The actual position of sea-level lies so near the summit
+  of the crust-heap that the varied relief of the upper portion leads to
+  the formation of a complicated coast-line and a great number of
+  detached portions of land. The hydrosphere is, in fact, continuous,
+  and the land is all in insular masses: the largest is the Old World of
+  Europe, Asia and Africa; the next in size, America; the third,
+  possibly, Antarctica; the fourth, Australia; the fifth, Greenland.
+  After this there is a considerable gap before New Guinea, Borneo,
+  Madagascar, Sumatra and the vast multitude of smaller islands
+  descending in size by regular gradations to mere rocks. The contrast
+  between island and mainland was natural enough in the days before the
+  discovery of Australia, and the mainland of the Old World was
+  traditionally divided into three continents. These "continents,"
+  "parts of the earth," or "quarters of the globe," proved to be
+  convenient divisions; America was added as a fourth, and subsequently
+  divided into two, while Australia on its discovery was classed
+  sometimes as a new continent, sometimes merely as an island, sometimes
+  compromisingly as an island-continent, according to individual
+  opinion. The discovery of the insularity of Greenland might again give
+  rise to the argument as to the distinction between island and
+  continent. Although the name of continent was not applied to large
+  portions of land for any physical reasons, it so happens that there is
+  a certain physical similarity or homology between them which is not
+  shared by the smaller islands or peninsulas.
+
+
+    Homology of continents.
+
+  The typical continental form is triangular as regards its sea-level
+  outline. The relief of the surface typically includes a central plain,
+  sometimes dipping below sea-level, bounded by lateral highlands or
+  mountain ranges, loftier on one side than on the other, the higher
+  enclosing a plateau shut in by mountains. South America and North
+  America follow this type most closely; Eurasia (the land mass of
+  Europe and Asia) comes next, while Africa and Australia are farther
+  removed from the type, and the structure of Antarctica and Greenland
+  is unknown.
+
+  If the continuous, unbroken, horizontal extent of land in a continent
+  is termed its _trunk_,[27] and the portions cut up by inlets or
+  channels of the sea into islands and peninsulas the _limbs_, it is
+  possible to compare the continents in an instructive manner.
+
+  The following table is from the statistics of Professor H. Wagner,[28]
+  his metric measurements being transposed into British units:
+
+
+    _Comparison of the Continents._
+
+    +---------------+-------+-------+-------+------+--------+------+------+
+    |               |       |       |       | Area |        |      |      |
+    |               | Area  | Mean  |  Area |penin-|  Area  | Area | Area |
+    |               | total |height,| trunk,|sulas,|islands,|limbs,|limbs,|
+    |               |  mil. | feet. |  mil. | mil. |  mil.  | mil. | per  |
+    |               | sq. m.|       | sq. m.|sq. m.| sq. m. |sq. m.| cent.|
+    +---------------+-------+-------+-------+------+--------+------+------+
+    | Old World     | 35.8  | 2360  |       |      |        |      |      |
+    | New World     | 16.2  | 2230  |       |      |        |      |      |
+    | Eurasia       | 20.85 | 2620  | 15.42 | 4.09 |  1.34  | 5.43 | 26   |
+    | Africa        | 11.46 | 2130  | 11.22 |  ..  |  0.24  | 0.24 |  2.1 |
+    | North America |  9.26 | 2300  |  6.92 | 0.78 |  1.56  | 2.34 | 25   |
+    | South America |  6.84 | 1970  |  6.76 | 0.02 |  0.06  | 0.08 |  1.1 |
+    | Australia     |  3.43 | 1310  |  2.77 | 0.16 |  0.50  | 0.66 | 19   |
+    | Asia          | 17.02 | 3120  | 12.93 | 3.05 |  1.04  | 4.09 | 24   |
+    | Europe        |  3.83 |  980  |  2.49 | 1.04 |  0.30  | 1.34 | 35   |
+    +---------------+-------+-------+-------+------+--------+------+------+
+
+
+    Islands.
+
+  The usual classification of islands is into continental and oceanic.
+  The former class includes all those which rise from the continental
+  shelf, or show evidence in the character of their rocks of having at
+  one time been continuous with a neighbouring continent. The latter
+  rise abruptly from the oceanic abysses. Oceanic islands are divided
+  according to their geological character into volcanic islands and
+  those of organic origin, including coral islands. More elaborate
+  subdivisions according to structure, origin and position have been
+  proposed.[29] In some cases a piece of land is only an island at high
+  water, and by imperceptible gradation the form passes into a
+  peninsula. The typical peninsula is connected with the mainland by a
+  relatively narrow isthmus; the name is, however, extended to any limb
+  projecting from the trunk of the mainland, even when, as in the Indian
+  peninsula, it is connected by its widest part.
+
+
+    Coasts.
+
+  Small peninsulas are known as promontories or headlands, and the
+  extremity as a cape. The opposite form, an inlet of the sea, is known
+  when wide as a gulf, bay or bight, according to size and degree of
+  inflection, or as a fjord or ria when long and narrow. It is
+  convenient to employ a specific name for a projection of a coast-line
+  less pronounced than a peninsula, and for an inlet less pronounced
+  than a bay or bight; outcurve and incurve may serve the turn. The
+  varieties of coast-lines were reduced to an exact classification by
+  Richthofen, who grouped them according to the height and slope of the
+  land into cliff-coasts (_Steilkusten_)--narrow beach coasts with
+  cliffs, wide beach coasts with cliffs, and low coasts, subdividing
+  each group according as the coast-line runs parallel to or crosses the
+  line of strike of the mountains, or is not related to mountain
+  structure. A further subdivision depends on the character of the
+  inter-relation of land and sea along the shore producing such types as
+  a fjord-coast, ria-coast or lagoon-coast. This extremely elaborate
+  subdivision may be reduced, as Wagner points out, to three types--the
+  continental coast where the sea comes up to the solid rock-material of
+  the land; the marine coast, which is formed entirely of soft material
+  sorted out by the sea; and the composite coast, in which both forms
+  are combined.
+
+
+    Coast-lines.
+
+  On large-scale maps it is necessary to show two coast-lines, one for
+  the highest, the other for the lowest tide; but in small-scale maps a
+  single line is usually wider than is required to represent the whole
+  breadth of the inter-tidal zone. The measurement of a coast-line is
+  difficult, because the length will necessarily be greater when
+  measured on a large-scale map where minute irregularities can be taken
+  into account. It is usual to distinguish between the general
+  coast-line measured from point to point of the headlands disregarding
+  the smaller bays, and the detailed coast-line which takes account of
+  every inflection shown by the map employed, and follows up river
+  entrances to the point where tidal action ceases. The ratio between
+  these two coast-lines represents the "coastal development" of any
+  region.
+
+
+    Submarine forms.
+
+  While the forms of the sea-bed are not yet sufficiently well known to
+  admit of exact classification, they are recognized to be as a rule
+  distinct from the forms of the land, and the importance of using a
+  distinctive terminology is felt. Efforts have been made to arrive at a
+  definite international agreement on this subject, and certain terms
+  suggested by a committee were adopted by the Eighth International
+  Geographical Congress at New York in 1904.[30] The forms of the ocean
+  floor include the "shelf," or shallow sea margin, the "depression," a
+  general term applied to all submarine hollows, and the "elevation." A
+  depression when of great extent is termed a "basin," when it is of a
+  more or less round form with approximately equal diameters, a "trough"
+  when it is wide and elongated with gently sloping borders, and a
+  "trench" when narrow and elongated with steeply sloping borders, one
+  of which rises higher than the other. The extension of a trough or
+  basin penetrating the land or an elevation is termed an "embayment"
+  when wide, and a "gully" when long and narrow; and the deepest part of
+  a depression is termed a "deep." A depression of small extent when
+  steep-sided is termed a "caldron," and a long narrow depression
+  crossing a part of the continental border is termed a "furrow." An
+  elevation of great extent which rises at a very gentle angle from a
+  surrounding depression is termed a "rise," one which is relatively
+  narrow and steep-sided a "ridge," and one which is approximately equal
+  in length and breadth but steep-sided a "plateau," whether it springs
+  direct from a depression or from a rise. An elevation of small extent
+  is distinguished as a "dome" when it is more than 100 fathoms from the
+  surface, a "bank" when it is nearer the surface than 100 fathoms but
+  deeper than 6 fathoms, and a "shoal" when it comes within 6 fathoms of
+  the surface and so becomes a serious danger to shipping. The highest
+  point of an elevation is termed a "height," if it does not form an
+  island or one of the minor forms.
+
+
+    Land forms.
+
+  The forms of the dry land are of infinite variety, and have been
+  studied in great detail.[31] From the descriptive or topographical
+  point of view, geometrical form alone should be considered; but the
+  origin and geological structure of land forms must in many cases be
+  taken into account when dealing with the function they exercise in the
+  control of mobile distributions. The geographers who have hitherto
+  given most attention to the forms of the land have been trained as
+  geologists, and consequently there is a general tendency to make
+  origin or structure the basis of classification rather than form
+  alone.
+
+
+    The six elementary land forms.
+
+  The fundamental form-elements may be reduced to the six proposed by
+  Professor Penck as the basis of his double system of classification by
+  form and origin.[32] These may be looked upon as being all derived by
+  various modifications or arrangements of the single form-unit, the
+  _slope_ or inclined plane surface. No one form occurs alone, but
+  always grouped together with others in various ways to make up
+  districts, regions and lands of distinctive characters. The
+  form-elements are:
+
+  1. The _plain_ or gently inclined uniform surface.
+
+  2. The _scarp_ or steeply inclined slope; this is necessarily of small
+  extent except in the direction of its length.
+
+  3. The _valley_, composed of two lateral parallel slopes inclined
+  towards a narrow strip of plain at a lower level which itself slopes
+  downwards in the direction of its length. Many varieties of this
+  fundamental form may be distinguished.
+
+  4. The _mount_, composed of a surface falling away on every side from
+  a particular place. This place may either be a point, as in a volcanic
+  cone, or a line, as in a mountain range or ridge of hills.
+
+  5. The _hollow_ or form produced by a land surface sloping inwards
+  from all sides to a particular lowest place, the converse of a mount.
+
+  6. The _cavern_ or space entirely surrounded by a land surface.
+
+
+    Geology and land forms.
+
+  These forms never occur scattered haphazard over a region, but always
+  in an orderly subordination depending on their mode of origin. The
+  dominant forms result from crustal movements, the subsidiary from
+  secondary reactions during the action of the primitive forms on mobile
+  distributions. The geological structure and the mineral composition of
+  the rocks are often the chief causes determining the character of the
+  land forms of a region. Thus the scenery of a limestone country
+  depends on the solubility and permeability of the rocks, leading to
+  the typical Karst-formations of caverns, swallow-holes and underground
+  stream courses, with the contingent phenomena of dry valleys and
+  natural bridges. A sandy beach or desert owes its character to the
+  mobility of its constituent sand-grains, which are readily drifted and
+  piled up in the form of dunes. A region where volcanic activity has
+  led to the embedding of dykes or bosses of hard rock amongst softer
+  strata produces a plain broken by abrupt and isolated eminences.[33]
+
+
+    Classification of mountains.
+
+  It would be impracticable to go fully into the varieties of each
+  specific form; but, partly as an example of modern geographical
+  classification, partly because of the exceptional importance of
+  mountains amongst the features of the land, one exception may be made.
+  The classification of mountains into types has usually had regard
+  rather to geological structure than to external form, so that some
+  geologists would even apply the name of a mountain range to a region
+  not distinguished by relief from the rest of the country if it bear
+  geological evidence of having once been a true range. A mountain may
+  be described (it cannot be defined) as an elevated region of irregular
+  surface rising comparatively abruptly from lower ground. The actual
+  elevation of a summit above sea-level does not necessarily affect its
+  mountainous character; a gentle eminence, for instance, rising a few
+  hundred feet above a tableland, even if at an elevation of say 15,000
+  ft., could only be called a hill.[34] But it may be said that any
+  abrupt slope of 2000 ft. or more in vertical height may justly be
+  called a mountain, while abrupt slopes of lesser height may be called
+  hills. Existing classifications, however, do not take account of any
+  difference in kind between mountain and hills, although it is common
+  in the German language to speak of _Hugelland_, _Mittelgebirge_ and
+  _Hochgebirge_ with a definite significance.
+
+  The simple classification employed by Professor James Geikie[35] into
+  mountains of accumulation, mountains of elevation and mountains of
+  circumdenudation, is not considered sufficiently thorough by German
+  geographers, who, following Richthofen, generally adopt a
+  classification dependent on six primary divisions, each of which is
+  subdivided. The terms employed, especially for the subdivisions,
+  cannot be easily translated into other languages, and the English
+  equivalents in the following table are only put forward tentatively:--
+
+    RICHTHOFEN'S CLASSIFICATION OF MOUNTAINS[36]
+
+      I. _Tektonische Gebirge_--Tectonic mountains.
+        (a) _Bruchgebirge oder Schollengebirge_--Block mountains.
+            1. _Einseitige Schollengebirge oder Schollenrandgebirge_--
+                  Scarp or tilted block mountains.
+                    (i.) _Tafelscholle_--Table blocks.
+                   (ii.) _Abrasionsscholle_--Abraded blocks.
+                  (iii.) _Transgressionsscholle_--Blocks of unconformable
+                              strata.
+            2. _Flexurgebirge_--Flexure mountains.
+            3. _Horstgebirge_--Symmetrical block mountains.
+        (b) _Faltungsgebirge_--Fold mountains.
+            1. _Homoomorphe Faltungsgebirge_--Homomorphic fold mountains.
+            2. _Heteromorphe Faltungsgebirge_--Heteromorphic fold
+                    mountains.
+
+     II. _Rumpfgebirge oder Abrasionsgebirge_--Trunk or abraded mountains.
+
+    III. _Ausbruchsgebirge_--Eruptive mountains.
+
+     IV. _Aufschuttungsgebirge_--Mountains of accumulation.
+
+      V. _Flachboden_--Plateaux.
+        (a) _Abrasionsplatten_--Abraded plateaux.
+        (b) _Marines Flachland_--Plain of marine erosion.
+        (c) _Schichtungstafelland_--Horizontally stratified tableland.
+        (d) _Ubergusstafelland_--Lava plain.
+        (e) _Stromflachland_--River plain.
+        (f) _Flachboden der atmospharischen Aufschuttung_--Plains of
+                   aeolian formation.
+
+     VI. _Erosionsgebirge_--Mountains of erosion.
+
+
+    Mountain forms.
+
+  From the morphological point of view it is more important to
+  distinguish the associations of forms, such as the _mountain mass_ or
+  group of mountains radiating from a centre, with the valleys furrowing
+  their flanks spreading towards every direction; the _mountain chain_
+  or line of heights, forming a long narrow ridge or series of ridges
+  separated by parallel valleys; the _dissected plateau_ or highland,
+  divided into mountains of circumdenudation by a system of deeply-cut
+  valleys; and the _isolated peak_, usually a volcanic cone or a hard
+  rock mass left projecting after the softer strata which embedded it
+  have been worn away (Monadnock of Professor Davis).
+
+
+    Distribution of mountains.
+
+  The geographical distribution of mountains is intimately associated
+  with the great structural lines of the continents of which they form
+  the culminating region. Lofty lines of fold mountains form the
+  "backbones" of North America in the Rocky Mountains and the west coast
+  systems, of South America in the Cordillera of the Andes, of Europe in
+  the Pyrenees, Alps, Carpathians and Caucasus, and of Asia in the
+  mountains of Asia Minor, converging on the Pamirs and diverging thence
+  in the Himalaya and the vast mountain systems of central and eastern
+  Asia. The remarkable line of volcanoes around the whole coast of the
+  Pacific and along the margin of the Caribbean and Mediterranean seas
+  is one of the most conspicuous features of the globe.
+
+
+    Functions of land forms.
+
+    Land waste.
+
+    Glaciers.
+
+  If land forms may be compared to organs, the part they serve in the
+  economy of the earth may, without straining the term, be characterized
+  as functions. The first and simplest function of the land surface is
+  that of guiding loose material to a lower level. The downward pull of
+  gravity suffices to bring about the fall of such material, but the
+  path it will follow and the distance it will travel before coming to
+  rest depend upon the land form. The loose material may, and in an arid
+  region does, consist only of portions of the higher parts of the
+  surface detached by the expansion and contraction produced by heating
+  and cooling due to radiation. Such broken material rolling down a
+  uniform scarp would tend to reduce its steepness by the loss of
+  material in the upper part and by the accumulation of a mound or scree
+  against the lower part of the slope. But where the side is not a
+  uniform scarp, but made up of a series of ridges and valleys, the
+  tendency will be to distribute the detritus in an irregular manner,
+  directing it away from one place and collecting it in great masses in
+  another, so that in time the land form assumes a new appearance. Snow
+  accumulating on the higher portions of the land, when compacted into
+  ice and caused to flow downwards by gravity, gives rise, on account of
+  its more coherent character, to continuous glaciers, which mould
+  themselves to the slopes down which they are guided, different
+  ice-streams converging to send forward a greater volume. Gradually
+  coming to occupy definite beds, which are deepened and polished by the
+  friction, they impress a characteristic appearance on the land, which
+  guides them as they traverse it, and, although the ice melts at lower
+  levels, vast quantities of clay and broken stones are brought down and
+  deposited in terminal moraines where the glacier ends.
+
+
+    Rain.
+
+    River systems.
+
+    Adjustment of rivers to land.
+
+  Rain is by far the most important of the inorganic mobile
+  distributions upon which land forms exercise their function of
+  guidance and control. The precipitation of rain from the aqueous
+  vapour of the atmosphere is caused in part by vertical movements of
+  the atmosphere involving heat changes and apparently independent of
+  the surface upon which precipitation occurs; but in greater part it is
+  dictated by the form and altitude of the land surface and the
+  direction of the prevailing winds, which itself is largely influenced
+  by the land. It is on the windward faces of the highest ground, or
+  just beyond the summit of less dominant heights upon the leeward side,
+  that most rain falls, and all that does not evaporate or percolate
+  into the ground is conducted back to the sea by a route which depends
+  only on the form of the land. More mobile and more searching than ice
+  or rock rubbish, the trickling drops are guided by the deepest lines
+  of the hillside in their incipient flow, and as these lines converge,
+  the stream, gaining strength, proceeds in its torrential course to
+  carve its channel deeper and entrench itself in permanent occupation.
+  Thus the stream-bed, from which at first the water might be blown away
+  into a new channel by a gale of wind, ultimately grows to be the
+  strongest line of the landscape. As the main valley deepens, the
+  tributary stream-beds are deepened also, and gradually cut their way
+  headwards, enlarging the area whence they draw their supplies. Thus
+  new land forms are created--valleys of curious complexity, for
+  example--by the "capture" and diversion of the water of one river by
+  another, leading to a change of watershed.[37] The minor tributaries
+  become more numerous and more constant, until the system of torrents
+  has impressed its own individuality on the mountain side. As the river
+  leaves the mountain, ever growing by the accession of tributaries, it
+  ceases, save in flood time, to be a formidable instrument of
+  destruction; the gentler slope of the land surface gives to it only
+  power sufficient to transport small stones, gravel, sand and
+  ultimately mud. Its valley banks are cut back by the erosion of minor
+  tributaries, or by rain-wash if the climate be moist, or left steep
+  and sharp while the river deepens its bed if the climate be arid. The
+  outline of the curve of a valley's sides ultimately depends on the
+  angle of repose of the detritus which covers them, if there has been
+  no subsequent change, such as the passage of a glacier along the
+  valley, which tends to destroy the regularity of the cross-section.
+  The slope of the river bed diminishes until the plain compels the
+  river to move slowly, swinging in _meanders_ proportioned to its size,
+  and gradually, controlled by the flattening land, ceasing to transport
+  material, but raising its banks and silting up its bed by the dropped
+  sediment, until, split up and shoaled, its distributaries struggle
+  across its delta to the sea. This is the typical river of which there
+  are infinite varieties, yet every variety would, if time were given,
+  and the land remained unchanged in level relatively to the sea,
+  ultimately approach to the type. Movements of the land either of
+  subsidence or elevation, changes in the land by the action of erosion
+  in cutting back an escarpment or cutting through a col, changes in
+  climate by affecting the rainfall and the volume of water, all tend to
+  throw the river valley out of harmony with the actual condition of its
+  stream. There is nothing more striking in geography than the
+  perfection of the adjustment of a great river system to its valleys
+  when the land has remained stable for a very lengthened period. Before
+  full adjustment has been attained the river bed may be broken in
+  places by waterfalls or interrupted by lakes; after adjustment the bed
+  assumes a permanent outline, the slope diminishing more and more
+  gradually, without a break in its symmetrical descent. Excellent
+  examples of the indecisive drainage of a new land surface, on which
+  the river system has not had time to impress itself, are to be seen in
+  northern Canada and in Finland, where rivers are separated by scarcely
+  perceptible divides, and the numerous lakes frequently belong to more
+  than one river system.
+
+
+    The geographical cycle.
+
+  The action of rivers on the land is so important that it has been made
+  the basis of a system of physical geography by Professor W.M. Davis,
+  who classifies land surfaces in terms of the three factors--structure,
+  process and time.[38] Of these time, during which the process is
+  acting on the structure, is the most important. A land may thus be
+  characterized by its position in the "geographical cycle", or cycle of
+  erosion, as young, mature or old, the last term being reached when the
+  base-level of erosion is attained, and the land, however varied its
+  relief may have been in youth or maturity, is reduced to a nearly
+  uniform surface or peneplain. By a re-elevation of a peneplain the
+  rivers of an old land surface may be restored to youthful activity,
+  and resume their shaping action, deepening the old valleys and
+  initiating new ones, starting afresh the whole course of the
+  geographical cycle. It is, however, not the action of the running
+  water on the land, but the function exercised by the land on the
+  running water, that is considered here to be the special province of
+  geography. At every stage of the geographical cycle the land forms, as
+  they exist at that stage, are concerned in guiding the condensation
+  and flow of water in certain definite ways. Thus, for example, in a
+  mountain range at right angles to a prevailing sea-wind, it is the
+  land forms which determine that one side of the range shall be richly
+  watered and deeply dissected by a complete system of valleys, while
+  the other side is dry, indefinite in its valley systems, and sends
+  none of its scanty drainage to the sea. The action of rain, ice and
+  rivers conspires with the movement of land waste to strip the layer of
+  soil from steep slopes as rapidly as it forms, and to cause it to
+  accumulate on the flat valley bottoms, on the graceful flattened cones
+  of alluvial fans at the outlet of the gorges of tributaries, or in the
+  smoothly-spread surface of alluvial plains.
+
+  The whole question of the regime of rivers and lakes is sometimes
+  treated under the name hydrography, a name used by some writers in the
+  sense of marine surveying, and by others as synonymous with
+  oceanography. For the study of rivers alone the name potamology[39]
+  has been suggested by Penck, and the subject being of much practical
+  importance has received a good deal of attention.[40]
+
+
+    Lakes and internal drainage.
+
+  The study of lakes has also been specialized under the name of
+  limnology (see LAKE).[41] The existence of lakes in hollows of the
+  land depends upon the balance between precipitation and evaporation. A
+  stream flowing into a hollow will tend to fill it up, and the water
+  will begin to escape as soon as its level rises high enough to reach
+  the lowest part of the rim. In the case of a large hollow in a very
+  dry climate the rate of evaporation may be sufficient to prevent the
+  water from ever rising to the lip, so that there is no outflow to the
+  sea, and a basin of internal drainage is the result. This is the case,
+  for instance, in the Caspian sea, the Aral and Balkhash lakes, the
+  Tarim basin, the Sahara, inner Australia, the great basin of the
+  United States and the Titicaca basin. These basins of internal
+  drainage are calculated to amount to 22% of the land surface. The
+  percentages of the land surface draining to the different oceans are
+  approximately--Atlantic, 34.3%; Arctic sea, 16.5%; Pacific, 14.4%;
+  Indian Ocean, 12.8%.[42]
+
+
+    Terminology of river systems.
+
+  The parts of a river system have not been so clearly defined as is
+  desirable, hence the exaggerated importance popularly attached to "the
+  source" of a river. A well-developed river system has in fact many
+  equally important and widely-separated sources, the most distant from
+  the mouth, the highest, or even that of largest initial volume not
+  being necessarily of greater geographical interest than the rest. The
+  whole of the land which directs drainage towards one river is known as
+  its basin, catchment area or drainage area--sometimes, by an incorrect
+  expression, as its valley or even its watershed. The boundary line
+  between one drainage area and others is rightly termed the watershed,
+  but on account of the ambiguity which has been tolerated it is better
+  to call it water-parting or, as in America, divide. The only other
+  important term which requires to be noted here is _talweg_, a word
+  introduced from the German into French and English, and meaning the
+  deepest line along the valley, which is necessarily occupied by a
+  stream unless the valley is dry.
+
+  The functions of land forms extend beyond the control of the
+  circulation of the atmosphere, the hydrosphere and the water which is
+  continually being interchanged between them; they are exercised with
+  increased effect in the higher departments of biogeography and
+  anthropogeography.
+
+
+    Biogeography.
+
+  The sum of the organic life on the globe is termed by some geographers
+  the biosphere, and it has been estimated that the whole mass of living
+  substance in existence at one time would cover the surface of the
+  earth to a depth of one-fifth of an inch.[43] The distribution of
+  living organisms is a complex problem, a function of many factors,
+  several of which are yet but little known. They include the biological
+  nature of the organism and its physical environment, the latter
+  involving conditions in which geographical elements, direct or
+  indirect, preponderate. The direct geographical elements are the
+  arrangement of land and sea (continents and islands standing in sharp
+  contrast) and the vertical relief of the globe, which interposes
+  barriers of a less absolute kind between portions of the same land
+  area or oceanic depression. The indirect geographical elements, which,
+  as a rule, act with and intensify the direct, are mainly climatic; the
+  prevailing winds, rainfall, mean and extreme temperatures of every
+  locality depending on the arrangement of land and sea and of land
+  forms. Climate thus guided affects the weathering of rocks, and so
+  determines the kind and arrangement of soil. Different species of
+  organisms come to perfection in different climates; and it may be
+  stated as a general rule that a species, whether of plant or animal,
+  once established at one point, would spread over the whole zone of the
+  climate congenial to it unless some barrier were interposed to its
+  progress. In the case of land and fresh-water organisms the sea is the
+  chief barrier; in the case of marine organisms, the land. Differences
+  in land forms do not exert great influence on the distribution of
+  living creatures directly, but indirectly such land forms as mountain
+  ranges and internal drainage basins are very potent through their
+  action on soil and climate. A snow-capped mountain ridge or an arid
+  desert forms a barrier between different forms of life which is often
+  more effective than an equal breadth of sea. In this way the surface
+  of the land is divided into numerous natural regions, the flora and
+  fauna of each of which include some distinctive species not shared by
+  the others. The distribution of life is discussed in the various
+  articles in this _Encyclopaedia_ dealing with biological, botanical
+  and zoological subjects.[44]
+
+
+    Floral zones.
+
+  The classification of the land surface into areas inhabited by
+  distinctive groups of plants has been attempted by many
+  phyto-geographers, but without resulting in any scheme of general
+  acceptance. The simplest classification is perhaps that of Drude
+  according to climatic zones, subdivided according to continents. This
+  takes account of--(1) the _Arctic-Alpine_ zone, including all the
+  vegetation of the region bordering on perpetual snow; (2) the _Boreal_
+  zone, including the temperate lands of North America, Europe and Asia,
+  all of which are substantially alike in botanical character; (3) the
+  _Tropical_ zone, divided sharply into (a) the tropical zone of the New
+  World, and (b) the tropical zone of the Old World, the forms of which
+  differ in a significant degree; (4) the _Austral_ zone, comprising all
+  continental land south of the equator, and sharply divided into three
+  regions the floras of which are strikingly distinct--(a) South
+  American, (b) South African and (c) Australian; (5) the _Oceanic_,
+  comprising all oceanic islands, the flora of which consists
+  exclusively of forms whose seeds could be drifted undestroyed by ocean
+  currents or carried by birds. To these might be added the antarctic,
+  which is still very imperfectly known. Many subdivisions and
+  transitional zones have been suggested by different authors.
+
+
+    Vegetation areas.
+
+  From the point of view of the economy of the globe this classification
+  by species is perhaps less important than that by mode of life and
+  physiological character in accordance with environment. The following
+  are the chief areas of vegetational activity usually recognized: (1)
+  The ice-deserts of the arctic and antarctic and the highest mountain
+  regions, where there is no vegetation except the lowest forms, like
+  that which causes "red snow." (2) The tundra or region of intensely
+  cold winters, forbidding tree-growth, where mosses and lichens cover
+  most of the ground when unfrozen, and shrubs occur of species which in
+  other conditions are trees, here stunted to the height of a few
+  inches. A similar zone surrounds the permanent snow on lofty mountains
+  in all latitudes. The tundra passes by imperceptible gradations into
+  the moor, bog and heath of warmer climates. (3) The temperate forests
+  of evergreen or deciduous trees, according to circumstances, which
+  occupy those parts of both temperate zones where rainfall and sunlight
+  are both abundant. (4) The grassy steppes or prairies where the
+  rainfall is diminished and temperatures are extreme, and grass is the
+  prevailing form of vegetation. These pass imperceptibly into--(5) the
+  arid desert, where rainfall is at a minimum, and the only plants are
+  those modified to subsist with the smallest supply of water. (6) The
+  tropical forest, which represents the maximum of plant luxuriance,
+  stimulated by the heaviest rainfall, greatest heat and strongest
+  light. These divisions merge one into the other, and admit of almost
+  indefinite subdivision, while they are subject to great modifications
+  by human interference in clearing and cultivating. Plants exhibit the
+  controlling power of environment to a high degree, and thus vegetation
+  is usually in close adjustment to the bolder geographical features of
+  a region.
+
+
+    Faunal realms.
+
+  The divisions of the earth into faunal regions by Dr P.L. Sclater have
+  been found to hold good for a large number of groups of animals as
+  different in their mode of life as birds and mammals, and they may
+  thus be accepted as based on nature. They are six in number: (1)
+  _Palaearctic_, including Europe, Asia north of the Himalaya, and
+  Africa north of the Sahara; (2) _Ethiopian_, consisting of Africa
+  south of the Atlas range, and Madagascar; (3) _Oriental_, including
+  India, Indo-China and the Malay Archipelago north of Wallace's line,
+  which runs between Bali and Lombok; (4) _Australian_, including
+  Australia, New Zealand, New Guinea and Polynesia; (5) _Nearctic_ or
+  North America, north of Mexico; and (6) _Neotropical_ or South
+  America. Each of these divisions is the home of a special fauna, many
+  species of which are confined to it alone; in the Australian region,
+  indeed, practically the whole fauna is peculiar and distinctive,
+  suggesting a prolonged period of complete biological isolation. In
+  some cases, such as the Ethiopian and Neotropical and the Palaearctic
+  and Nearctic regions, the faunas, although distinct, are related,
+  several forms on opposite sides of the Atlantic being analogous, e.g.
+  the lion and puma, ostrich and rhea. Where two of the faunal realms
+  meet there is usually, though not always, a mixing of faunas. These
+  facts have led some naturalists to include the Palaearctic and
+  Nearctic regions in one, termed _Holarctic_, and to suggest
+  transitional regions, such as the _Sonoran_, between North and South
+  America, and the _Mediterranean_, between Europe and Africa, or to
+  create sub-regions, such as Madagascar and New Zealand. Oceanic
+  islands have, as a rule, distinctive faunas and floras which resemble,
+  but are not identical with, those of other islands in similar
+  positions.
+
+
+    Biological distribution as a means of geographical research.
+
+  The study of the evolution of faunas and the comparison of the faunas
+  of distant regions have furnished a trustworthy instrument of
+  pre-historic geographical research, which enables earlier geographical
+  relations of land and sea to be traced out, and the approximate
+  period, or at least the chronological order of the larger changes, to
+  be estimated. In this way, for example, it has been suggested that a
+  land, "Lemuria," once connected Madagascar with the Malay Archipelago,
+  and that a northern extension of the antarctic land once united the
+  three southern continents.
+
+  The distribution of fossils frequently makes it possible to map out
+  approximately the general features of land and sea in long-past
+  geological periods, and so to enable the history of crustal relief to
+  be traced.[45]
+
+
+    Reaction of organisms on environment.
+
+  While the tendency is for the living forms to come into harmony with
+  their environment and to approach the state of equilibrium by
+  successive adjustments if the environment should happen to change, it
+  is to be observed that the action of organisms themselves often tends
+  to change their environment. Corals and other quick-growing calcareous
+  marine organisms are the most powerful in this respect by creating new
+  land in the ocean. Vegetation of all sorts acts in a similar way,
+  either in forming soil and assisting in breaking up rocks, in filling
+  up shallow lakes, and even, like the mangrove, in reclaiming wide
+  stretches of land from the sea. Plant life, utilizing solar light to
+  combine the inorganic elements of water, soil and air into living
+  substance, is the basis of all animal life. This is not by the supply
+  of food alone, but also by the withdrawal of carbonic acid from the
+  atmosphere, by which vegetation maintains the composition of the air
+  in a state fit for the support of animal life. Man in the primitive
+  stages of culture is scarcely to be distinguished from other animals
+  as regards his subjection to environment, but in the higher grades of
+  culture the conditions of control and reaction become much more
+  complicated, and the department of anthropogeography is devoted to
+  their consideration.
+
+
+    Anthropogeography.
+
+  The first requisites of all human beings are food and protection, in
+  their search for which men are brought into intimate relations with
+  the forms and productions of the earth's surface. The degree of
+  dependence of any people upon environment varies inversely as the
+  degree of culture or civilization, which for this purpose may perhaps
+  be defined as the power of an individual to exercise control over the
+  individual and over the environment for the benefit of the community.
+  The development of culture is to a certain extent a question of race,
+  and although forming one species, the varieties of man differ in
+  almost imperceptible gradations with a complexity defying
+  classification (see ANTHROPOLOGY). Professor Keane groups man round
+  four leading types, which may be named the black, yellow, red and
+  white, or the Ethiopic, Mongolic, American and Caucasic. Each may be
+  subdivided, though not with great exactness, into smaller groups,
+  either according to physical characteristics, of which the form of the
+  head is most important, or according to language.
+
+
+    Types of man.
+
+  The black type is found only in tropical or sub-tropical countries,
+  and is usually in a primitive condition of culture, unless educated by
+  contact with people of the white type. They follow the most primitive
+  forms of religion (mainly fetishism), live on products of the woods or
+  of the chase, with the minimum of work, and have only a loose
+  political organization. The red type is peculiar to America,
+  inhabiting every climate from polar to equatorial, and containing
+  representatives of many stages of culture which had apparently
+  developed without the aid or interference of people of any other race
+  until the close of the 15th century. The yellow type is capable of a
+  higher culture, cherishes higher religious beliefs, and inhabits as a
+  rule the temperate zone, although extending to the tropics on one side
+  and to the arctic regions on the other. The white type, originating in
+  the north temperate zone, has spread over the whole world. They have
+  attained the highest culture, profess the purest forms of monotheistic
+  religion, and have brought all the people of the black type and many
+  of those of the yellow under their domination.
+
+  The contrast between the yellow and white types has been softened by
+  the remarkable development of the Japanese following the assimilation
+  of western methods.
+
+  The actual number of human inhabitants in the world has been
+  calculated as follows:
+
+                            By Continents.[46]
+
+    Asia                       875,000,000
+    Europe                     392,000,000
+    Africa                     170,000,000
+    America                    143,000,000
+    Australia and Polynesia      7,000,000
+                             -------------
+      Total                  1,587,000,000
+
+                               By Race.[47]
+
+    White (Caucasic)           770,000,000
+    Yellow (Mong.)             540,000,000
+    Black (Ethiopic)           175,000,000
+    Red (American)              22,000,000
+                             -------------
+      Total                  1,507,000,000
+
+  In round numbers the population of the world is about 1,600,000,000,
+  and, according to an estimate by Ravenstein,[48] the maximum
+  population which it will be possible for the earth to maintain is 6000
+  millions, a number which, if the average rate of increase in 1891
+  continued, would be reached within 200 years.
+
+  While highly civilized communities are able to evade many of the
+  restrictions of environment, to overcome the barriers to
+  intercommunication interposed by land or sea, to counteract the
+  adverse influence of climate, and by the development of trade even to
+  inhabit countries which cannot yield a food-supply, the mass of
+  mankind is still completely under the control of those conditions
+  which in the past determined the distribution and the mode of life of
+  the whole human race.
+
+
+    Influence of environment on man.
+
+  In tropical forests primitive tribes depend on the collection of wild
+  fruits, and in a minor degree on the chase of wild animals, for their
+  food. Clothing is unnecessary; hence there is little occasion for
+  exercising the mental faculties beyond the sense of perception to
+  avoid enemies, or the inventive arts beyond what is required for the
+  simplest weapons and the most primitive fortifications. When the
+  pursuit of game becomes the chief occupation of a people there is of
+  necessity a higher development of courage, skill, powers of
+  observation and invention; and these qualities are still further
+  enhanced in predatory tribes who take by force the food, clothing and
+  other property prepared or collected by a feebler people. The
+  fruit-eating savage cannot stray beyond his woods which bound his life
+  as the water bounds that of a fish; the hunter is free to live on the
+  margin of forests or in open country, while the robber or warrior from
+  some natural stronghold of the mountains sweeps over the adjacent
+  plains and carries his raids into distant lands. Wide grassy steppes
+  lead to the organization of the people as nomads whose wealth consists
+  in flocks and herds, and their dwellings are tents. The nomad not only
+  domesticates and turns to his own use the gentler and more powerful
+  animals, such as sheep, cattle, horses, camels, but even turns some
+  predatory creatures, like the dog, into a means of defending their
+  natural prey. They hunt the beasts of prey destructive to their
+  flocks, and form armed bands for protection against marauders or for
+  purposes of aggression on weaker sedentary neighbours. On the fertile
+  low grounds along the margins of rivers or in clearings of forests,
+  agricultural communities naturally take their rise, dwelling in
+  villages and cultivating the wild grains, which by careful nurture and
+  selection have been turned into rich cereals. The agriculturist as a
+  rule is rooted to the soil. The land he tills he holds, and acquires a
+  closer connexion with a particular patch of ground than either the
+  hunter or the herdsman. In the temperate zone, where the seasons are
+  sharply contrasted, but follow each other with regularity, foresight
+  and self-denial were fostered, because if men did not exercise these
+  qualities seed-time or harvest might pass into lost opportunities and
+  the tribes would suffer. The more extreme climates of arid regions on
+  the margins of the tropics, by the unpredictable succession of
+  droughts and floods, confound the prevision of uninstructed people,
+  and make prudence and industry qualities too uncertain in their
+  results to be worth cultivating. Thus the civilization of agricultural
+  peoples of the temperate zone grew rapidly, yet in each community a
+  special type arose adapted to the soil, the crop and the climate. On
+  the seashore fishing naturally became a means of livelihood, and
+  dwellers by the sea, in virtue of the dangers to which they are
+  exposed from storm and unseaworthy craft, are stimulated to a higher
+  degree of foresight, quicker observation, prompter decision and more
+  energetic action in emergencies than those who live inland. The
+  building and handling of vessels also, and the utilization of such
+  uncontrollable powers of nature as wind and tide, helped forward
+  mechanical invention. To every type of coast there may be related a
+  special type of occupation and even of character; the deep and gloomy
+  fjord, backed by almost impassable mountains, bred bold mariners whose
+  only outlet for enterprise was seawards towards other lands--the
+  _viks_ created the vikings. On the gently sloping margin of the
+  estuary of a great river a view of tranquil inland life was equally
+  presented to the shore-dweller, and the ocean did not present the only
+  prospect of a career. Finally the mountain valley, with its patches of
+  cultivable soil on the alluvial fans of tributary torrents, its narrow
+  pastures on the uplands only left clear of snow in summer, its
+  intensified extremes of climates and its isolation, almost equal to
+  that of an island, has in all countries produced a special type of
+  brave and hardy people, whose utmost effort may bring them comfort,
+  but not wealth, by honest toil, who know little of the outer world,
+  and to whom the natural outlet for ambition is marauding on the
+  fertile plains. The highlander and viking, products of the valleys
+  raised high amid the mountains or half-drowned in the sea, are
+  everywhere of kindred spirit.
+
+  It is in some such manner as these that the natural conditions of
+  regions, which must be conformed to by prudence and utilized by labour
+  to yield shelter and food, have led to the growth of peoples differing
+  in their ways of life, thought and speech. The initial differences so
+  produced are confirmed and perpetuated by the same barriers which
+  divide the faunal or floral regions, the sea, mountains, deserts and
+  the like, and much of the course of past history and present politics
+  becomes clear when the combined results of differing race and
+  differing environment are taken into account.[49]
+
+
+    Density of population.
+
+  The specialization which accompanies the division of labour has
+  important geographical consequences, for it necessitates communication
+  between communities and the interchange of their products. Trade
+  makes it possible to work mineral resources in localities where food
+  can only be grown with great difficulty and expense, or which are even
+  totally barren and waterless, entirely dependent on supplies from
+  distant sources.
+
+  The population which can be permanently supported by a given area of
+  land differs greatly according to the nature of the resources and the
+  requirements of the people. Pastoral communities are always scattered
+  very thinly over large areas; agricultural populations may be almost
+  equally sparse where advanced methods of agriculture and labour-saving
+  machinery are employed; but where a frugal people are situated on a
+  fertile and inexhaustible soil, such as the deltas and river plains of
+  Egypt, India and China, an enormous population may be supported on a
+  small area. In most cases, however, a very dense population can only
+  be maintained in regions where mineral resources have fixed the site
+  of great manufacturing industries. The maximum density of population
+  which a given region can support is very difficult to determine; it
+  depends partly on the race and standard of culture of the people,
+  partly on the nature and origin of the resources on which they depend,
+  partly on the artificial burdens imposed and very largely on the
+  climate. Density of population is measured by the average number of
+  people residing on a unit of area; but in order to compare one part of
+  the world with another the average should, strictly speaking, be taken
+  for regions of equal size or of equal population; and the portions of
+  the country which are permanently uninhabitable ought to be excluded
+  from the calculation.[50] Considering the average density of
+  population within the political limits of countries, the following
+  list is of some value; the figures for a few smaller divisions of
+  large countries are added (in brackets) for comparison:
+
+    _Average Population on 1 sq. m._ (_For 1900 or 1901._)
+
+    +--------------------+---------+-------------------+---------+
+    |      Country.      | Density |      Country.     | Density |
+    |                    | of pop. |                   | of pop. |
+    +--------------------+---------+-------------------+---------+
+    | (Saxony)           |   743*  | Ceylon            |  141**  |
+    | Belgium            |   589*  | Greece            |   97    |
+    | Java               |   568** | European Turkey   |   90    |
+    | (England and Wales)|   558   | Spain             |   97    |
+    | (Bengal)           |   495** | European Russia   |   55**  |
+    | Holland            |   436   | Sweden            |   30    |
+    | United Kingdom     |   344   | United States     |   25    |
+    | Japan              |   317   | Mexico            |   18    |
+    | Italy              |   293   | Norway            |   18    |
+    | China proper       |   270** | Persia            |   15    |
+    | German Empire      |   270   | New Zealand       |    7    |
+    | Austria            |   226   | Argentina         |    5    |
+    | Switzerland        |   207   | Brazil            |    4.5  |
+    | France             |   188   | Eastern States of |         |
+    | Indian Empire      |   167** |   Australia       |    3    |
+    | Denmark            |   160** | Dominion of Canada|    1.5  |
+    | Hungary            |   154** | Siberia           |    1    |
+    | Portugal           |   146   | West Australia    |    0.2  |
+    +--------------------+---------+-------------------+---------+
+      * Almost exclusively industrial.
+     ** Almost exclusively agricultural.
+
+
+    Migration.
+
+  The movement of people from one place to another without the immediate
+  intention of returning is known as migration, and according to its
+  origin it may be classed as centrifugal (directed _from_ a particular
+  area) and centripetal (directed _towards_ a particular area).
+  Centrifugal migration is usually a matter of compulsion; it may be
+  necessitated by natural causes, such as a change of climate leading to
+  the withering of pastures or destruction of agricultural land, to
+  inundation, earthquake, pestilence or to an excess of population over
+  means of support; or to artificial causes, such as the wholesale
+  deportation of a conquered people; or to political or religious
+  persecution. In any case the people are driven out by some adverse
+  change; and when the urgency is great they may require to drive out in
+  turn weaker people who occupy a desirable territory, thus propagating
+  the wave of migration, the direction of which is guided by the forms
+  of the land into inevitable channels. Many of the great historic
+  movements of peoples were doubtless due to the gradual change of
+  geographical or climatic conditions; and the slow desiccation of
+  Central Asia has been plausibly suggested as the real cause of the
+  peopling of modern Europe and of the medieval wars of the Old World,
+  the theatres of which were critical points on the great natural lines
+  of communication between east and west.
+
+  In the case of centripetal migrations people flock to some particular
+  place where exceptionally favourable conditions have been found to
+  exist. The rushes to gold-fields and diamond-fields are typical
+  instances; the growth of towns on coal-fields and near other sources
+  of power, and the rapid settlement of such rich agricultural districts
+  as the wheat-lands of the American prairies and great plains are other
+  examples.
+
+  There is, however, a tendency for people to remain rooted to the land
+  of their birth, when not compelled or induced by powerful external
+  causes to seek a new home.
+
+
+    Political geography.
+
+  Thus arises the spirit of patriotism, a product of purely geographical
+  conditions, thereby differing from the sentiment of loyalty, which is
+  of racial origin. Where race and soil conspire to evoke both loyalty
+  and patriotism in a people, the moral qualities of a great and
+  permanent nation are secured. It is noticeable that the patriotic
+  spirit is strongest in those places where people are brought most
+  intimately into relation with the land; dwellers in the mountain or by
+  the sea, and, above all, the people of rugged coasts and mountainous
+  archipelagoes, have always been renowned for love of country, while
+  the inhabitants of fertile plains and trading communities are
+  frequently less strongly attached to their own land.
+
+  Amongst nomads the tribe is the unit of government, the political bond
+  is personal, and there is no definite territorial association of the
+  people, who may be loyal but cannot be patriotic. The idea of a
+  country arises only when a nation, either homogeneous or composed of
+  several races, establishes itself in a region the boundaries of which
+  may be defined and defended against aggression from without. Political
+  geography takes account of the partition of the earth amongst
+  organized communities, dealing with the relation of races to regions,
+  and of nations to countries, and considering the conditions of
+  territorial equilibrium and instability.
+
+
+    Boundaries.
+
+  The definition of boundaries and their delimitation is one of the most
+  important parts of political geography. Natural boundaries are always
+  the most definite and the strongest, lending themselves most readily
+  to defence against aggression. The sea is the most effective of all,
+  and an island state is recognized as the most stable. Next in
+  importance comes a mountain range, but here there is often difficulty
+  as to the definition of the actual crest-line, and mountain ranges
+  being broad regions, it may happen that a small independent state,
+  like Switzerland or Andorra, occupies the mountain valleys between two
+  or more great countries. Rivers do not form effective international
+  boundaries, although between dependent self-governing communities they
+  are convenient lines of demarcation. A desert, or a belt of country
+  left purposely without inhabitants, like the mark, marches or
+  debatable lands of the middle ages, was once a common means of
+  separating nations which nourished hereditary grievances. The
+  "buffer-state" of modern diplomacy is of the same ineffectual type. A
+  less definite though very practical boundary is that formed by the
+  meeting-line of two languages, or the districts inhabited by two
+  races. The line of fortresses protecting Austria from Italy lies in
+  some places well back from the political boundary, but just inside the
+  linguistic frontier, so as to separate the German and Italian races
+  occupying Austrian territory. Arbitrary lines, either traced from
+  point to point and marked by posts on the ground, or defined as
+  portions of meridians and parallels, are now the most common type of
+  boundaries fixed by treaty. In Europe and Asia frontiers are usually
+  strongly fortified and strictly watched in times of peace as well as
+  during war. In South America strictly defined boundaries are still the
+  exception, and the claims of neighbouring nations have very frequently
+  given rise to war, though now more commonly to arbitration.[51]
+
+
+    Forms of government.
+
+  The modes of government amongst civilized peoples have little
+  influence on political geography; some republics are as arbitrary and
+  exacting in their frontier regulations as some absolute monarchies. It
+  is, however, to be noticed that absolute monarchies are confined to
+  the east of Europe and to Asia, Japan being the only established
+  constitutional monarchy east of the Carpathians. Limited monarchies
+  are (with the exception of Japan) peculiar to Europe, and in these the
+  degree of democratic control may be said to diminish as one passes
+  eastwards from the United Kingdom. Republics, although represented in
+  Europe, are the peculiar form of government of America and are unknown
+  in Asia.
+
+  The forms of government of colonies present a series of transitional
+  types from the autocratic administration of a governor appointed by
+  the home government to complete democratic self-government. The latter
+  occurs only in the temperate possessions of the British empire, in
+  which there is no great preponderance of a coloured native population.
+  New colonial forms have been developed during the partition of Africa
+  amongst European powers, the sphere of influence being especially
+  worthy of notice. This is a vaguer form of control than a
+  protectorate, and frequently amounts merely to an agreement amongst
+  civilized powers to respect the right of one of their number to
+  exercise government within a certain area, if it should decide to do
+  so at any future time.
+
+  The central governments of all civilized countries concerned with
+  external relations are closely similar in their modes of action, but
+  the internal administration may be very varied. In this respect a
+  country is either centralized, like the United Kingdom or France, or
+  federated of distinct self-governing units like Germany (where the
+  units include kingdoms, at least three minor types of monarchies,
+  municipalities and a crown land under a nominated governor), or the
+  United States, where the units are democratic republics. The ultimate
+  cause of the predominant form of federal government may be the
+  geographical diversity of the country, as in the cantons occupying the
+  once isolated mountain valleys of Switzerland, the racial diversity of
+  the people, as in Austria-Hungary, or merely political expediency, as
+  in republics of the American type.
+
+  The minor subdivisions into provinces, counties and parishes, or
+  analogous areas, may also be related in many cases to natural features
+  or racial differences perpetuated by historical causes. The
+  territorial divisions and subdivisions often survive the conditions
+  which led to their origin; hence the study of political geography is
+  allied to history as closely as the study of physical geography is
+  allied to geology, and for the same reason.
+
+
+    Towns.
+
+  The aggregation of population in towns was at one time mainly brought
+  about by the necessity for defence, a fact indicated by the defensive
+  sites of many old towns. In later times, towns have been more often
+  founded in proximity to valuable mineral resources, and at critical
+  points or nodes on lines of communication. These are places where the
+  mode of travelling or of transport is changed, such as seaports, river
+  ports and railway termini, or natural resting-places, such as a ford,
+  the foot of a steep ascent on a road, the entrance of a valley leading
+  up from a plain into the mountains, or a crossing-place of roads or
+  railways.[52] The existence of a good natural harbour is often
+  sufficient to give origin to a town and to fix one end of a line of
+  land communication.
+
+
+    Lines of communication.
+
+  In countries of uniform surface or faint relief, roads and railways
+  may be constructed in any direction without regard to the
+  configuration. In places where the low ground is marshy, roads and
+  railways often follow the ridge-lines of hills, or, as in Finland, the
+  old glacial eskers, which run parallel to the shore. Wherever the
+  relief of the land is pronounced, roads and railways are obliged to
+  occupy the lowest ground winding along the valleys of rivers and
+  through passes in the mountains. In exceptional cases obstructions
+  which it would be impossible or too costly to turn are overcome by a
+  bridge or tunnel, the magnitude of such works increasing with the
+  growth of engineering skill and financial enterprise. Similarly the
+  obstructions offered to water communication by interruption through
+  land or shallows are overcome by cutting canals or dredging out
+  channels. The economy and success of most lines of communication
+  depend on following as far as possible existing natural lines and
+  utilizing existing natural sources of power.[53]
+
+
+    Commercial geography.
+
+  Commercial geography may be defined as the description of the earth's
+  surface with special reference to the discovery, production, transport
+  and exchange of commodities. The transport concerns land routes and
+  sea routes, the latter being the more important. While steam has been
+  said to make a ship independent of wind and tide, it is still true
+  that a long voyage even by steam must be planned so as to encounter
+  the least resistance possible from prevailing winds and permanent
+  currents, and this involves the application of oceanographical and
+  meteorological knowledge. The older navigation by utilizing the power
+  of the wind demands a very intimate knowledge of these conditions, and
+  it is probable that a revival of sailing ships may in the present
+  century vastly increase the importance of the study of maritime
+  meteorology.
+
+  The discovery and production of commodities require a knowledge of the
+  distribution of geological formations for mineral products, of the
+  natural distribution, life-conditions and cultivation or breeding of
+  plants and animals and of the labour market. Attention must also be
+  paid to the artificial restrictions of political geography, to the
+  legislative restrictions bearing on labour and trade as imposed in
+  different countries, and, above all, to the incessant fluctuations of
+  the economic conditions of supply and demand and the combinations of
+  capitalists or workers which affect the market.[54] The term "applied
+  geography" has been employed to designate commercial geography, the
+  fact being that every aspect of scientific geography may be applied to
+  practical purposes, including the purposes of trade. But apart from
+  the applied science, there is an aspect of pure geography which
+  concerns the theory of the relation of economics to the surface of the
+  earth.
+
+
+    Conclusion.
+
+  It will be seen that as each successive aspect of geographical science
+  is considered in its natural sequence the conditions become more
+  numerous, complex, variable and practically important. From the
+  underlying abstract mathematical considerations all through the
+  superimposed physical, biological, anthropological, political and
+  commercial development of the subject runs the determining control
+  exercised by crust-forms acting directly or indirectly on mobile
+  distributions; and this is the essential principle of geography.
+       (H. R. M.)
+
+
+FOOTNOTES:
+
+  [1] A concise sketch of the whole history of geographical method or
+    theory as distinguished from the history of geographical discovery
+    (see later section of this article) is only to be found in the
+    introduction to H. Wagner's _Lehrbuch der Geographie_, vol. i.
+    (Leipzig, 1900), which is in every way the most complete treatise on
+    the principles of geography.
+
+  [2] _History of Ancient Geography_ (Cambridge, 1897), p. 70.
+
+  [3] See J.L. Myres, "An Attempt to reconstruct the Maps used by
+    Herodotus," _Geographical Journal_, viii. (1896), p. 605.
+
+  [4] _Geschichte der wissenschaftlichen Erdkunde der Griechen_
+    (Leipzig, 1891), Abt. 3, p. 60.
+
+  [5] Bunbury's _History of Ancient Geography_ (2 vols., London, 1879),
+    Muller's _Geographi Graeci minores_ (2 vols., Paris, 1855, 1861) and
+    Berger's _Geschichte der wissenschaftlichen Erdkunde der Griechen_ (4
+    vols., Leipzig, 1887-1893) are standard authorities on the Greek
+    geographers.
+
+  [6] The period of the early middle ages is dealt with in Beazley's
+    _Dawn of Modern Geography_ (London; part i., 1897; part ii., 1901;
+    part iii., 1906); see also Winstedt, _Cosmos Indicopleustes_ (1910).
+
+  [7] From translator's preface to the English version by Mr Dugdale
+    (1733), entitled _A Complete System of General Geography_, revised by
+    Dr Peter Shaw (London, 1756).
+
+  [8] Printed in _Schriften zur physischen Geographie_, vol. vi. of
+    Schubert's edition of the collected works of Kant (Leipzig, 1839).
+    First published with notes by Rink in 1802.
+
+  [9] _History of Civilization_, vol. i. (1857).
+
+  [10] See H.J. Mackinder in _British Association Report_ (Ipswich),
+    1895, p. 738, for a summary of German opinion, which has been
+    expressed by many writers in a somewhat voluminous literature.
+
+  [11] H. Wagner's year-book, _Geographische Jahrbuch_, published at
+    Gotha, is the best systematic record of the progress of geography in
+    all departments; and Haack's _Geographen Kalender_, also published
+    annually at Gotha, gives complete lists of the geographical societies
+    and geographers of the world.
+
+  [12] This phrase is old, appearing in one of the earliest English
+    works on geography, William Cuningham's _Cosmographical Glasse
+    conteinyng the pleasant Principles of Cosmographie, Geographie,
+    Hydrographie or Navigation_ (London, 1559).
+
+  [13] See also S. Gunther, _Handbuch der mathematischen Geographie_
+    (Stuttgart, 1890).
+
+  [14] "On the Height of the Land and the Depth of the Ocean," _Scot.
+    Geog. Mag._ iv. (1888), p. 1. Estimates had been made previously by
+    Humboldt, De Lapparent, H. Wagner, and subsequently by Penck and
+    Heiderich, and for the oceans by Karstens.
+
+  [15] _Petermanns Mitteilungen_, xxv. (1889), p. 17.
+
+  [16] _Proc. Roy. Soc. Edin._ xvii. (1890) p. 185.
+
+  [17] _Comptes rendus Acad. Sci._ (Paris, 1890), vol. iii. p. 994.
+
+  [18] "Areal und mittlere Erhebung der Landflachen sowie der
+    Erdkruste" in Gerland's _Beitrage zur Geophysik_, ii. (1895) p. 667.
+    See also _Nature_, 54 (1896), p. 112.
+
+  [19] _Petermanns Mitteilungen_, xxxv. (1889) p. 19.
+
+  [20] The areas of the continental shelf and lowlands are
+    approximately equal, and it is an interesting circumstance that,
+    taken as a whole, the actual coast-line comes just midway on the most
+    nearly level belt of the earth's surface, excepting the ocean floor.
+    The configuration of the continental slope has been treated in detail
+    by Nansen in _Scientific Results of Norwegian North Polar
+    Expedition_, vol. iv. (1904), where full references to the literature
+    of the subject will be found.
+
+  [21] _British Association Report_ (Edinburgh, 1892), p. 699.
+
+  [22] _Das Antlitz der Erde_ (4 vols., Leipzig, 1885, 1888, 1901).
+    Translated under the editorship of E. de Margerie, with much
+    additional matter, as _La Face de la terre_, vols. i. and ii. (Paris,
+    1897, 1900), and into English by Dr Hertha Sollas as _The Face of the
+    Earth_, vols. i. and ii. (Oxford, 1904, 1906).
+
+  [23] Elie de Beaumont, _Notice sur les systemes de montagnes_ (3
+    vols., Paris, 1852).
+
+  [24] _Vestiges of the Molten Globe_ (London, 1875).
+
+  [25] See J.W. Gregory, "The Plan of the Earth and its Causes," _Geog.
+    Journal_, xiii. (1899) p. 225; Lord Avebury, _ibid._ xv. (1900) p.
+    46; Marcel Bertrand, "Deformation tetraedrique de la terre et
+    deplacement du pole," _Comptes rendus Acad. Sci._ (Paris, 1900), vol.
+    cxxx. p. 449; and A. de Lapparent, _ibid._ p. 614.
+
+  [26] See A.E.H. Love, "Gravitational Stability of the Earth," _Phil.
+    Trans._ ser. A. vol. ccvii. (1907) p. 171.
+
+  [27] _Rumpf_, in German, the language in which this distinction was
+    first made.
+
+  [28] _Lehrbuch der Geographie_ (Hanover and Leipzig, 1900), Bd. i. S.
+    245, 249.
+
+  [29] See, for example, F.G. Hahn's _Insel-Studien_ (Leipzig, 1883).
+
+  [30] See _Geographical Journal_, xxii. (1903) pp. 191-194.
+
+  [31] The most important works on the classification of land forms are
+    F. von Richthofen, _Fuhrer fur Forschungsreisende_ (Berlin, 1886); G.
+    de la Noe and E. de Margerie, _Les Formes du terrain_ (Paris, 1888);
+    and above all A. Penck, _Morphologie der Erdoberflache_ (2 vols.,
+    Stuttgart, 1894). Compare also A. de Lapparent, _Lecons de geographie
+    physique_ (2nd ed., Paris, 1898), and W.M. Davis, _Physical
+    Geography_ (Boston, 1899).
+
+  [32] "Geomorphologie als genetische Wissenschaft," in _Report of
+    Sixth International Geog. Congress_ (London, 1895), p. 735 (English
+    Abstract, p. 748).
+
+  [33] On this subject see J. Geikie, _Earth Sculpture_ (London, 1898);
+    J.E. Marr, _The Scientific Study of Scenery_ (London, 1900); Sir A.
+    Geikie, _The Scenery and Geology of Scotland_ (London, 2nd ed.,
+    1887); Lord Avebury (Sir J. Lubbock), _The Scenery of Switzerland_
+    (London, 1896) and _The Scenery of England_ (London, 1902).
+
+  [34] Some geographers distinguish a mountain from a hill by origin;
+    thus Professor Seeley says "a mountain implies elevation and a hill
+    implies denudation, but the external forms of both are often
+    identical." _Report VI. Int. Geog. Congress_ (London, 1895), p. 751.
+
+  [35] "Mountains," in _Scot. Geog. Mag._ ii. (1896) p. 145.
+
+  [36] _Fuhrer fur Forschungsreisende_, pp. 652-685.
+
+  [37] See, for a summary of river-action, A. Phillipson, _Studien uber
+    Wasserscheiden_ (Leipzig, 1886); also I.C. Russell, _River
+    Development_, (London, 1898) (published as _The Rivers of North
+    America_, New York, 1898).
+
+  [38] W.M. Davis, "The Geographical Cycle," _Geog. Journ._ xiv. (1899)
+    p. 484.
+
+  [39] A. Penck, "Potamology as a Branch of Physical Geography," _Geog.
+    Journ._ x. (1897) p. 619.
+
+  [40] See, for instance, E. Wisotzki, _Hauptfluss und Nebenfluss_
+    (Stettin, 1889). For practical studies see official reports on the
+    Mississippi, Rhine, Seine, Elbe and other great rivers.
+
+  [41] F.A. Forel, _Handbuch der Seenkunde: allgemeine Limnologie_
+    (Stuttgart, 1901); F.A. Forel, "La Limnologie, branche de la
+    geographie," _Report VI. Int. Geog. Congress_ (London, 1895), p. 593;
+    also _Le Leman_ (2 vols., Lausanne, 1892, 1894); H. Lullies, "Studien
+    uber Seen," _Jubilaumsschrift der Albertus-Universitat_ (Konigsberg,
+    1894); and G.R. Credner, "Die Reliktenseen," _Petermanns
+    Mitteilungen_, Erganzungshefte 86 and 89 (Gotha., 1887, 1888).
+
+  [42] J. Murray, "Drainage Areas of the Continents," _Scot. Geog.
+    Mag._ ii. (1886) p. 548.
+
+  [43] Wagner, _Lehrbuch der Geographie_ (1900), i. 586.
+
+  [44] For details, see A.R. Wallace, _Geographical Distribution of
+    Animals and Island Life_; A. Heilprin, _Geographical and Geological
+    Distribution of Animals_ (1887); O. Drude, _Handbuch der
+    Pflanzengeographie_; A. Engler, _Entwickelungsgeschichte der
+    Pflanzenwelt_; also Beddard, _Zoogeography_ (Cambridge, 1895); and
+    Sclater, _The Geography of Mammals_ (London, 1899).
+
+  [45] See particularly A. de Lapparent, _Traite de geologie_ (4th ed.,
+    Paris, 1900).
+
+  [46] Estimate for 1900. H. Wagner, _Lehrbuch der Geographie_, i. P.
+    658.
+
+  [47] Estimate for year not stated. A.H. Keane in _International
+    Geography_, p. 108.
+
+  [48] In _Proc. R. G. S._ xiii. (1891) p. 27.
+
+  [49] On the influence of land on people see Shaler, _Nature and Man
+    in America_ (New York and London, 1892); and Ellen C. Semple's
+    _American History and its Geographic Conditions_ (Boston, 1903).
+
+  [50] See maps of density of population in Bartholomew's great
+    large-scale atlases, _Atlas of Scotland_ and _Atlas of England_.
+
+  [51] For the history of territorial changes in Europe, see Freeman,
+    _Historical Geography of Europe_, edited by Bury (Oxford), 1903; and
+    for the official definition of existing boundaries, see Hertslet,
+    _The Map of Europe by Treaty_ (4 vols., London, 1875, 1891); _The Map
+    of Africa by Treaty_ (3 vols., London, 1896). Also Lord Curzon's
+    Oxford address on _Frontiers_ (1907).
+
+  [52] For numerous special instances of the determining causes of town
+    sites, see G.G. Chisholm, "On the Distribution of Towns and Villages
+    in England," _Geographical Journal_ (1897), ix. 76, x. 511.
+
+  [53] The whole subject of anthropogeography is treated in a masterly
+    way by F. Ratzel in his _Anthropogeographie_ (Stuttgart, vol. i. 2nd
+    ed., 1899, vol. ii. 1891), and in his _Politische Geographie_
+    (Leipzig, 1897). The special question of the reaction of man on his
+    environment is handled by G.P. Marsh in _Man and Nature, or Physical
+    Geography as modified by Human Action_ (London, 1864).
+
+  [54] For commercial geography see G.G. Chisholm, _Manual of
+    Commercial Geography_ (1890).
+
+
+
+
+GEOID (from Gr. [Greek: ge], the earth), an imaginary surface employed
+by geodesists which has the property that every element of it is
+perpendicular to the plumb-line where that line cuts it. Compared with
+the "spheroid of reference" the surface of the geoid is in general
+depressed over the oceans and raised over the great land masses. (See
+EARTH, FIGURE OF THE.)
+
+
+
+
+GEOK-TEPE, a former fortress of the Turkomans, in Russian Transcaspia,
+in the oasis of Akhal-tekke, on the Transcaspian railway, 28 m. N.W. of
+Askabad. It consisted of a walled enclosure 1-3/4 m. in circuit, the
+wall being 18 ft. high and 20 to 30 ft. thick. In December 1880 the
+place was attacked by 6000 Russians under General Skobelev, and after a
+siege of twenty-three days was carried by storm, although the defenders
+numbered 25,000. A monument and a small museum commemorate the event.
+
+
+
+
+GEOLOGY (from Gr. [Greek: ge], the earth, and [Greek: logos], science),
+the science which investigates the physical history of the earth. Its
+object is to trace the structural progress of our planet from the
+earliest beginnings of its separate existence, through its various
+stages of growth, down to the present condition of things. It seeks to
+determine the manner in which the evolution of the earth's great surface
+features has been effected. It unravels the complicated processes by
+which each continent has been built up. It follows, even into detail,
+the varied sculpture of mountain and valley, crag and ravine. Nor does
+it confine itself merely to changes in the inorganic world. Geology
+shows that the present races of plants and animals are the descendants
+of other and very different races which once peopled the earth. It
+teaches that there has been a progressive development of the
+inhabitants, as well as one of the globe on which they have dwelt; that
+each successive period in the earth's history, since the introduction of
+living things, has been marked by characteristic types of the animal and
+vegetable kingdoms; and that, however imperfectly the remains of these
+organisms have been preserved or may be deciphered, materials exist for
+a history of life upon the planet. The geographical distribution of
+existing faunas and floras is often made clear and intelligible by
+geological evidence; and in the same way light is thrown upon some of
+the remoter phases in the history of man himself. A subject so
+comprehensive as this must require a wide and varied basis of evidence.
+It is one of the characteristics of geology to gather evidence from
+sources which at first sight seem far removed from its scope, and to
+seek aid from almost every other leading branch of science. Thus, in
+dealing with the earliest conditions of the planet, the geologist must
+fully avail himself of the labours of the astronomer. Whatever is
+ascertainable by telescope, spectroscope or chemical analysis, regarding
+the constitution of other heavenly bodies, has a geological bearing. The
+experiments of the physicist, undertaken to determine conditions of
+matter and of energy, may sometimes be taken as the starting-points of
+geological investigation. The work of the chemical laboratory forms the
+foundation of a vast and increasing mass of geological inquiry. To the
+botanist, the zoologist, even to the unscientific, if observant,
+traveller by land or sea, the geologist turns for information and
+assistance.
+
+But while thus culling freely from the dominions of other sciences,
+geology claims as its peculiar territory the rocky framework of the
+globe. In the materials composing that framework, their composition and
+arrangement, the processes of their formation, the changes which they
+have undergone, and the terrestrial revolutions to which they bear
+witness, lie the main data of geological history. It is the task of the
+geologist to group these elements in such a way that they may be made to
+yield up their evidence as to the march of events in the evolution of
+the planet. He finds that they have in large measure arranged themselves
+in chronological sequence,--the oldest lying at the bottom and the
+newest at the top. Relics of an ancient sea-floor are overlain by traces
+of a vanished land-surface; these are in turn covered by the deposits of
+a former lake, above which once more appear proofs of the return of the
+sea. Among these rocky records lie the lavas and ashes of long-extinct
+volcanoes. The ripple left upon the shore, the cracks formed by the
+sun's heat upon the muddy bottom of a dried-up pool, the very imprint of
+the drops of a passing rainshower, have all been accurately preserved,
+and yield their evidence as to geographical conditions often widely
+different from those which exist where such markings are now found.
+
+But it is mainly by the remains of plants and animals imbedded in the
+rocks that the geologist is guided in unravelling the chronological
+succession of geological changes. He has found that a certain order of
+appearance characterizes these organic remains, that each great group of
+rocks is marked by its own special types of life, and that these types
+can be recognized, and the rocks in which they occur can be correlated
+even in distant countries, and where no other means of comparison would
+be possible. At one moment he has to deal with the bones of some large
+mammal scattered through a deposit of superficial gravel, at another
+time with the minute foraminifers and ostracods of an upraised
+sea-bottom. Corals and crinoids crowded and crushed into a massive
+limestone where they lived and died, ferns and terrestrial plants matted
+together into a bed of coal where they originally grew, the scattered
+shells of a submarine sand-bank, the snails and lizards which lived and
+died within a hollow-tree, the insects which have been imprisoned within
+the exuding resin of old forests, the footprints of birds and
+quadrupeds, the trails of worms left upon former shores--these, and
+innumerable other pieces of evidence, enable the geologist to realize in
+some measure what the faunas and floras of successive periods have been,
+and what geographical changes the site of every land has undergone.
+
+It is evident that to deal successfully with these varied materials, a
+considerable acquaintance with different branches of science is needful.
+Especially necessary is a tolerably wide knowledge of the processes now
+at work in changing the surface of the earth, and of at least those
+forms of plant and animal life whose remains are apt to be preserved in
+geological deposits, or which in their structure and habitat enable us
+to realize what their forerunners were. It has often been insisted that
+the present is the key to the past; and in a wide sense this assertion
+is eminently true. Only in proportion as we understand the present,
+where everything is open on all sides to the fullest investigation, can
+we expect to decipher the past, where so much is obscure, imperfectly
+preserved or not preserved at all. A study of the existing economy of
+nature ought thus to be the foundation of the geologist's training.
+
+While, however, the present condition of things is thus employed, we
+must obviously be on our guard against the danger of unconsciously
+assuming that the phase of nature's operations which we now witness has
+been the same in all past time, that geological changes have always or
+generally taken place in former ages in the manner and on the scale
+which we behold to-day, and that at the present time all the great
+geological processes, which have produced changes in the past eras of
+the earth's history, are still existent and active. As a working
+hypothesis we may suppose that the nature of geological processes has
+remained constant from the beginning; but we cannot postulate that the
+action of these processes has never varied in energy. The few centuries
+wherein man has been observing nature obviously form much too brief an
+interval by which to measure the intensity of geological action in all
+past time. For aught we can tell the present is an era of quietude and
+slow change, compared with some of the eras which have preceded it. Nor
+perhaps can we be quite sure that, when we have explored every
+geological process now in progress, we have exhausted all the causes of
+change which, even in comparatively recent times, have been at work.
+
+In dealing with the geological record, as the accessible solid part of
+the globe is called, we cannot too vividly realize that at the best it
+forms but an imperfect chronicle. Geological history cannot be compiled
+from a full and continuous series of documents. From the very nature of
+its origin the record is necessarily fragmentary, and it has been
+further mutilated and obscured by the revolutions of successive ages.
+And even where the chronicle of events is continuous, it is of very
+unequal value in different places. In one case, for example, it may
+present us with an unbroken succession of deposits many thousands of
+feet in thickness, from which, however, only a few meagre facts as to
+geological history can be gleaned. In another instance it brings before
+us, within the compass of a few yards, the evidence of a most varied and
+complicated series of changes in physical geography, as well as an
+abundant and interesting suite of organic remains. These and other
+characteristics of the geological record become more apparent and
+intelligible as we proceed in the study of the science.
+
+_Classification._--For systematic treatment the subject may be
+conveniently arranged in the following parts:--
+
+1. _The Historical Development of Geological Science._--Here a brief
+outline will be given of the gradual growth of geological conceptions
+from the days of the Greeks and Romans down to modern times, tracing the
+separate progress of the more important branches of inquiry and noting
+some of the stages which in each case have led up to the present
+condition of the science.
+
+2. _The Cosmical Aspects of Geology._--This section embraces the
+evidence supplied by astronomy and physics regarding the form and
+motions of the earth, the composition of the planets and sun, and the
+probable history of the solar system. The subjects dealt with under this
+head are chiefly treated in separate articles.
+
+3. _Geognosy._--An inquiry into the materials of the earth's substance.
+This division, which deals with the parts of the earth, its envelopes of
+air and water, its solid crust and the probable condition of its
+interior, especially treats of the more important minerals of the crust,
+and the chief rocks of which that crust is built up. Geognosy thus lays
+a foundation of knowledge regarding the nature of the materials
+constituting the mass of the globe, and prepares the way for an
+investigation of the processes by which these materials are produced and
+altered.
+
+4. _Dynamical Geology_ studies the nature and working of the various
+geological processes whereby the rocks of the earth's crust are formed
+and metamorphosed, and by which changes are effected upon the
+distribution of sea and land, and upon the forms of terrestrial
+surfaces. Such an inquiry necessitates a careful examination of the
+existing geological economy of nature, and forms a fitting introduction
+to an inquiry into the geological changes of former periods.
+
+5. _Geotectonic or Structural Geology_ has for its object the
+architecture of the earth's crust. It embraces an inquiry into the
+manner in which the various materials composing this crust have been
+arranged. It shows that some have been formed in beds or strata of
+sediment on the floor of the sea, that others have been built up by the
+slow aggregation of organic forms, that others have been poured out in a
+molten condition or in showers of loose dust from subterranean sources.
+It further reveals that, though originally laid down in almost
+horizontal beds, the rocks have subsequently been crumpled, contorted
+and dislocated, that they have been incessantly worn down, and have
+often been depressed and buried beneath later accumulations.
+
+6. _Palaeontological Geology._--This branch of the subject, starting
+from the evidence supplied by the organic forms which are found
+preserved in the crust of the earth, includes such questions as the
+relations between extinct and living types, the laws which appear to
+have governed the distribution of life in time and in space, the
+relative importance of different genera of animals in geological
+inquiry, the nature and use of the evidence from organic remains
+regarding former conditions of physical geography. Some of these
+problems belong also to zoology and botany, and are more fully discussed
+in the articles PALAEONTOLOGY and PALAEOBOTANY.
+
+7. _Stratigraphical Geology._--This section might be called geological
+history. It works out the chronological succession of the great
+formations of the earth's crust, and endeavours to trace the sequence of
+events of which they contain the record. More particularly, it
+determines the order of succession of the various plants and animals
+which in past time have peopled the earth, and thus ascertains what has
+been the grand march of life upon this planet.
+
+8. _Physiographical Geology_, proceeding from the basis of fact laid
+down by stratigraphical geology regarding former geographical changes,
+embraces an inquiry into the origin and history of the features of the
+earth's surface--continental ridges and ocean basins, plains, valleys
+and mountains. It explains the causes on which local differences of
+scenery depend, and shows under what very different circumstances, and
+at what widely separated intervals, the hills and mountains, even of a
+single country, have been produced.
+
+Most of the detail embraced in these several sections is relegated to
+separate articles, to which references are here inserted. The following
+pages thus deal mainly with the general principles and historical
+development of the science:--
+
+
+  PART I.--HISTORICAL DEVELOPMENT
+
+  _Geological Ideas among the Greeks and Romans._--Many geological
+  phenomena present themselves in so striking a form that they could
+  hardly fail to impress the imagination of the earliest and rudest
+  races of mankind. Such incidents as earthquakes and volcanic
+  eruptions, destructive storms on land and sea, disastrous floods and
+  landslips suddenly strewing valleys with ruin, must have awakened the
+  terror of those who witnessed them. Prominent features of landscape,
+  such as mountain-chains with their snows, clouds and thunderstorms,
+  dark river-chasms that seem purposely cleft open in order to give
+  passage to the torrents that rush through them, crags with their
+  impressive array of pinnacles and recesses must have appealed of old,
+  as they still do, to the awe and wonder of those who for the first
+  time behold them. Again, banks of sea-shells in far inland districts
+  would, in course of time, arrest the attention of the more intelligent
+  and reflective observers, and raise in their minds some kind of
+  surmise as to how such shells could ever have come there. These and
+  other conspicuous geological problems found their earliest solution in
+  legends and myths, wherein the more striking terrestrial features and
+  the elemental forces of nature were represented to be the
+  manifestation of the power of unseen supernatural beings.
+
+  The basin of the Mediterranean Sea was especially well adapted, from
+  its physical conditions, to be the birth-place of such fables. It is a
+  region frequently shaken by earthquakes, and contains two distinct
+  centres of volcanic activity, one in the Aegean Sea and one in Italy.
+  It is bounded on the north by a long succession of lofty snow-capped
+  mountain-ranges, whence copious rivers, often swollen by heavy rains
+  or melted snows, carry the drainage into the sea. On the south it
+  boasts the Nile, once so full of mystery; likewise wide tracts of arid
+  desert with their dreaded dust storms. The Mediterranean itself,
+  though an inland sea, is subject to gales, which, on exposed coasts,
+  raise breakers quite large enough to give a vivid impression of the
+  power of ocean waves. The countries that surround this great sheet of
+  water display in many places widely-spread deposits full of sea
+  shells, like those that still live in the neighbouring bays and gulfs.
+  Such a region was not only well fitted to supply subjects for
+  mythology, but also to furnish, on every side, materials which, in
+  their interest and suggestiveness, would appeal to the reason of
+  observant men.
+
+  It was natural, therefore, that the early philosophers of Greece
+  should have noted some of these geological features, and should have
+  sought for other explanations of them than those to be found in the
+  popular myths. The opinions entertained in antiquity on these subjects
+  may be conveniently grouped under two heads: (1) Geological processes
+  now in operation, and (2) geological changes in the past.
+
+
+    Earthquakes and volcanoes.
+
+  1. _Contemporary Processes._--The geological processes of the present
+  time are partly at work underground and partly on the surface of the
+  earth. The former, from their frequently disastrous character,
+  received much attention from Greek and Roman authors. Aristotle, in
+  his _Meteorics_, cites the speculations of several of his predecessors
+  which he rejects in favour of his own opinion to the effect that
+  earthquakes are due to the generation of wind within the earth, under
+  the influence of the warmth of the sun and the internal heat. Wind,
+  being the lightest and most rapidly moving body, is the cause of
+  motion in other bodies, and fire, united with wind, becomes flame,
+  which is endowed with great rapidity of motion. Aristotle looked upon
+  earthquakes and volcanic eruptions as closely connected with each
+  other, the discharge of hot materials to the surface being the result
+  of a severe earthquake, when finally the wind rushes out with
+  violence, and sometimes buries the surrounding country under sparks
+  and cinders, as had happened at Lipari. These crude conceptions of
+  the nature of volcanic action, and the cause of earthquakes, continued
+  to prevail for many centuries. They are repeated by Lucretius, who,
+  however, following Anaximenes, includes as one of the causes of
+  earthquakes the fall of mountainous masses of rock undermined by time,
+  and the consequent propagation of gigantic tremors far and wide
+  through the earth. Strabo, having travelled through the volcanic
+  districts of Italy, was able to recognize that Vesuvius had once been
+  an active volcano, although no eruption had taken place from it within
+  human memory. He continued to hold the belief that volcanic energy
+  arose from the movement of subterranean wind. He believed that the
+  district around the Strait of Messina, which had formerly suffered
+  from destructive earthquakes, was seldom visited by them after the
+  volcanic vents of that region had been opened, so as to provide an
+  escape for the subterranean fire, wind, water and burning masses. He
+  cites in his _Geography_ a number of examples of widespread as well as
+  local sinkings of land, and alludes also to the uprise of the
+  sea-bottom. He likewise regards some islands as having been thrown up
+  by volcanic agency, and others as torn from the mainland by such
+  convulsions as earthquakes.
+
+  The most detailed account of earthquake phenomena which has come down
+  to us from antiquity is that of Seneca in his _Quaestiones Naturales_.
+  This philosopher had been much interested in the accounts given him by
+  survivors and witnesses of the earthquake which convulsed the district
+  of Naples in February A.D. 63. He distinguished several distinct
+  movements of the ground: 1st, the up and down motion (_succussio_);
+  2nd, the oscillatory motion (_inclinatio_); and probably a third, that
+  of trembling or vibration. While admitting that some earthquakes may
+  arise from the collapse of the walls of subterranean cavities, he
+  adhered to the old idea, held by the most numerous and important
+  previous writers, that these commotions are caused mainly by the
+  movements of wind imprisoned within the earth. As to the origin of
+  volcanic outbursts he supposed that the subterranean wind in
+  struggling for an outlet, and whirling through the chasms and
+  passages, meets with great store of sulphur and other combustible
+  substances, which by mere friction are set on fire. The elder Pliny
+  reiterates the commonly accepted opinion as to the efficacy of wind
+  underground. In discussing the phenomena of earthquakes he remarks
+  that towns with many culverts and houses with cellars suffer less than
+  others, and that at Naples those houses are most shaken which stand on
+  hard ground. It thus appears that with regard to subterranean
+  geological operations, no advance was made during the time of the
+  Greeks and Romans as to the theoretical explanation of these
+  phenomena; but a considerable body of facts was collected, especially
+  as to the effects of earthquakes and the occurrence of volcanic
+  eruptions.
+
+
+    Action of rivers.
+
+  The superficial processes of geology, being much less striking than
+  those of subterranean energy, naturally attracted less attention in
+  antiquity. The operations of rivers, however, which so intimately
+  affect a human population, were watched with more or less care.
+  Herodotus, struck by the amount of alluvial silt brought down annually
+  by the Nile and spread over the flat inundated land, inferred that
+  "Egypt is the gift of the river." Aristotle, in discussing some of the
+  features of rivers, displays considerable acquaintance with the
+  various drainage-systems on the north side of the Mediterranean basin.
+  He refers to the mountains as condensers of the atmospheric moisture,
+  and shows that the largest rivers rise among the loftiest high
+  grounds. He shows how sensibly the alluvial deposits carried down to
+  the sea increase the breadth of the land, and cites some parts of the
+  shores of the Black Sea, where, in sixty years, the rivers had brought
+  down such a quantity of material that the vessels then in use required
+  to be of much smaller draught than previously, the water shallowing so
+  much that the marshy ground would, in course of time, become dry land.
+  Strabo supplies further interesting information as to the work of
+  rivers in making their alluvial plains and in pushing their deltas
+  seaward. He remarks that these deltas are prevented from advancing
+  farther outward by the ebb and flow of the tides.
+
+
+    Occurrences of fossils.
+
+  2. _Past Processes._--The abundant well-preserved marine shells
+  exposed among the upraised Tertiary and post-Tertiary deposits in the
+  countries bordering the Mediterranean are not infrequently alluded to
+  in Greek and Latin literature. Xenophanes of Colophon (614 B.C.)
+  noticed the occurrence of shells and other marine productions inland
+  among the mountains, and inferred from them that the land had risen
+  out of the sea. A similar conclusion was drawn by Xanthus the Lydian
+  (464 B.C.) from shells like scallops and cockles, which were found far
+  from the sea in Armenia and Lower Phrygia. Herodotus, Eratosthenes,
+  Strato and Strabo noted the vast quantities of fossil shells in
+  different parts of Egypt, together with beds of salt, as evidence that
+  the sea had once spread over the country. But by far the most
+  philosophical opinions on the past mutations of the earth's surface
+  are those expressed by Aristotle in the treatise already cited.
+  Reviewing the evidence of these changes, he recognized that the sea
+  now covers tracts that were once dry land, and that land will one day
+  reappear where there is now sea. These alternations are to be regarded
+  as following each other in a certain order and periodicity. But they
+  are apt to escape our notice because they require successive periods
+  of time, which, compared with our brief existence, are of enormous
+  duration, and because they are brought about so imperceptibly that we
+  fail to detect them in progress. In a celebrated passage in his
+  _Metamorphoses_, Ovid puts into the mouth of the philosopher
+  Pythagoras an account of what was probably regarded as the Pythagorean
+  view of the subject in the Augustan age. It affirms the interchange of
+  land and sea, the erosion of valleys by descending rivers, the washing
+  down of mountains into the sea, the disappearance of the rivers and
+  the submergence of land by earthquake movements, the separation of
+  some islands from, and the union of others with, the mainland, the
+  uprise of hills by volcanic action, the rise and extinction of burning
+  mountains. There was a time before Etna began to glow, and the time is
+  coming when the mountain will cease to burn.
+
+  From this brief sketch it will be seen that while the ancients had
+  accumulated a good deal of information regarding the occurrence of
+  geological changes, their interpretations of the phenomena were to a
+  considerable extent mere fanciful speculation. They had acquired only
+  a most imperfect conception of the nature and operation of the
+  geological processes; and though many writers realized that the
+  surface of the earth has not always been, and will not always remain,
+  as it is now, they had no glimpse of the vast succession of changes of
+  that surface which have been revealed by geology. They built
+  hypotheses on the slenderest basis of fact, and did not realize the
+  necessity of testing or verifying them.
+
+  _Progress of Geological Conceptions in the Middle Ages._--During the
+  centuries that succeeded the fall of the Western empire little
+  progress was made in natural science. The schoolmen in the monasteries
+  and other seminaries were content to take their science from the
+  literature of Greece and Rome. The Arabs, however, not only collected
+  and translated that literature, but in some departments made original
+  observations themselves. To one of the most illustrious of their
+  number, Avicenna, the translator of Aristotle, a treatise has been
+  ascribed, in which singularly modern ideas are expressed regarding
+  mountains, some of which are there stated to have been produced by an
+  uplifting of the ground, while others have been left prominent, owing
+  to the wearing away of the softer rocks around them. In either case,
+  it is confessed that the process would demand long tracts of time for
+  its completion.
+
+  After the revival of learning the ancient problem presented by fossil
+  shells imbedded in the rocks of the interior of many countries
+  received renewed attention. But the conditions for its solution were
+  no longer what they had been in the days of the philosophers of
+  antiquity. Men were not now free to adopt and teach any doctrine they
+  pleased on the subject. The Christian church had meanwhile arisen to
+  power all over Europe, and adjudged as heretics all who ventured to
+  impugn any of her dogmas. She taught that the land and the sea had
+  been separated on the third day of creation, before the appearance of
+  any animal life, which was not created until the fifth day. To assert
+  that the dry land is made up in great part of rocks that were formed
+  in the sea, and are crowded with the remains of animals, was plainly
+  to impugn the veracity of the Bible. Again, it had come to be the
+  orthodox belief that only somewhere about 6000 years had elapsed since
+  the time of Adam and Eve. If any thoughtful observer, impressed with
+  the overwhelming force of the evidence that the fossiliferous
+  formations of the earth's crust must have taken long periods of time
+  for their accumulation, ventured to give public expression to his
+  conviction, he ran considerable risk of being proceeded against as a
+  heretic. It was needful, therefore, to find some explanation of the
+  facts of nature, which would not run counter to the ecclesiastical
+  system of the day. Various such interpretations were proposed,
+  doubtless in an honest endeavour at reconciliation. Three of these
+  deserve special notice: (1) Many able observers and diligent
+  collectors of fossils persuaded themselves that these objects never
+  belonged to organisms of any kind, but should be regarded as mere
+  "freaks of nature," having no more connexion with any once living
+  creature than the frost patterns on a window. They were styled
+  "formed" or "figured" stones, "lapides sui generis," and were asserted
+  to be due to some inorganic imitative process within the earth or to
+  the influence of the stars. (2) Observers who could not resist the
+  evidence of their senses that the fossil shells once belonged to
+  living animals, and who, at the same time, felt the necessity of
+  accounting for the presence of marine organisms in the rocks of which
+  the dry land is largely built up, sought a way out of the difficulty
+  by invoking the Deluge of Noah. Here was a catastrophe which, they
+  said, extended over the whole globe, and by which the entire dry land
+  was submerged even up to the tops of the high hills. True, it only
+  lasted one hundred and fifty days, but so little were the facts then
+  appreciated that no difficulty seems to have been generally felt in
+  crowding the accumulation of the thousands of feet of fossiliferous
+  formations into that brief space of time. (3) Some more intelligent
+  men in Italy, recognizing that these interpretations could not be
+  upheld, fell back upon the idea that the rocks in which fossil shells
+  are imbedded might have been heaped up by repeated and vigorous
+  eruptions from volcanic centres. Certain modern eruptions in the
+  Aegean Sea and in the Bay of Naples had drawn attention to the
+  rapidity with which hills of considerable size could be piled around
+  an active crater. It was argued that if Monte Nuovo near Naples could
+  have been accumulated to a height of nearly 500 ft. in two days, there
+  seemed to be no reason against believing that, during the time of the
+  Flood, and in the course of the centuries that have elapsed since
+  that event, the whole of the fossiliferous rocks might have been
+  deposited. Unfortunately for this hypothesis it ignored the fact that
+  these rocks do not consist of volcanic materials.
+
+
+    Leonardo da Vinci; Fracastorio; Falloppio.
+
+  So long as the fundamental question remained in dispute as to the true
+  character and history of the stratified portion of the earth's crust
+  containing organic remains, geology as a science could not begin its
+  existence. The diluvialists (those who relied on the hypothesis of the
+  Flood) held the field during the 16th, 17th and a great part of the
+  18th century. They were looked on as the champions of orthodoxy; and,
+  on that account, they doubtless wielded much more influence than would
+  have been gained by them from the force of their arguments. Yet during
+  those ages there were not wanting occasional observers who did good
+  service in combating the prevalent misconceptions, and in preparing
+  the way for the ultimate triumph of truth. It was more especially in
+  Italy, where many of the more striking phenomena of geology are
+  conspicuously displayed, that the early pioneers of the science arose,
+  and that for several generations the most marked progress was made
+  towards placing the investigations of the past history of the earth
+  upon a basis of careful observation and scientific deduction. One of
+  the first of these leaders was Leonardo da Vinci (1452-1519), who,
+  besides his achievements in painting, sculpture, architecture and
+  engineering, contributed some notable observations regarding the great
+  problem of the origin of fossil shells. He ridiculed the notion that
+  these objects could have been formed by the influence of the stars,
+  and maintained that they had once belonged to living organisms, and
+  therefore that what is now land was formerly covered by the sea.
+  Girolamo Fracastorio (1483-1553) claimed that the shells could never
+  have been left by the Flood, which was a mere temporary inundation,
+  but that they proved the mountains, in which they occur, to have been
+  successively uplifted out of the sea. On the other hand, even an
+  accomplished anatomist like Gabriello Falloppio (1523-1562) found it
+  easier to believe that the bones of elephants, teeth of sharks, shells
+  and other fossils were mere earthy inorganic concretions, than that
+  the waters of Noah's Flood could ever nave reached as far as Italy.
+
+
+    Nicolas Steno.
+
+  By much the most important member of this early band of Italian
+  writers was undoubtedly Nicolas Steno (1631-1687), who, though born in
+  Copenhagen, ultimately settled in Florence. Having made a European
+  reputation as an anatomist, his attention was drawn to geological
+  problems by finding that the rocks of the north of Italy contained
+  what appeared to be sharks' teeth closely resembling those of a
+  dog-fish, of which he had published the anatomy. Cautiously at first,
+  for fear of offending orthodox opinions, but afterwards more boldly,
+  he proclaimed his conviction that those objects had once been part of
+  living animals, and that they threw light on some of the past history
+  of the earth. He published in 1669 a small tract, _De solido intra
+  solidum naturaliter contento_, in which he developed the ideas he had
+  formed of this history from an attentive study of the rocks. He showed
+  that the stratified formations of the hills and valleys consist of
+  such materials as would be laid down in the form of sediment in turbid
+  water; that where they contain marine productions this water is proved
+  to have been the sea; that diversities in their composition point to
+  commingling of currents, carrying different kinds of sediment of which
+  the heaviest would first sink to the bottom. He made original and
+  important observations on stratification, and laid down some of the
+  fundamental axioms in stratigraphy. He reasoned that as the original
+  position of strata was approximately horizontal, when they are found
+  to be steeply inclined or vertical, or bent into arches, they have
+  been disrupted by subterranean exhalations, or by the falling in of
+  the roofs of underground cavernous spaces. It is to this alteration of
+  the original position of the strata that the inequalities of the
+  earth's surface, such as mountains, are to be ascribed, though some
+  have been formed by the outburst of fire, ashes and stones from inside
+  the earth. Another effect of the dislocation has been to provide
+  fissures, which serve as outlets for springs. Steno's anatomical
+  training peculiarly fitted him for dealing authoritatively with the
+  question of the nature and origin of the fossils contained in the
+  rocks. He had no hesitation in affirming that, even if no shells had
+  ever been found living in the sea, the internal structure of these
+  fossils would demonstrate that they once formed parts of living
+  animals. And not only shells, but teeth, bones and skeletons of many
+  kinds of fishes had been quarried out of the rocks, while some of the
+  strata had skulls, horns and teeth of land-animals. Illustrating his
+  general principles by a sketch of what he supposed to have been the
+  past history of Tuscany, he added a series of diagrams which show how
+  clearly he had conceived the essential elements of stratigraphy. He
+  thought he could perceive the records of six successive phases in the
+  evolution of the framework of that country, and was inclined to
+  believe that a similar chronological sequence would be found all over
+  the world. He anticipated the objections that would be brought against
+  his views on account of the insuperable difficulty in granting the
+  length of time that would be required for all the geographical
+  vicissitudes which his interpretation required. He thought that many
+  of the fossils must be as old as the time of the general deluge, but
+  he was careful not to indulge in any speculation as to the antiquity
+  of the earth.
+
+
+    Lazzaro Moro.
+
+  To the Italian school, as especially typified in Steno, must be
+  assigned the honour of having thus begun to lay firmly and truly the
+  first foundation stones of the modern science of geology. The same
+  school included Antonio Vallisneri (1661-1730), who surpassed his
+  predecessors in his wider and more exact knowledge of the
+  fossiliferous rocks that form the backbone of the Italian peninsula,
+  which he contended were formed during a wide and prolonged submergence
+  of the region, altogether different from the brief deluge of Noah.
+  There was likewise Lazzaro Moro (1687-1740), who did good service
+  against the diluvialists, but the fundamental feature of his system of
+  nature lay in the preponderant part which, unaware of the great
+  difference between volcanic materials and ordinary sediment, he
+  assigned to volcanic action in the production of the sedimentary rocks
+  of the earth's crust. He supposed that in the beginning the globe was
+  completely surrounded with water, beneath which the solid earth lay as
+  a smooth ball. On the third day of creation, however, vast fires were
+  kindled inside the globe, whereby the smooth surface of stone was
+  broken up, and portions of it, appearing above the water, formed the
+  earliest land. From that time onward, volcanic eruptions succeeded
+  each other, not only on the emerged land, but on the sea-floor, over
+  which the ejected material spread in an ever augmenting thickness of
+  sedimentary strata. In this way Moro carried the history of the
+  stratified rocks beyond the time of the Flood back to the Creation,
+  which was supposed to have been some 1600 years earlier; and he
+  brought it down to the present day, when fresh sedimentary deposits
+  are continually accumulating. He thus incurred no censure from the
+  ecclesiastical guardians of the faith, and he succeeded in attracting
+  increased public attention to the problems of geology. The influence
+  of his teaching, however, was subsequently in great part due to the
+  Carmelite friar Generelli, who published an eloquent exposition of
+  Moro's views.
+
+  _The Cosmogonists and Theories of the Earth._--While in Italy
+  substantial progress was made in collecting information regarding the
+  fossiliferous formations of that country, and in forming conclusions
+  concerning them based upon more or less accurate observations, the
+  tendency to mere fanciful speculation, which could not be wholly
+  repressed in any country, reached a remarkable extravagance in
+  England. In proportion as materials were yet lacking from which to
+  construct a history of the evolution of our planet in accordance with
+  the teaching of the church, imagination supplied the place of
+  ascertained fact, and there appeared during the last twenty years of
+  the 18th century a group of English cosmogonists, who, by the
+  sensational character of their speculations, aroused general attention
+  both in Britain and on the continent. It may be doubted, however,
+  whether the effect of their writings was not to hinder the advance of
+  true science by diverting men from the observation of nature into
+  barren controversy over unrealities. It is not needful here to do more
+  than mention the names of Thomas Burnet, whose _Sacred Theory of the
+  Earth_ appeared in 1681, and William Whiston, whose New Theory of the
+  Earth was published in 1696. Hardly less fanciful than these writers,
+  though his practical acquaintance with rocks and fossils was
+  infinitely greater, was John Woodward, whose _Essay towards a Natural
+  History of the Earth_ dates from 1695. More important as a
+  contribution to science was the catalogue of the large collection of
+  fossils, which he had made from the rocks of England and which he
+  bequeathed to the university of Cambridge. This catalogue appeared in
+  1728-1729 with the title of _An attempt towards a Natural History of
+  the Fossils of England_.
+
+
+    Descartes.
+
+  A striking contrast to these cosmogonists is furnished by another
+  group, which arose in France and Germany, and gave to the world the
+  first rational ideas concerning the probable primeval evolution of our
+  globe. The earliest of these pioneers was the illustrious philosopher
+  Rene Descartes (1596-1650). He propounded a scheme of cosmical
+  development in which he represented the earth, like the other planets,
+  to have been originally a mass of glowing material like the sun, and
+  to have gradually cooled on the outside, while still retaining an
+  incandescent, self-luminous nucleus. Yet with this noble conception,
+  which modern science has accepted, Descartes could not shake himself
+  free from the time-honoured error in regard to the origin of volcanic
+  action. He thought that certain exhalations within the earth condense
+  into oil, which, when in violent motion, enters into the subterranean
+  cavities, where it passes into a kind of smoke. This smoke is from
+  time to time ignited by a spark of fire and, pressing violently
+  against its containing walls, gives rise to earthquakes. If the flame
+  breaks through to the surface at the top of a mountain, it may escape
+  with enormous energy, hurling forth much earth mingled with sulphur or
+  bitumen, and thus producing a volcano. The mountain might burn for a
+  long time until at last its store of fuel in the shape of sulphur or
+  bitumen would be exhausted. Not only did the philosopher refrain from
+  availing himself of the high internal temperature of the globe as the
+  source of volcanic energy, he even did not make use of it as the cause
+  of the ignition of his supposed internal fuel, but speculated on the
+  kindling of the subterranean fires by the spirits or gases setting
+  fire to the exhalations, or by the fall of masses of rock and the
+  sparks produced by their friction or percussion.
+
+
+    Leibnitz.
+
+  The ideas of Descartes regarding planetary evolution were enlarged and
+  made more definite by Wilhelm Gottfried Leibnitz (1646-1716), whose
+  teaching has largely influenced all subsequent speculation on the
+  subject. In his great tract, the _Protogaea_ (published in 1749,
+  thirty-three years after his death), he traced the probable passage of
+  our earth from an original condition of incandescent vapour into that
+  of a smooth molten globe, which, by continuous cooling, acquired an
+  external solid crust and rugose surface. He thought that the more
+  ancient rocks, such as granite and gneiss, might be portions of the
+  earliest outer crust; and that as the external solidification
+  advanced, immense subterranean cavities were left which were filled
+  with air and water. By the collapse of the roofs of these caverns,
+  valleys might be originated at the surface, while the solid
+  intervening walls would remain in place and form mountains. By the
+  disruption of the crust, enormous bodies of water were launched over
+  the surface of the earth, which swept vast quantities of sediment
+  together, and thus gave rise to sedimentary deposits. After many
+  vicissitudes of this kind, the terrestrial forces calmed down, and a
+  more stable condition of things was established.
+
+  An important feature in the cosmogony of Leibnitz is the prominent
+  place which he assigned to organic remains in the stratified rocks of
+  the crust. Ridiculing the foolish attempts to account for the presence
+  of these objects by calling them "sports of nature," he showed that
+  they are to be regarded as historical monuments; and he adduced a
+  number of instances wherein successive platforms of strata, containing
+  organic remains, bear witness to a series of advances and retreats of
+  the sea. He recognized that some of the fossils appeared to have
+  nothing like them in the living world of to-day, but some analogous
+  forms might yet be found, he thought, in still unexplored parts of the
+  earth; and even if no living representatives should ever be
+  discovered, many types of animals might have undergone transformation
+  during the great changes which had affected the surface of the earth.
+  In spite of his clear realization of the vast store of potential
+  energy residing within the highly heated interior of the earth,
+  Leibnitz continued to regard volcanic action as due to the combustion
+  of inflammable substances enclosed within the terrestrial crust, such
+  as stone-coal, naphtha and sulphur.
+
+
+    Buffon.
+
+  Appealing to a much wider public than Descartes or Leibnitz, and
+  basing his speculations on a wider acquaintance with the organic and
+  inorganic realms of nature, G.L.L. de Buffon (1707-1788) was
+  undoubtedly one of the most influential forces that in Europe guided
+  the growth of geological ideas during the 18th century. He published
+  in 1749 a _Theory of the Earth_, in which he adopted views similar to
+  those of Descartes and Leibnitz as to planetary evolution; but though
+  he realized the importance of fossils as records of former conditions
+  of the earth's surface, he accounted for them by supposing that they
+  had been deposited from a universal ocean, a large part of which had
+  subsequently been engulfed into caverns in the interior of the globe.
+  Thirty years later, after having laboured with skill and enthusiasm in
+  all branches of natural history, he published another work, his famous
+  _Epoques de la nature_ (1778), which is specially remarkable as the
+  first attempt to deal with the history of the earth in a chronological
+  manner, and to compute, on a basis of experiment, the antiquity of the
+  several stages of this history. His experiments were made with globes
+  of cast iron, and could not have yielded results of any value for his
+  purpose; but in so far as his calculations were not mere random
+  guesses but had some kind of foundation on experiment, they deserve
+  respectful recognition. He divided the history of our earth into six
+  periods of unequal duration, the whole comprising a period of some
+  70,000 or 75,000 years. He supposed that the stage of incandescence,
+  before the globe had consolidated to the centre, lasted 2936 years,
+  and that about 35,000 years elapsed before the surface had cooled
+  sufficiently to be touched, and therefore to be capable of supporting
+  living things. Terrestrial animal life, however, was not introduced
+  until 55,000 or 60,000 years after the beginning of the world or about
+  15,000 years before our time. Looking into the future, he foresaw
+  that, by continued refrigeration, our globe will eventually become
+  colder than ice, and this fair face of nature, with its manifold
+  varieties of plant and animal life, will perish after having existed
+  for 132,000 years.
+
+  Buffon's conception of the operation of the geological agents did not
+  become broader or more accurate in the interval between the appearance
+  of his two treatises. He still continued to believe in the lowering of
+  the ocean by subsidence into vast subterranean cavities, with a
+  consequent emergence of land. He still looked on volcanoes as due to
+  the burning of "pyritous and combustible stones," though he now called
+  in the co-operation of electricity. He calculated that the first
+  volcanoes could not arise until some 50,000 years after the beginning
+  of the world, by which time a sufficient extent of dense vegetation
+  had been buried in the earth to supply them with fuel. He appears to
+  have had but an imperfect acquaintance with the literature of his own
+  time. At least there can be little doubt that had he availed himself
+  of the labours of his own countryman, Jean Etienne Guettard
+  (1715-1786), of Giovanni Arduino (1714-1795) in Italy, and of Johann
+  Gottlob Lehmann (d. 1767) and George Christian Fuchsel (1722-1773) in
+  Germany, he would have been able to give to his "epochs" a more
+  definite succession of events and a greater correspondence with the
+  facts of nature.
+
+
+    James Hutton.
+
+  Among the writers of the 18th century, who formed philosophical
+  conceptions of the system of processes by which the life of our earth
+  as a habitable globe is carried on, a foremost place must be assigned
+  to James Hutton (1726-1797). Educated for the medical profession, he
+  studied at Edinburgh and at Paris, and took his doctor's degree at
+  Leiden. But having inherited a small landed property in Berwickshire,
+  he took to agriculture, and after putting his land into excellent
+  order, let his farm and betook himself to Edinburgh, there to gratify
+  the scientific tastes which he had developed early in life. He had
+  been more especially led to study minerals and rocks, and to meditate
+  on the problems which they suggest as to the constitution and history
+  of the earth. His journeys in Britain and on the continent of Europe
+  had furnished him with material for reflection; and he had gradually
+  evolved a system or theory in which all the scattered facts could be
+  arranged so as to show their mutual dependence and their place in the
+  orderly mechanism of the world. He used to discuss his views with one
+  or two of his friends, but refrained from publishing them to the world
+  until, on the foundation of the Royal Society of Edinburgh, he
+  communicated an outline of his doctrine to that learned body in 1785.
+  Some years later he expanded this first essay into a larger work in
+  two volumes, which were published in 1795 with the title of _Theory of
+  the Earth, with Proofs and Illustrations_.
+
+
+    John Playfair.
+
+  Hutton's teaching has exercised a profound influence on modern
+  geology. This influence, however, has arisen less from his own
+  writings than from the account of his doctrines given by his friend
+  John Playfair in the classic work entitled _Illustrations of the
+  Huttonian Theory_, published in 1802. Hutton wrote in so prolix and
+  obscure a style as rather to repel than attract readers. Playfair, on
+  the other hand, expressed himself in such clear and graceful language
+  as to command general attention, and to gain wide acceptance for his
+  master's views. Unlike the older cosmogonists, Hutton refrained from
+  trying to explain the origin of things, and from speculations as to
+  what might possibly have been the early history of our globe. He
+  determined from the outset to interpret the past by what can be seen
+  to be the present order of nature; and he refused to admit the
+  operation of causes which cannot be shown to be part of the actual
+  terrestrial system. Like other observers who had preceded him, he
+  recognized in the various rocks composing the dry land evidence of
+  former geographical conditions very different from those which now
+  prevail. He saw that the vast majority of rocks consist of hardened
+  sediments and must have been deposited in the sea. He could
+  distinguish among them an older or Primary series, and a younger or
+  Secondary series; and did not dispute the existence of a Tertiary
+  series claimed by Peter Simon Pallas (1741-1811). He believed that
+  these various aqueous accumulations had been consolidated by
+  subterranean heat, that the oldest and lowest rocks had suffered most
+  from this action, that into these more deep-seated masses subsequent
+  veins and larger bodies of molten matter were injected from below, and
+  thus that what was originally loose detritus eventually became changed
+  in such crystalline schists as are now found in mountain-chains. In
+  the course of these terrestrial revolutions sedimentary strata,
+  originally more or less nearly horizontal, have been pushed upward,
+  dislocated, crumpled, placed on end, and even elevated to form ranges
+  of lofty mountains. Hutton looked upon these disturbances as due to
+  the expansive power of subterranean heat; but he did not attempt to
+  sketch the mechanism of the process, and he expressly declined to
+  offer any conjecture as to how the land so elevated remains in that
+  position. He thought that the interior of our planet may "be a fluid
+  mass, melted, but unchanged by the action of heat"; and, far from
+  connecting volcanoes with the combustion of inflammable substances, as
+  had been the prevalent belief for so many centuries, he looked upon
+  them as a beneficent provision of "spiracles to the subterranean
+  furnace, in order to prevent the unnecessary elevation of land and
+  fatal effects of earthquakes."
+
+  A distinguishing feature of the Huttonian philosophy is to be seen in
+  the breadth of its conceptions regarding the geological operations
+  continually in progress on the surface of the globe. Hutton saw that
+  the land is undergoing a ceaseless process of degradation, through the
+  influence of the air, frost, rain, rivers and the sea, and that in
+  course of time, if no countervailing agency should intervene, the
+  whole of the dry land will be washed away into the sea. But he also
+  perceived that this universal erosion is not everywhere carried on at
+  the same rate; that it is specially active along the channels of
+  torrents and rivers, and that, owing to this difference these channels
+  are gradually deepened and widened, until the complicated
+  valley-system of a country is carved out. He recognized that the
+  detritus worn away from the land must be spread out over the floor of
+  the sea, so as to form there strata similar to those that compose most
+  of the dry land. As he could detect in the structure of land
+  convincing evidence that former sea floors had been elevated to form
+  the continents and islands of to-day, he could look forward to future
+  ages, when the same subterranean agency which had raised up the
+  present land would again be employed to uplift the bed of the existing
+  ocean, thus to renew the surface of our earth as a habitable globe,
+  and to start a fresh cycle of erosion and deposition.
+
+
+    Lamarck.
+
+  Though Hutton was not unaware that organic remains abound in many of
+  the stratified rocks, he left them out of consideration in the
+  elaboration of his theory. It was otherwise with one of his French
+  contemporaries, the illustrious J.B. Lamarck (1744-1829), who, after
+  having attained great eminence as a botanist, turned to zoology when
+  he was nearly fifty years of age, and before long rose to even greater
+  distinction in that department of science. His share in the
+  classification and description of the mollusca and in founding
+  invertebrate palaeontology, his theory of organic evolution and his
+  philosophical treatment of many biological questions have been tardily
+  recognized, but his contributions to geology have been less generally
+  acknowledged. When he accepted the "professorship of zoology; of
+  insects, of worms and of microscopic animals" at the Museum of Natural
+  History, Paris, in 1793, he at once entered with characteristic ardour
+  and capacity into the new field of research then opened to him. In
+  dealing with the mollusca he considered not merely the living but also
+  the extinct forms, especially the abundant, varied and well-preserved
+  genera and species furnished by the Tertiary deposits of the Paris
+  basin, of which he published descriptions and plates that proved of
+  essential service in the stratigraphical work of Cuvier and Alexandre
+  Brongniart (1770-1847). His labours among these relics of ancient seas
+  and lakes led him to ponder over the past history of the globe, and as
+  he was seldom dilatory in making known the opinions he had formed, he
+  communicated some of his conclusions to the National Institute in
+  1799. These, including a further elaboration of his views, he
+  published in 1802 in a small volume entitled Hydrogeologie.
+
+  This treatise, though it did not reach a second edition and has never
+  been reprinted, deserves an honourable place in geological literature.
+  Its object, the author states, was to present some important and novel
+  considerations, which he thought should form the basis of a true
+  theory of the earth. He entirely agreed with the doctrine of the
+  subaerial degradation of the land and the erosion of valleys by
+  running water. Not even Playfair could have stated this doctrine more
+  emphatically, and it is worthy of notice that Playfair's
+  _Illustrations of the Huttonian Theory_ appeared in the same year with
+  Lamarck's book. The French naturalist, however, carried his
+  conclusions so far as to take no account of any great movements of the
+  terrestrial crust, which might have produced or modified the main
+  physical features of the surface of the globe. He thought that all
+  mountains, except such as were thrown up by volcanic agency or local
+  accidents, have been cut out of plains, the original surfaces of which
+  are indicated by the crests and summits of these elevations.
+
+  Lamarck, in reflecting upon the wide diffusion of fossil shells and
+  the great height above the sea at which they are found, conceived the
+  extraordinary idea that the ocean basin has been scoured out by the
+  sea, and that, by an impulse communicated to the waters through the
+  influence chiefly of the moon, the sea is slowly eating away the
+  eastern margins of the continents, and throwing up detritus on their
+  western coasts, and is thus gradually shifting its basin round the
+  globe. He would not admit the operation of cataclysms; but insisted as
+  strongly as Hutton on the continuity of natural processes, and on the
+  necessity of explaining former changes of the earth's surface by
+  causes which can still be seen to be in operation. As might be
+  anticipated from his previous studies, he brought living things and
+  their remains into the forefront of his theory of the earth. He looked
+  upon fossils as one of the chief means of comprehending the
+  revolutions which the surface of the earth has undergone; and in his
+  little volume he again and again dwells on the vast antiquity to which
+  these revolutions bear witness. He acutely argues, from the condition
+  of fossil shells, that they must have lived and died where their
+  remains are now found.
+
+  In the last part of his treatise Lamarck advances some peculiar
+  opinions in physics and chemistry, which he had broached eighteen
+  years before, but which had met with no acceptance among the
+  scientific men of his time. He believed that the tendency of all
+  compound substances is to decay, and thereby to be resolved into their
+  component constituents. Yet he saw that the visible crust of the earth
+  consists almost wholly of compound bodies. He therefore set himself to
+  solve the problem thus presented. Perceiving that the biological
+  action of living organisms is constantly forming combinations of
+  matter, which would never have otherwise come into existence, he
+  proceeded to draw the extraordinary conclusion that the action of
+  plant and animal life (the _Pouvoir de la vie_) upon the inorganic
+  world is so universal and so potent, that the rocks and minerals which
+  form the outer part of the earth's crust are all, without exception,
+  the result of the operations of once living bodies. Though this
+  sweeping deduction must be allowed to detract from the value of
+  Lamarck's work, there can be no doubt that he realized, more fully
+  than any one had done before him, the efficacy of plants and animals
+  as agents of geological change.
+
+
+    Cuvier.
+
+  The last notable contributor to the cosmological literature of geology
+  was another illustrious Frenchman, the comparative anatomist Cuvier
+  (1769-1832). He was contemporary with Lamarck, but of a very different
+  type of mind. The brilliance of his speculations, and the charm with
+  which he expounded them, early gained for him a prominent place in the
+  society of Paris. He too was drawn by his zoological studies to
+  investigate fossil organic remains, and to consider the former
+  conditions of the earth's surface, of which they are memorials. It was
+  among the vertebrate organisms of the Paris basin that he found his
+  chief material, and from them that he prepared the memoirs which led
+  to him being regarded as the founder of vertebrate palaeontology. But
+  beyond their biological interest, they awakened in him a keen desire
+  to ascertain the character and sequence of the geographical
+  revolutions to which they bear witness. He approached the subject from
+  an opposite and less philosophical point of view than that of Lamarck,
+  coming to it with certain preconceived notions, which affected all
+  his subsequent writings. While Lamarck was by instinct an
+  evolutionist, who sought to trace in the history of the past the
+  operation of the same natural processes as are still at work, Cuvier,
+  on the other hand, was a catastrophist, who invoked a succession of
+  vast cataclysms to account for the interruptions in the continuity of
+  the geological record.
+
+  In a preliminary _Discourse_ prefixed to his _Recherches sur les
+  ossemens fossiles_ (1821) Cuvier gave an outline of what he conceived
+  to have been the past history of our globe, so far as he had been able
+  to comprehend it from his investigations of the Tertiary formations of
+  France. He believed that in that history evidence can be recognized of
+  the occurrence of many sudden and disastrous revolutions, which, to
+  judge from their effects on the animal life of the time, must have
+  exceeded in violence anything we can conceive at the present day, and
+  must have been brought about by other agencies than those which are
+  now in operation. Yet, in spite of these catastrophes, he saw that
+  there has been an upward progress in the animal forms inhabiting the
+  globe, until the series ended in the advent of man. He could not,
+  however, find any evidence that one species has been developed from
+  another, for in that case there should have been traces of
+  intermediate forms among the stratified formations, where he affirmed
+  that they had never been found. A prominent position in the
+  _Discourse_ is given to a strenuous argument to disprove the alleged
+  antiquity of some nations, and to show that the last great catastrophe
+  occurred not more than some 5000 or 6000 years ago. Cuvier thus linked
+  himself with those who in previous generations had contended for the
+  efficacy of the Deluge. But his researches among fossil animals had
+  given him a far wider outlook into the geological past, and had opened
+  up to him a succession of deeply interesting problems in the history
+  of life upon the earth, which, though he had not himself material for
+  their solution, he could foresee would be cleared up in the future.
+
+  _Gradual Shaping of Geology into a Distinct Branch of Science._--It
+  will be seen from the foregoing historical sketch that it was only
+  after the lapse of long centuries, and from the labours of many
+  successive generations of observers and writers, that what we now know
+  as the science of geology came to be recognized as a distinct
+  department of natural knowledge, founded upon careful and extended
+  study of the structure of the earth, and upon observation of the
+  natural processes, which are now at work in changing the earth's
+  surface. The term "geology,"[1] descriptive of this branch of the
+  investigation of nature, was not proposed until the last quarter of
+  the 18th century by Jean Andre De Luc (1727-1817) and Horace Benedict
+  De Saussure (1740-1749). But the science was then in a markedly
+  half-formed condition, theoretical speculation still in large part
+  supplying the place of deductions from a detailed examination of
+  actual fact. In 1807 a few enterprising spirits founded the Geological
+  Society of London for the special purpose of counteracting the
+  prevalent tendency and confining their intention "to investigate the
+  mineral structure of the earth." The cosmogonists and framers of
+  Theories of the Earth were succeeded by other schools of thought. The
+  Catastrophists saw in the composition of the crust of the earth
+  distinct evidence that the forces of nature were once much more
+  stupendous in their operation than they now are, and that they had
+  from time to time devastated the earth's surface; extirpating the
+  races of plants and animals, and preparing the ground for new
+  creations of organized life. Then came the Uniformitarians, who,
+  pushing the doctrines of Hutton to an extreme which he did not
+  propose, saw no evidence that the activity of the various geological
+  causes has ever seriously differed from what it is at present. They
+  were inclined to disbelieve that the stratified formations of the
+  earth's crust furnish conclusive evidence of a gradual progression,
+  from simple types of life in the oldest strata to the most highly
+  developed forms in the youngest; and saw no reason why remains of the
+  higher vertebrates should not be met with among the Palaeozoic
+  formations. Sir Charles Lyell (1797-1875) was the great leader of this
+  school. His admirably clear and philosophical presentations of
+  geological facts which, with unwearied industry, he collected from the
+  writings of observers in all parts of the world, impressed his views
+  upon the whole English-speaking world, and gave to geological science
+  a coherence and interest which largely accelerated its progress. In
+  his later years, however, he frankly accepted the views of Darwin in
+  regard to the progressive character of the geological record.
+
+  The youngest of the schools of geological thought is that of the
+  Evolutionists. Pointing to the whole body of evidence from inorganic
+  and organic nature, they maintain that the history of our planet has
+  been one of continual and unbroken development from the earliest
+  cosmical beginnings down to the present time, and that the crust of
+  the earth contains an abundant, though incomplete, record of the
+  successive stages through which the plant and animal kingdoms have
+  reached their existing organization. The publication of Darwin's
+  _Origin of Species_ in 1859, in which evolution was made the key to
+  the history of the animal and vegetable kingdoms, produced an
+  extraordinary revolution in geological opinion. The older schools of
+  thought rapidly died out, and evolution became the recognized creed of
+  geologists all over the world.
+
+
+    Werner.
+
+  _Development of Opinion regarding Igneous Rocks._--So long as the idea
+  prevailed that volcanoes are caused by the combustion of inflammable
+  substances underground, there could be no rational conception of
+  volcanic action and its products. Even so late as the middle of the
+  18th century, as above remarked, such a good observer as Lazzaro Moro
+  drew so little distinction between volcanic and other rocks that he
+  could believe the fossiliferous formations to have been mainly formed
+  of materials ejected from eruptive vents. After his time the notion
+  continued to prevail that all the rocks which form the dry land were
+  laid down under water. Even streams of lava, which were seen to flow
+  from an active crater, were regarded only as portions of sedimentary
+  or other rocks, which had been melted by the fervent heat of the
+  burning inflammable materials that had been kindled underground. In
+  spite of the speculations of Descartes and Leibnitz, it was not yet
+  generally comprehended that there exists beneath the terrestrial crust
+  a molten magma, which, from time to time, has been injected into that
+  crust, and has pierced through it, so as to escape at the surface with
+  all the energy of an active volcano. What we now recognize to be
+  memorials of these former injections and propulsions were all
+  confounded with the rocks of unquestionably aqueous origin. The last
+  great teacher by whom these antiquated doctrines were formulated into
+  a system and promulgated to the world was Abraham Gottlob Werner
+  (1749-1815), the most illustrious German mineralogist and geognost of
+  the second half of the 18th century. While still under twenty-six
+  years of age, he was appointed teacher of mining and mineralogy at the
+  Mining Academy of Freiberg in Saxony--a post which he continued to
+  fill up to the end of his life. Possessed of great enthusiasm for his
+  subject, clear, methodical and eloquent in his exposition of it, he
+  soon drew around him men from all parts of the world, who repaired to
+  study under the great oracle of what he called geognosy (Gr. [Greek:
+  ge], the earth, [Greek: gnosis], knowledge) or earth-knowledge.
+  Reviving doctrines that had been current long before his time, he
+  taught that the globe was once completely surrounded with an ocean,
+  from which the rocks of the earth's crust were deposited as chemical
+  precipitates, in a certain definite order over the whole planet. Among
+  these "universal formations" of aqueous origin were included many
+  rocks, which have long been recognized to have been once molten, and
+  to have risen from below into the upper parts of the terrestrial
+  crust. Werner, following the old tradition, looked upon volcanoes as
+  modern features in the history of the planet, which could not have
+  come into existence until a sufficient amount of vegetation had been
+  buried to furnish fuel for their maintenance. Hence he attached but
+  little importance to them, and did not include in his system of rocks
+  any division of volcanic or igneous materials. From the predominant
+  part assigned by him to the sea in the accumulation of the materials
+  of the visible part of the earth, Werner and his school were known as
+  "Neptunists."
+
+
+    Origin of basalt.
+
+  But many years before the Saxon professor began to teach, clear
+  evidence had been produced from central France that basalt, one of the
+  rocks claimed by him as a chemical precipitate and a universal
+  formation, is a lava which has been poured out in a molten state at
+  various widely separated periods of time and at many different places.
+  So far back as 1752 J.E. Guettard (1715-1786) had shown that the
+  basaltic rocks of Auvergne are true lavas, which have flowed out in
+  streams from groups of once active cones. Eleven years later the
+  observation was confirmed and greatly extended by Nicholas Desmarest
+  (1725-1815), who, during a long course of years, worked out and mapped
+  the complicated volcanic records of that interesting region, and
+  demonstrated to all who were willing impartially to examine the
+  evidence the true volcanic nature of basalt. These views found
+  acceptance from some observers, but they were vehemently opposed by
+  the followers of Werner, who, by the force of his genius, made his
+  theoretical conceptions predominate all over Europe. The controversy
+  as to the origin of basalt was waged with great vigour during the
+  later decades of the 18th century. Desmarest took no part in it. He
+  had accumulated such conclusive proof of the correctness of his
+  deductions, and had so fully expounded the clearness of the evidence
+  in their favour furnished by the region of Auvergne, that, when any
+  one came to consult him on the subject, he contented himself with
+  giving the advice to "go and see." While the debate was in progress on
+  the continent, the subject was approached from a new and independent
+  point of view by Hutton in Scotland. This illustrious philosopher, as
+  already stated, realized the importance of the internal heat of the
+  globe in consolidating the sedimentary rocks, and believed that molten
+  material from the earth's interior has been protruded from below into
+  the overlying crust. Some of the material thus injected could be
+  recognized, he thought, in granite and in the various dark massive
+  rocks which, known in Scotland under the name of "whinstone," were
+  afterwards called "Trap," and are now grouped under various names,
+  such as basalt, dolerite and diorite. So important a share did Hutton
+  thus assign to the internal heat in the geological evolution of the
+  planet, that he and those who adopted the same opinions were styled
+  "Plutonists," or, especially where they concerned themselves with the
+  volcanic origin of basalt, "Vulcanists." The geological world was thus
+  divided into two hostile camps, that of the Neptunists or Wernerians,
+  and that of the Plutonists, Vulcanists or Huttonians.
+
+  After many years of futile controversy the first serious weakening of
+  the position of the dominant Neptunist school arose from the defection
+  of some of the most prominent of Werner's pupils. In particular Jean
+  Francois D'Aubuisson de Voisins (1769-1819), who had written a
+  treatise on the aqueous origin of the basalts of Saxony, went
+  afterwards to Auvergne, where he was speedily a convert to the views
+  expounded by Desmarest as to the volcanic nature of basalt. Having
+  thus to relinquish one of the fundamental articles of the Freiberg
+  faith, he was subsequently led to modify his adherence to others
+  until, as he himself confessed, his views came almost wholly to agree
+  with those of Hutton. Not less complete, and even more important, was
+  the conversion of the great Leopold von Buch (1774-1853). He, too, was
+  trained by Werner himself, and proved to be the most illustrious pupil
+  of the Saxon professor. Full of admiration for the Neptunism in which
+  he had been reared, he, in his earliest separate work, maintained the
+  aqueous origin of basalt, and contrasted the wide field opened up to
+  the spirit of observation by his master's teaching with the narrower
+  outlook offered by "the volcanic theory." But a little further
+  acquaintance with the facts of nature led Von Buch also to abandon his
+  earlier prepossessions. It was a personal visit to the volcanic region
+  of Auvergne that first opened his eyes, and led him to recant what he
+  had believed and written about basalt. But the abandonment of so
+  essential a portion of the Wernerian creed prepared the way for
+  further relinquishments. When a few years later he went to Norway and
+  found to his astonishment that granite, which he had been taught to
+  regard as the oldest chemical precipitate from the universal ocean,
+  could there be seen to have broken through and metamorphosed
+  fossiliferous limestones, and to have sent veins into them, his faith
+  in Werner's order of the succession of the rocks in the earth's crust
+  received a further momentous shock. While one after another of the
+  Freiberg doctrines crumbled away before him, he was now able to
+  interrogate nature on a wider field than the narrow limits of Saxony,
+  and he was thus gradually led to embrace the tenets of the opposite
+  school. His commanding position, as the most accomplished geologist on
+  the continent, gave great importance to his recantation of the
+  Neptunist creed. His defection indeed was the severest blow that this
+  creed had yet sustained. It may be said to have rung the knell of
+  Wernerianism, which thereafter rapidly declined in influence, while
+  Plutonism came steadily to the front, where it has ever since
+  remained.
+
+  Although Desmarest had traced in Auvergne a long succession of
+  volcanic eruptions, of which the oldest went back to a remote period
+  of time, and although he had shown that this succession, coupled with
+  the records of contemporaneous denudation, might be used in defining
+  epochs of geological history, it was not until many years after his
+  day that volcanic action came to be recognized as a normal part of the
+  mechanism of our globe, which had been in operation from the remotest
+  past, and which had left numerous records among the rocks of the
+  terrestrial crust. During the progress of the controversy between the
+  two great opposing factions in the later portion of the 18th and the
+  first three decades of the 19th century, those who espoused the
+  Vulcanist cause were intent on proving that certain rocks, which are
+  intercalated among the stratified formations and which were claimed by
+  the Neptunists as obviously formed by water, are nevertheless of truly
+  igneous origin. These observers fixed their eyes on the evidence that
+  the material of such rocks, instead of having been deposited from
+  aqueous solution, had once been actually molten, and had in that
+  condition been thrust between the strata, had enveloped portions of
+  them, and had indurated or otherwise altered them. They spoke of these
+  masses as "unerupted lavas"; and undoubtedly in innumerable instances
+  they were right. But their zeal to establish an intrusive origin led
+  them to overlook the proofs that some intercalated sheets of igneous
+  material had not been injected into the strata, but had been poured
+  out at the surface as truly volcanic discharges, and therefore
+  belonged to the ancient periods represented by the strata between
+  which they are interposed. It may readily be supposed that any proofs
+  of the contemporaneous intercalation of such sheets would be eagerly
+  seized upon by the Neptunists in favour of their aqueous theory. The
+  influence of the ancient belief that "burning mountains" could only
+  rise from the combustion of subterranean inflammable materials
+  extended even into the ranks of the Vulcanists, so far at least as to
+  lead to a general acquiescence in the assumption that volcanoes
+  appeared to belong to a late phase in the history of the planet. It
+  was not until after considerable progress had been made in determining
+  the palaeontological distinctions and order of succession of the
+  stratified formations of the earth's crust that it became possible to
+  trace among these formations a succession of volcanic episodes which
+  were contemporaneous with them. In no part of the world has an ampler
+  record of such episodes been preserved than in the British Isles. It
+  was natural, therefore, that the subject should there receive most
+  attention. As far back as 1820 Ami Boue (1794-1881) showed that the
+  Old Red Sandstone of Scotland includes a great series of volcanic
+  rocks, and that other rocks of volcanic origin are associated with the
+  Carboniferous formations. H.T. de la Beche (1796-1855) afterwards
+  traced proofs of contemporaneous eruptions among the Devonian rocks of
+  the south-west of England. Adam Sedgwick (1785-1873) showed, first in
+  the Lake District, and afterwards in North Wales, the presence of
+  abundant volcanic sheets among the oldest divisions of the Palaeozoic
+  series; while Roderick Impey Murchison (1792-1871) made similar
+  discoveries among the Lower Silurian rocks. From the time of these
+  pioneers the volcanic history of the country has been worked out by
+  many observers until it is now known with a fulness as yet unattained
+  in any other region.
+
+  _Growth of Opinion regarding Earthquakes._--We have seen how crude
+  were the conceptions of the ancients regarding the causes of volcanic
+  action, and that they connected volcanoes and earthquakes as results
+  of the commotion of wind imprisoned within subterranean caverns and
+  passages. One of the earliest treatises, in which the phenomena of
+  terrestrial movements were discussed in the spirit of modern science,
+  was the posthumous collection of papers by Robert Hooke (1635-1703),
+  entitled _Lectures and Discourses of Earthquakes and Subterranean
+  Eruptions_, where the probable agency of earthquakes in upheaving and
+  depressing land is fully considered, but without any definite
+  pronouncement as to the author's conception of its origin. Hooke still
+  associated earthquakes with volcanic action, and connected both with
+  what he called "the general congregation of sulphurous subterraneous
+  vapours." He conceived that some kind of "fermentation" takes place
+  within the earth, and that the materials which catch fire and give
+  rise to eruptions or earthquakes are analogous to those that
+  constitute gunpowder. The first essay wherein earthquakes are treated
+  from the modern point of view as the results of a shock that sends
+  waves through the crust of the earth was written by the Rev. John
+  Michell, and communicated to the Royal Society in the year 1760. Still
+  under the old misconception that volcanoes are due to the combustion
+  of inflammable materials, which he thought might be set on fire by the
+  spontaneous combustion of pyritous strata, he supposed that, by the
+  sudden access of large bodies of water to these subterranean fires,
+  vapour is produced in such quantity and with such force as to give
+  rise to the shock. From the centre of origin of this shock waves, he
+  thought, are propagated through the earth, which are largest at the
+  start and gradually diminish as they travel outwards. By drawing lines
+  at different places in the direction of the track of these waves, he
+  believed that the place of common intersection of these lines would be
+  nearly the centre of the disturbance. In this way he showed that the
+  great Lisbon earthquake of 1755 had its focus under the Atlantic,
+  somewhere between the latitudes of Lisbon and Oporto, and he estimated
+  that the depth at which it originated could not be much less than 1
+  m., and probably did not exceed 3 m. Michell, however, misconceived
+  the character of the waves which he described, seeing that he believed
+  them to be due to the actual propagation of the vapour itself
+  underneath the surface of the earth. A century had almost passed after
+  the date of his essay before modern scientific methods of observation
+  and the use of recording instruments began to be applied to the study
+  of earthquake phenomena. In 1846 Robert Mallet (1810-1881) published
+  an important paper "On the Dynamics of Earthquakes" in the
+  _Transactions of the Royal Irish Academy_. From that time onward he
+  continued to devote his energies to the investigation, studying the
+  effects of the Calabrian earthquake of 1857, experimenting on the
+  transmission of waves of shock through various materials, caused by
+  exploding charges of gunpowder, and collecting all the information to
+  be obtained on the subject. His writings, and especially his work in
+  two volumes on _The First Principles of Observational Seismology_,
+  must be regarded as having laid the foundations of this branch of
+  modern geology (see EARTHQUAKE; SEISMOMETER).
+
+  _History of the Evolution of Stratigraphical Geology._--Men had long
+  been familiar with the evidence that the present dry land once lay
+  under the sea, before they began to realize that the rocks, of which
+  the land consists, contain a record of many alternations of land and
+  sea, and relics of a long succession of plants and animals from early
+  and simple types up to the manifold and complex forms of to-day. In
+  countries where coal-mining had been prosecuted for generations, it
+  had been recognized that the rocks consist of strata superposed on
+  each other in a definite order, which was found to extend over the
+  whole of a district. As far back as 1719 John Strachey drew attention
+  to this fact in a communication published in the _Philosophical
+  Transactions_. John Michell (1760), in the paper on earthquakes
+  already cited, showed that he had acquired a clear understanding of
+  the order of succession among stratified formations, and perceived
+  that to disturbances of the terrestrial crust must be ascribed the
+  fact that the lower or older and more inclined strata form the
+  mountains, while the younger and more horizontal strata are spread
+  over the plains.
+
+  In Italy G. Arduino (1713-1795) classified the rocks in the north of
+  the peninsula as Primitive, Secondary, Tertiary and Volcanic. A
+  similar threefold order was announced for the Harz and Erzgebirge by
+  J.G. Lehmann in 1756. He recognized in that region an ancient series
+  of rocks in inclined or vertical strata, which rise to the tops of the
+  hills and descend to an unknown depth into the interior. These masses,
+  he thought, were contemporaneous with the making of the world. Next
+  came the Flotzgebirge, consisting of younger sediments, disposed in
+  flat or gently inclined sheets which overlie the first and more
+  disturbed series, and are full of petrified remains of plants and
+  animals. Lastly he included the mountains which have from time to time
+  been formed by local accidents. Still more advanced were the
+  conceptions of G.C. Fuchsel, who in the year 1762 published in Latin
+  _A History of the Earth and the Sea, based on a History of the
+  Mountains of Thuringia_; and in 1773, in German, a _Sketch of the most
+  Ancient History of the Earth and Man_. In these works he described the
+  stratigraphical relations and general characters of the various
+  geological formations in his little principality; and taking them as
+  indicative of a general order of succession, he traced what he
+  believed to have been a series of revolutions through which the earth
+  has passed. In interpreting this geological history, he laid great
+  stress on the evidence of the fossils contained in the rocks. He
+  recognized that the various formations differ from each other in their
+  enclosed organic remains, and that from these differences the
+  existence of former sea-bottoms and land surfaces can be determined.
+
+  The labours of these pioneers paved the way for the advent of Werner.
+  Though the system evolved by this teacher claimed to discard theory
+  and to be established on a basis of observed facts, it rested on a
+  succession of hypotheses, for which no better foundation could be
+  shown than the belief of their author in their validity. Starting from
+  the extremely limited stratigraphical range displayed in the
+  geological structure of Saxony, he took it as a type for the rest of
+  the globe, persuading himself and impressing upon his followers that
+  the rocks of that small kingdom were to be taken as examples of his
+  "universal formations." The oldest portion of the series, classed by
+  him as "Primitive," consisted of rocks which he maintained had been
+  deposited from chemical solution. Yet they included granite, gneiss,
+  basalt, porphyry and serpentine, which, even in his own day, were by
+  many observers correctly regarded as of igneous origin. A later group
+  of rocks, to which he gave the name of "Transition," comprised, in his
+  belief, partly chemical, partly mechanical sediments, and contained
+  the earliest fossil organic remains. A third group, for which he
+  reserved Lehmann's name "Flotz," was made up chiefly of mechanical
+  detritus, while youngest of all came the "Alluvial" series of loams,
+  clays, sands, gravels and peat. It was by the gradual subsidence of
+  the ocean that, as he believed, the general mass of the dry land
+  emerged, the first-formed rocks being left standing up, sometimes on
+  end, to form the mountains, while those of later date, less steeply
+  inclined, occupied successively lower levels down to the flat alluvial
+  accumulations of the plains. Neither Werner, nor any of his followers,
+  ventured to account for what became of the water as the sea-level
+  subsided, though, in despite of their antipathy to anything like
+  speculation, they could not help suggesting, as an answer to the
+  cogent arguments of their opponents, that "one of the celestial bodies
+  which sometimes approach near to the earth may have been able to
+  withdraw a portion of our atmosphere and of our ocean." Nor was any
+  attempt made to explain the extraordinary nature of the supposed
+  chemical precipitates of the universal ocean. The progress of inquiry
+  even in Werner's lifetime disproved some of the fundamental portions
+  of his system. Many of the chemical precipitates were shown to be
+  masses that had been erupted in a molten state from below. His order
+  of succession was found not to hold good; and though he tried to
+  readjust his sequence and to introduce into it modifications to suit
+  new facts, its inherent artificiality led to its speedy decline after
+  his death. It must be conceded, however, that the stress which he laid
+  upon the fact that the rocks of the earth's crust were deposited in a
+  definite order had an important influence in directing attention to
+  this subject, and in preparing the way for a more natural system,
+  based not on mere mineralogical characters, but having regard to the
+  organic remains, which were now being gathered in ever-increasing
+  numbers and variety from stratified formations of many different ages
+  and from all parts of the globe.
+
+  It was in France and in England that the foundations of stratigraphy,
+  based upon a knowledge of organic remains, were first successfully
+  laid. Abbe J.L. Giraud-Soulavie (1752-1813), in his _Histoire
+  naturelle de la France meridionale_, which appeared in seven volumes,
+  subdivided the limestones of Vivarais into five ages, each marked by a
+  distinct assemblage of shells. In the lowest strata, representing the
+  first age, none of the fossils were believed by him to have any living
+  representatives, and he called these rocks "Primordial." In the next
+  group a mingling of living with extinct forms was observable. The
+  third age was marked by the presence of shells of still existing
+  species. The strata of the fourth series were characterized by
+  carbonaceous shales or slates, containing remains of primordial
+  vegetation, and perhaps equivalents of the first three calcareous
+  series. The fifth age was marked by recent deposits containing remains
+  of terrestrial vegetation and of land animals. It is remarkable that
+  these sagacious conclusions should have been formed and published at a
+  time when the geologists of the Continent were engaged in the
+  controversy about the origin of basalt, or in disputes about the
+  character and stratigraphical position of the supposed universal
+  formations, and when the interest and importance of fossil organic
+  remains still remained unrecognized by the vast majority of the
+  combatants.
+
+  The rocks of the Paris basin display so clearly an orderly
+  arrangement, and are so distinguished for the variety and perfect
+  preservation of their enclosed organic remains, that they could not
+  fail to attract the early notice of observers. J. E. Guettard, G.F.
+  Rouelle (1703-1770), N. Desmarest, A.L. Lavoisier (1743-1794) and
+  others made observations in this interesting district. But it was
+  reserved for Cuvier (1769-1832) and A. Brongniart (1770-1847) to work
+  out the detailed succession of the Tertiary formations, and to show
+  how each of these is characterized by its own peculiar assemblage of
+  organic remains. The later progress of investigation has slightly
+  corrected and greatly amplified the tabular arrangement established by
+  these authors in 1808, but the broad outlines of the Tertiary
+  stratigraphy of the Paris basin remain still as Cuvier and Brongniart
+  left them. The most important subsequent change in the classification
+  of the Tertiary formations was made by Sir Charles Lyell, who,
+  conceiving in 1828 the idea of a classification of these rocks by
+  reference to their relative proportions of living and extinct species
+  of shells, established, in collaboration with G.P. Deshayes, the now
+  universally accepted divisions Eocene, Miocene and Pliocene.
+
+  Long before Cuvier and Brongniart published an account of their
+  researches, another observer had been at work among the Secondary
+  formations of the west of England, and had independently discovered
+  that the component members of these formations were each distinguished
+  by a peculiar group of organic remains; and that this distinction
+  could be used to discriminate them over all the region through which
+  he had traced them. The remarkable man who arrived at this
+  far-reaching generalization was William Smith (1769-1839), a land
+  surveyor who, in the prosecution of his professional business, found
+  opportunities of traversing a great part of England, and of putting
+  his deductions to the test. As the result of these journeys he
+  accumulated materials enough to enable him to produce a geological map
+  of the country, on which the distribution and succession of the rocks
+  were for the first time delineated. Smith's labours laid the
+  foundation of stratigraphical geology in England and he was styled
+  even in his lifetime the "Father of English geology." From his day
+  onward the significance of fossil organic remains gained rapidly
+  increasing recognition. Thus in England the outlines traced by him
+  among the Secondary and Tertiary formations were admirably filled in
+  by Thomas Webster (1773-1844); while the Cretaceous series was worked
+  out in still greater detail in the classic memoirs of William Henry
+  Fitton (1780-1861).
+
+  There was one stratigraphical domain, however, into which William
+  Smith did not enter. He traced his sequence of rocks down into the
+  Coal Measures, but contented himself with only a vague reference to
+  what lay underneath that formation. Though some of these underlying
+  rocks had in various countries yielded abundant fossils, they had
+  generally suffered so much from terrestrial disturbances, and their
+  order of succession was consequently often so much obscured throughout
+  western Europe, that they remained but little known for many years
+  after the stratigraphy of the Secondary and Tertiary series had been
+  established. At last in 1831 Murchison began to attack this _terra
+  incognita_ on the borders of South Wales, working into it from the Old
+  Red Sandstone, the stratigraphical position of which was well known.
+  In a few years he succeeded in demonstrating the existence of a
+  succession of formations, each distinguished by its own peculiar
+  assemblage of organic remains which were distinct from those in any of
+  the overlying strata. To these formations he gave the name of Silurian
+  (q.v.). From the key which his researches supplied, it was possible to
+  recognize in other countries the same order of formations and the same
+  sequence of fossils, so that, in the course of a few years,
+  representatives of the Silurian system were found far and wide over
+  the globe. While Murchison was thus engaged, Sedgwick devoted himself
+  to the more difficult task of unravelling the complicated structure of
+  North Wales. He eventually made out the order of the several
+  formations there, with their vast intercalations of volcanic material.
+  He named them the Cambrian system (q.v.), and found them to contain
+  fossils, which, however, lay for some time unexamined by him. He at
+  first believed, as Murchison also did, that his rocks were all older
+  than any part of the Silurian series. It was eventually discovered
+  that a portion of them was equivalent to the lower part of that
+  series. The oldest of Sedgwick's groups, containing distinctive
+  fossils, retain the name Cambrian, and are of high interest, as they
+  enclose the remains of the earliest faunas which are yet well known.
+  Sedgwick and Murchison rendered yet another signal service to
+  stratigraphical geology by establishing, in 1839, on a basis of
+  palaeontological evidence supplied by W. Lonsdale, the independence of
+  the Devonian system (q.v.).
+
+  For many years the rocks below the oldest fossiliferous deposits
+  received comparatively little attention. They were vaguely described
+  as the "crystalline schists" and were often referred to as parts of
+  the primeval crust in which no chronology was to be looked for. W.E.
+  Logan (1798-1875) led the way, in Canada, by establishing there
+  several vast series of rocks, partly of crystalline schists and
+  gneisses (Laurentian) and partly of slates and conglomerates
+  (Huronian). Later observers, both in Canada and the United States,
+  have greatly increased our knowledge of these rocks, and have shown
+  their structure to be much more complex than was at first supposed
+  (see ARCHEAN SYSTEM).
+
+  During the latter half of the 19th century the most important
+  development of stratigraphical geology was the detailed working out
+  and application of the principle of zonal classification to the
+  fossiliferous formations--that is, the determination of the sequence
+  and distribution of organic remains in these formations, and the
+  arrangement of the strata into zones, each of which is distinguished
+  by a peculiar assemblage of fossil species (see under Part VI.). The
+  zones are usually named after one especially characteristic species.
+  This system of classification was begun in Germany with reference to
+  the members of the Jurassic system (q.v.) by A. Oppel (1856-1858) and
+  F.A. von Quenstedt (1858), and it has since been extended through the
+  other Mesozoic formations. It has even been found to be applicable to
+  the Palaeozoic rocks, which are now subdivided into palaeontological
+  zones. In the Silurian system, for example, the graptolites have been
+  shown by C. Lapworth to furnish a useful basis for zonal subdivisions.
+  The lowest fossiliferous horizon in the Cambrian rocks of Europe and
+  North America is known as the _Olenellus_ zone, from the prominence in
+  it of that genus of trilobite.
+
+  Another conspicuous feature in the progress of stratigraphy during the
+  second half of the 19th century was displayed by the rise and rapid
+  development of what is known as Glacial geology. The various deposits
+  of "drift" spread over northern Europe, and the boulders scattered
+  across the surface of the plains had long attracted notice, and had
+  even found a place in popular legend and superstition. When men began
+  to examine them with a view to ascertain their origin, they were
+  naturally regarded as evidences of the Noachian deluge. The first
+  observer who drew attention to the smoothed and striated surfaces of
+  rock that underlie the Drifts was Hutton's friend, Sir James Hall, who
+  studied them in the lowlands of Scotland and referred them to the
+  action of great debacles of water, which, in the course of some
+  ancient terrestrial convulsion, had been launched across the face of
+  the country. Playfair, however, pointed out that the most potent
+  geological agents for the transportation of large blocks of stone are
+  the glaciers. But no one was then bold enough to connect the travelled
+  boulders with glaciers on the plains of Germany and of Britain. Yet
+  the transporting agency of ice was invoked in explanation of their
+  diffusion. It came to be the prevalent belief among the geologists of
+  the first half of the 19th century, that the fall of temperature,
+  indicated by the gradual increase in the number of northern species of
+  shells in the English Crag deposits, reached its climax during the
+  time of the Drift, and that much of the north and centre of Europe was
+  then submerged beneath a sea, across which floating icebergs and floes
+  transported the materials of the Drift and dropped the scattered
+  boulders. As the phenomena are well developed around the Alps, it was
+  necessary to suppose that the submergence involved the lowlands of the
+  Continent up to the foot of that mountain chain--a geographical change
+  so stupendous as to demand much more evidence than was adduced in its
+  support. At last Louis Agassiz (1807-1873), who had varied his
+  palaeontological studies at Neuchatel by excursions into the Alps, was
+  so much struck by the proofs of the former far greater extension of
+  the Swiss glaciers, that he pursued the investigation and satisfied
+  himself that the ice had formerly extended from the Alpine valleys
+  right across the great plain of Switzerland, and had transported huge
+  boulders from the central mountains to the flanks of the Jura. In the
+  year 1840 he visited Britain and soon found evidence of similar
+  conditions there. He showed that it was not by submergence in a sea
+  cumbered with floating ice, but by the former presence of vast
+  glaciers or sheets of ice that the Drift and erratic blocks had been
+  distributed. The idea thus propounded by him did not at once command
+  complete approval, though traces of ancient glaciers in Scotland and
+  Wales were soon detected by native geologists, particularly by W.
+  Buckland, Lyell, J.D. Forbes and Charles Maclaren. Robert Chambers
+  (1802-1871) did good service in gathering additional evidence from
+  Scotland and Norway in favour of Agassiz's views, which steadily
+  gained adherents until, after some quarter of a century, they were
+  adopted by the great majority of geologists in Britain, and
+  subsequently in other countries. Since that time the literature of
+  geology has been swollen by a vast number of contributions in which
+  the history of the Glacial period, and its records both in the Old and
+  New World, have been fully discussed.
+
+  _Rise and Progress of Palaeontological Geology._--As this branch of
+  the science deals with the evidence furnished by fossil organic
+  remains as to former geographical conditions, it early attracted
+  observers who, in the superficial beds of marine shells found at some
+  distance from the coast, saw proofs of the former submergence of the
+  land under the sea. But the occurrence of fossils embedded in the
+  heart of the solid rocks of the mountains offered much greater
+  difficulties of explanation, and further progress was consequently
+  slow. Especially baneful was the belief that these objects were mere
+  sports of nature, and had no connexion with any once living organisms.
+  So long as the true organic origin of the fossil plants and animals
+  contained in the rocks was in dispute, it was hardly possible that
+  much advance could be made in their systematic study, or in the
+  geological deductions to be drawn from them. One good result of the
+  controversy, however, was to be seen in the large collections of these
+  "formed stones" that were gathered together in the cabinets and
+  museums of the 17th and 18th centuries. The accumulation and
+  comparison of these objects naturally led to the production of
+  treatises in which they were described and not unfrequently
+  illustrated by good engravings. Switzerland was more particularly
+  noted for the number and merit of its works of this kind, such as
+  that of K.N. Lang (_Historia lapidum figuratorum Helvetiae_, 1708) and
+  those of Johann Jacob Scheuchzer (1672-1733). In England, also,
+  illustrated treatises were published both by men who looked on fossils
+  as mere freaks of nature, and by those who regarded them as proofs of
+  Noah's flood. Of the former type were the works of Martin Lister
+  (1638-1712) and Robert Plot (_Natural History of Oxfordshire_, 1677).
+  The Celtic scholar Edward Llwyd (1660-1709) wrote a Latin treatise
+  containing good plates of a thousand fossils in the Ashmolean Museum,
+  Oxford, and J. Woodward, in 1728-1729, published his _Natural History
+  of the Fossils of England_, already mentioned, wherein he described
+  his own extensive collection, which he bequeathed to the University of
+  Cambridge, where it is still carefully preserved. The most voluminous
+  and important of all these works, however, appeared at a later date at
+  Nuremberg. It was begun by G.W. Knorr (1705-1761), who himself
+  engraved for it a series of plates, which for beauty and accuracy have
+  seldom been surpassed. After his death the work was continued by
+  J.E.I. Walch (1725-1778), and ultimately consisted of four massive
+  folio volumes and nearly 300 plates under the title of _Lapides
+  diluvii universalis testes_. Although the authors supposed their
+  fossils to be relics of Noah's flood, their work must be acknowledged
+  to mark a distinct onward stage in the palaeontological department of
+  geology.
+
+  It was in France that palaeontological geology began to be cultivated
+  in a scientific spirit. The potter Bernard Palissy, as far back as
+  1580, had dwelt on the importance of fossil shells as monuments of
+  revolutions of the earth's surface; but the observer who first
+  undertook the detailed study of the subject was Jean Etienne Guettard,
+  who began in 1751 to publish his descriptions of fossils in the form
+  of memoirs presented to the Academy of Sciences of Paris. To him they
+  were not only of deep interest as monuments of former types of
+  existence, but they had an especial value as records of the changes
+  which the country had undergone from sea to land and from land to sea.
+  More especially noteworthy was a monograph by him which appeared in
+  1765 bearing the title "On the accidents that have befallen Fossil
+  Shells compared with those which are found to happen to shells now
+  living in the Sea." In this treatise he showed that the fossils have
+  been encrusted with barnacles and serpulae, have been bored into by
+  other organisms, and have often been rounded or broken before final
+  entombment; and he inferred that these fossils must have lived and
+  died on the sea-floor under similar conditions to those which obtain
+  on the sea-floor to-day. His argument was the most triumphant that had
+  ever been brought against the doctrine of _lusus naturae_, and that of
+  the efficacy of Noah's flood--doctrines which still held their ground
+  in Guettard's day. When Soulavie, Cuvier and Brongniart in France, and
+  William Smith in England, showed that the rock formations of the
+  earth's crust could be arranged in chronological order, and could be
+  recognized far and wide by means of their enclosed organic remains,
+  the vast significance of these remains in geological research was
+  speedily realized, and palaeontological geology at once entered on a
+  new and enlarged phase of development. But apart from their value as
+  chronological monuments, and as witnesses of former conditions of
+  geography, fossils presented in themselves a wide field of
+  investigation as types of life that had formerly existed, but had now
+  passed away. It was in France that this subject first took definite
+  shape as an important branch of science. The mollusca of the Tertiary
+  deposits of the Paris basin became, in the hands of Lamarck, the basis
+  on which invertebrate palaeontology was founded. The same series of
+  strata furnished to Cuvier the remains of extinct land animals, of
+  which, by critical study of their fragmentary bones and skeletons, he
+  worked out restorations that may be looked on as the starting-point of
+  vertebrate palaeontology. These brilliant researches, rousing
+  widespread interest in such studies, showed how great a flood of light
+  could be thrown on the past history of the earth and its inhabitants.
+  But the full significance of these extinct types of life could not be
+  understood so long as the doctrine of the immutability of species, so
+  strenuously upheld by Cuvier, maintained its sway among naturalists.
+  Lamarck, as far back as the year 1800, had begun to propound his
+  theory of evolution and the transformation of species; but his views,
+  strongly opposed by Cuvier and the great body of naturalists of the
+  day, fell into neglect. Not until after the publication in 1859 of the
+  _Origin of Species_ by Charles Darwin were the barriers of old
+  prejudice in this matter finally broken down. The possibility of
+  tracing the ancestry of living forms back into the remotest ages was
+  then perceived; the time-honoured fiction that the stratified
+  formations record a series of catastrophes and re-creations was
+  finally dissipated; and the earth's crust was seen to contain a noble,
+  though imperfect, record of the grand evolution of organic types of
+  which our planet has been the theatre.
+
+  _Development of Petrographical Geology._--Theophrastus, the favourite
+  pupil of Aristotle, wrote a treatise _On Stones_, which has come down
+  to our own day, and may be regarded as the earliest work on
+  petrography. At a subsequent period Pliny, in his _Natural History_,
+  collected all that was known in his day regarding the occurrence and
+  uses of minerals and rocks. But neither of these works is of great
+  scientific importance, though containing much interesting information.
+  Minerals from their beauty and value attracted notice before much
+  attention was paid to rocks, and their study gave rise to the science
+  of mineralogy long before geology came into existence. When rocks
+  began to be more particularly scrutinized, it was chiefly from the
+  side of their usefulness for building and other economic purposes. The
+  occurrence of marine shells in many of them had early attracted
+  attention to them. But their varieties of composition and origin did
+  not become the subject of serious study until after Linnaeus and J.G.
+  Wallerius in the 18th century had made a beginning. The first
+  important contribution to this department of the science was that of
+  Werner, who in 1786 published a classification and description of
+  rocks in which he arranged them in two divisions, simple and compound,
+  and further distinguished them by various external characters and by
+  their relative age. The publication of this scheme may be said to mark
+  the beginning of scientific petrography. Werner's system, however, had
+  the serious defect that the chronological order in which he grouped
+  the rocks, and the hypothesis by which he accounted for them as
+  chemical precipitates from the original ocean, were both alike
+  contrary to nature. It was hardly possible indeed that much progress
+  could be made in this branch of geology until chemistry and mineralogy
+  had made greater advances; and especially until it was possible to
+  ascertain the intimate chemical and mineralogical composition, and the
+  minute structure of rocks. The study, however, continued to be pursued
+  in Germany, where the influence of Werner's enthusiasm still led men
+  to enter the petrographical rather than the palaeontological domain.
+  The resources of modern chemistry were pressed into the service, and
+  analyses were made and multiplied to such a degree that it seemed as
+  if the ultimate chemical constitution of every type of rock had now
+  been thoroughly revealed. The condition of the science in the middle
+  of the 19th century was well shown by J.L.A. Roth, who in 1861
+  collected about 1000 trustworthy analyses which up to that time had
+  been made. But though the chemical elements of the rocks had been
+  fairly well determined, the manner in which they were combined in the
+  compound rocks could for the most part be only more or less plausibly
+  conjectured. As far back as 1831 an account was published of a process
+  devised by William Nicol of Edinburgh, whereby sections of fossil wood
+  could be cut, mounted on glass, and reduced to such a degree of
+  transparency as to be easily examined under a microscope. Henry Sorby,
+  of Sheffield, having seen Nicol's preparations, perceived how
+  admirably adapted the process was for the study of the minute
+  structure and composition of rocks. In 1858 he published in the
+  _Quarterly Journal of the Geological Society_ a paper "On the
+  Microscopical Structure of Crystals." This essay led to a complete
+  revolution of petrographical methods and gave a vast impetus to the
+  study of rocks. Petrology entered upon a new and wider field of
+  investigation. Not only were the mineralogical constituents of the
+  rocks detected, but minute structures were revealed which shed new
+  light on the origin and history of these mineral masses, and opened up
+  new paths in theoretical geology. In the hands of H. Vogelsang, F.
+  Zirkel, H. Rosenbusch, and a host of other workers in all civilized
+  countries, the literature of this department of the science has grown
+  to a remarkable extent. Armed with the powerful aid of modern optical
+  instruments, geologists are now able with far more prospect of success
+  to resume the experiments begun a century before by de Saussure and
+  Hall. G.A. Daubree, C. Friedel, E. Sarasin, F. Fouque and A. Michel
+  Levy in France, C. Doelter y Cisterich and E. Hussak of Gratz, J.
+  Morozewicz of Warsaw and others, have greatly advanced our knowledge
+  by their synthetical analyses, and there is every reason to hope that
+  further advances will be made in this field of research.
+
+  _Rise of Physiographical Geology._--Until stratigraphical geology had
+  advanced so far as to show of what a vast succession of rocks the
+  crust of the earth is built up, by what a long and complicated series
+  of revolutions these rocks have come to assume their present
+  positions, and how enormous has been the lapse of time which all these
+  changes represent, it was not possible to make a scientific study of
+  the surface features of our globe. From ancient times it had been
+  known that many parts of the land had once been under the sea; but
+  down even to the beginning of the 19th century the vaguest conceptions
+  continued to prevail as to the operations concerned in the submergence
+  and elevation of land, and as to the processes whereby the present
+  outlines of terrestrial topography were determined. We have seen, for
+  instance, that according to the teaching of Werner the oldest rocks
+  were first precipitated from solution in the universal ocean to form
+  the mountains, that the vertical position of their strata was
+  original, that as the waters subsided successive formations were
+  deposited and laid bare, and that finally the superfluous portion of
+  the ocean was whisked away into space by some unexplained co-operation
+  of another planetary body. Desmarest, in his investigation of the
+  volcanic history of Auvergne, was the first observer to perceive by
+  what a long process of sculpture the present configuration of the land
+  has been brought about. He showed conclusively that the valleys have
+  been carved out by the streams that flow in them, and that while they
+  have sunk deeper and deeper into the framework of the land, the spaces
+  of ground between them have been left as intervening ridges and hills.
+  De Saussure learnt a similar lesson from his studies of the Alps, and
+  Hutton and Playfair made it a cardinal feature in their theory of the
+  earth. Nevertheless the idea encountered so much opposition that it
+  made but little way until after the middle of the 19th century.
+  Geologists preferred to believe in convulsions of nature, whereby
+  valleys were opened and mountains were upheaved. That the main
+  features of the land, such as the great mountain-chains, had been
+  produced by gigantic plication of the terrestrial crust was now
+  generally admitted, and also that minor fractures and folds had
+  probably initiated many of the valleys. But those who realized most
+  vividly the momentous results achieved by ages of subaerial denudation
+  perceived that, as Hutton showed, even without the aid of underground
+  agency, the mere flow of water in streams across a mass of land must
+  in course of time carve out just such a system of valleys as may
+  anywhere be seen. It was J.B. Jukes who, in 1862, first revived the
+  Huttonian doctrine, and showed how completely it explained the
+  drainage-lines in the south of Ireland. Other writers followed in
+  quick succession until, in a few years, the doctrine came to be widely
+  recognized as one of the established principles of modern geology.
+  Much help was derived from the admirable illustrations of
+  land-sculpture and river-erosion supplied from the Western Territories
+  and States of the American Union.
+
+  Another branch of physiographical geology which could only come into
+  existence after most of the other departments of the science had made
+  large progress, deals with the evolution of the framework of each
+  country and of the several continents and oceans of the globe. It is
+  now possible, with more or less confidence, to trace backward the
+  history of every terrestrial area, to see how sea and land have there
+  succeeded each other, how rivers and lakes have come and gone, how the
+  crust of the earth has been ridged up at widely separated intervals,
+  each movement determining some line of mountains or plains, how the
+  boundaries of the oceans have shifted again and again in the past, and
+  thus how, after so prolonged a series of revolutions, the present
+  topography of each country, and of the globe as a whole, has been
+  produced. In the prosecution of this subject maps have been
+  constructed to show what is conjectured to have been the distribution
+  of sea and land during the various geological periods in different
+  parts of the world, and thus to indicate the successive stages through
+  which the architecture of the land has been gradually evolved. The
+  most noteworthy contribution to this department of the science is the
+  _Antlitz der Erde_ of Professor Suess of Vienna. This important and
+  suggestive work has been translated into French and English.
+
+
+PART II.--COSMICAL ASPECTS
+
+Before geology had attained to the position of an inductive science, it
+was customary to begin investigations into the history of the earth by
+propounding or adopting some more or less fanciful hypothesis in
+explanation of the origin of our planet, or even of the universe. Such
+preliminary notions were looked upon as essential to a right
+understanding of the manner in which the materials of the globe had been
+put together. One of the distinguishing features of Hutton's Theory of
+the Earth consisted in his protest that it is no part of the province of
+geology to discuss the origin of things. He taught that in the materials
+from which geological evidence is to be compiled there can be found "no
+traces of a beginning, no prospect of an end." In England, mainly to the
+influence of the school which he founded, and to the subsequent rise of
+the Geological Society of London, which resolved to collect facts
+instead of fighting over hypotheses, is due the disappearance of the
+crude and unscientific cosmologies by which the writings of the earlier
+geologists were distinguished.
+
+But there can now be little doubt that in the reaction against those
+visionary and often grotesque speculations, geologists were carried too
+far in an opposite direction. In allowing themselves to believe that
+geology had nothing to do with questions of cosmogony, they gradually
+grew up in the conviction that such questions could never be other than
+mere speculation, interesting or amusing as a theme for the employment
+of the fancy, but hardly coming within the domain of sober and inductive
+science. Nor would they soon have been awakened out of this belief by
+anything in their own science. It is still true that in the data with
+which they are accustomed to deal, as comprising the sum of geological
+evidence, there can be found no trace of a beginning, though the
+evidence furnished by the terrestrial crust shows a general evolution of
+organic forms from some starting-point which cannot be seen. The oldest
+rocks which have been discovered on any part of the globe have probably
+been derived from other rocks older than themselves. Geology by itself
+has not yet revealed, and is little likely ever to reveal, a trace of
+the first solid crust of our globe. If, then, geological history is to
+be compiled from direct evidence furnished by the rocks of the earth, it
+cannot begin at the beginning of things, but must be content to date
+its first chapter from the earliest period of which any record has been
+preserved among the rocks.
+
+Nevertheless, though geology in its usual restricted sense has been, and
+must ever be, unable to reveal the earliest history of our planet, it no
+longer ignores, as mere speculation, what is attempted in this subject
+by its sister sciences. Astronomy, physics and chemistry have in late
+years all contributed to cast light on the earlier stages of the earth's
+existence, previous to the beginning of what is commonly regarded as
+geological history. But whatever extends our knowledge of the former
+conditions of our globe may be legitimately claimed as part of the
+domain of geology. If this branch of inquiry, therefore, is to continue
+worthy of its name as the science of the earth, it must take cognizance
+of these recent contributions from other sciences. It must no longer be
+content to begin its annals with the records of the oldest rocks, but
+must endeavour to grope its way through the ages which preceded the
+formation of any rocks. Thanks to the results achieved with the
+telescope, the spectroscope and the chemical laboratory, the story of
+these earliest ages of our earth is every year becoming more definite
+and intelligible.
+
+Up to the present time no definite light has been thrown by physics on
+the origin and earliest condition of our globe. The famous nebular
+theory (q.v.) of Kant and Laplace sketched the supposed evolution of the
+solar system from a gaseous nebula, slowly rotating round a more
+condensed central portion of its mass, which eventually became the sun.
+As a consequence of increased rapidity of rotation resulting from
+cooling and contraction, the nebula acquired a more and more lenticular
+form, until at last it threw off from its equatorial protuberance a ring
+of matter. Subsequently the same process was repeated, and other similar
+rings successively separated from the parent mass. Each ring went
+through a corresponding series of changes until it ultimately became a
+planet, with or without one or more attendant satellites. The intimate
+relationship of our earth to the sun and the other planets was, in this
+way, shown. But there are some serious physical difficulties in the way
+of the acceptance of the nebular hypothesis. Another explanation is
+given by the meteoritic hypothesis, according to which, out of the
+swarms of meteorites with which the regions of space are crowded, the
+sun and planets have been formed by gradual accretion.
+
+According to these theoretical views we should expect to find a general
+uniformity of composition in the constituent matter of the solar system.
+For many years the only available evidence on this point was derived
+from the meteorites (q.v.) which so constantly fall from outer space
+upon the surface of the earth. These bodies were found to consist of
+elements, all of which had been recognized as entering into the
+constitution of the earth. But the discoveries of spectroscopic research
+have made known a far more widely serviceable method of investigation,
+which can be applied even to the luminous stars and nebulae that lie far
+beyond the bounds of the solar system. By this method information has
+been obtained regarding the constitution of the sun, and many of our
+terrestrial metals, such as iron, nickel and magnesium, have been
+ascertained to exist in the form of incandescent vapour in the solar
+atmosphere. The present condition of the sun probably represents one of
+the phases through which stars and planets pass in their progress
+towards becoming cool and dark bodies in space. If our globe was at
+first, like its parent sun, an incandescent mass of probably gaseous
+matter, occupying much more space than it now fills, we can conceive
+that it has ever since been cooling and contracting until it has reached
+its present form and dimensions, and that it still retains a high
+internal temperature. Its oblately spheroidal form is such as would be
+assumed by a rotating mass of matter in the transition from a vaporous
+and self-luminous or liquid condition to one of cool and dark solidity.
+But it has been claimed that even a solid spherical globe might develop,
+under the influence of protracted rotation, such a shape as the earth at
+present possesses.
+
+The observed increase of temperature downwards in our planet has
+hitherto been generally accepted as a relic and proof of an original
+high temperature and mobility of substance. Recently, however, the
+validity of this proof has been challenged on the ground that the
+ascertained amount of radium in the rocks of the outer crust is more
+than sufficient to account for the observed downward increase of
+temperature. Too little, however, is known of the history and properties
+of what is called radium to afford a satisfactory ground on which to
+discard what has been, and still remains, the prevalent belief on this
+subject.
+
+An important epoch in the geological history of the earth was marked by
+the separation of the moon from its mass (see TIDE). Whether the
+severance arose from the rupture of a surrounding ring or the gradual
+condensation of matter in such a ring, or from the ejection of a single
+mass of matter from the rapidly rotating planet, it has been shown that
+our satellite was only a few thousand miles from the earth's surface,
+since when it has retreated to its present distance of 240,000 m. Hence
+the influence of the moon's attraction, and all the geological effects
+to which it gives rise, attained their maximum far back in the
+development of the globe, and have been slowly diminishing throughout
+geological history.
+
+The sun by virtue of its vast size has not yet passed out of the
+condition of glowing gas, and still continues to radiate heat beyond the
+farthest planet of the solar system. The earth, however, being so small
+a body in comparison, would cool down much more quickly. Underneath its
+hot atmosphere a crust would conceivably begin to form over its molten
+surface, though the interior might still possess a high temperature and,
+owing to the feeble conducting power of rocks, would remain intensely
+hot for a protracted series of ages.
+
+Full information regarding the form and size of the earth, and its
+relations to the other planetary members of the solar system, will be
+found in the articles PLANET and SOLAR SYSTEM. For the purposes of
+geological inquiry the reader will bear in mind that the equatorial
+diameter of our globe is estimated to be about 7925 m., and the polar
+diameter about 7899 m.; the difference between these two sums
+representing the amount of flattening at the poles (about 26-1/2 m.).
+The planet has been compared in shape to an orange, but it resembles an
+orange which has been somewhat squeezed, for its equatorial
+circumference is not a regular circle but an ellipse, of which the major
+axis lies in long. 8 deg. 15' W.--on a meridian which cuts the
+north-west corner of America, passing through Portugal and Ireland, and
+the north-east corner of Asia in the opposite hemisphere.
+
+The rotation of the earth on its axis exerts an important influence on
+the movements of the atmosphere, and thereby affects the geological
+operations connected with these movements. The influence of rotation is
+most marked in the great aerial circulation between the poles and the
+equator. Currents of air, which set out in a meridional direction from
+high latitudes towards the equator, come from regions where the velocity
+due to rotation is small to where it is greater, and they consequently
+fall behind. Thus, in the northern hemisphere a north wind, as it moves
+away from its northern source of origin, is gradually deflected more and
+more towards the west and becomes a north-east current; while in the
+opposite hemisphere a wind making from high southern latitudes towards
+the equator becomes, from the same cause, a south-east current. Where,
+on the other hand, the air moves from the equatorial to the polar
+regions its higher velocity of rotation carries it eastward, so that on
+the south side of the equator it becomes a north-west current and on the
+north side a south-west current. It is to this cause that the easting
+and westing of the great atmospheric currents are to be attributed, as
+is familiarly exemplified in the trade winds.
+
+The atmospheric circulation thus deflected influences the circulation of
+the ocean. The winds which persistently blow from the north-east on the
+north side of the equator, and from the south-east on the south side,
+drive the superficial waters onwards, and give rise to converging
+oceanic currents which unite to form the great westerly equatorial
+current.
+
+A more direct effect of terrestrial rotation has been claimed in the
+case of rivers which flow in a meridional direction. It has been
+asserted that those, which in the northern hemisphere flow from north to
+south, like the Volga, by continually passing into regions where the
+velocity of rotation is increasingly greater, are thrown more against
+their western than their eastern banks, while those whose general course
+is in an opposite direction, like the Irtisch and Yenesei, press more
+upon their eastern sides. There cannot be any doubt that the tendency of
+the streams must be in the directions indicated. But when the
+comparatively slow current and constantly meandering course of most
+rivers are taken into consideration, it may be doubted whether the
+influence of rotation is of much practical account so far as
+river-erosion is concerned.
+
+One of the cosmical relations of our planet which has been more
+especially prominent in geological speculations relates to the position
+of the earth's axis of rotation. Abundant evidence has now been obtained
+to prove that at a comparatively late geological period a rich flora,
+resembling that of warm climates at the present day, existed in high
+latitudes even within less than 9 deg. of the north pole, where, with an
+extremely low temperature and darkness lasting for half of the year, no
+such vegetation could possibly now exist. It has accordingly been
+maintained by many geologists that the axis of rotation must have
+shifted, and that when the remarkable Arctic assemblage of fossil plants
+lived the region of their growth must have lain in latitudes much nearer
+to the equator of the time.
+
+The possibility of any serious displacement of the rotational axis since
+a very early period in the earth's history has been strenuously denied
+by astronomers, and their arguments have been generally, but somewhat
+reluctantly, accepted by geologists, who find themselves confronted with
+a problem which has hitherto seemed insoluble. That the axis is not
+rigidly stable, however, has been postulated by some physicists, and has
+now been demonstrated by actual observation and measurement. It is
+admitted that by the movement of large bodies of water the air over the
+surface of the globe, and more particularly by the accumulation of vast
+masses of snow and ice in different regions, the position of the axis
+might be to some extent shifted; more serious effects might follow from
+widespread upheavals or depressions of the surface of the lithosphere.
+On the assumption of the extreme rigidity of the earth's interior,
+however, the general result of mathematical calculation is to negative
+the supposition that in any of these ways within the period represented
+by what is known as the "geological record," that is, since the time of
+the oldest known sedimentary formations, the rotational axis has ever
+been so seriously displaced as to account for such stupendous geological
+events as the spread of a luxuriant vegetation far up into polar
+latitudes. If, however, the inside of the globe possesses a great
+plasticity than has been allowed, the shifting of the axis might not be
+impossible, even to such an extent as would satisfy the geological
+requirements. This question is one on which the last word has not been
+said, and regarding which judgment must remain in suspense.
+
+In recent years fresh information bearing on the minor devagations of
+the pole has been obtained from a series of several thousand careful
+observations made in Europe and North America. It has thus been
+ascertained that the pole wanders with a curiously irregular but
+somewhat spiral movement, within an amplitude of between 40 and 50 ft.,
+and completes its erratic circuit in about 428 days. It was not supposed
+that its movement had any geological interest, but Dr John Milne has
+recently pointed out that the times of sharpest curvature in the path of
+the pole coincide with the occurrence of large earthquakes, and has
+suggested that, although it can hardly be assumed that this coincidence
+shows any direct connexion between earthquake frequency and changes in
+the position of the earth's axis, both effects may not improbably arise
+from the same redistribution of surface material by ocean currents and
+meteorological causes.
+
+If for any reason the earth's centre of gravity were sensibly displaced,
+momentous geological changes would necessarily ensue. That the centre of
+gravity does not coincide with the centre of figure of the globe, but
+lies to the south of it, has long been known. This greater aggregation
+of dense material in the southern hemisphere probably dates from the
+early ages of the earth's consolidation, and it is difficult to believe
+that any readjustment of the distribution of this material in the
+earth's interior is now possible. But certain rearrangements of the
+hydrosphere on the surface of the globe may, from time to time, cause a
+shifting of the centre of gravity, which will affect the level of the
+ocean. The accumulation of enormous masses of ice around the pole will
+give rise to such a displacement, and will thus increase the body of
+oceanic water in the glaciated hemisphere. Various calculations have
+been made of the effect of the transference of the ice-cap from one pole
+to the other, a revolution which may possibly have occurred more than
+once in the past history of the globe. James Croll estimated that if the
+mass of ice in the southern hemisphere be assumed to be 1000 ft. thick
+down to lat. 60 deg., its removal to the opposite hemisphere would raise
+the level of the sea 80 ft. at the north pole, while the Rev. Osmond
+Fisher made the rise as much as 409 ft. The melting of the ice would
+still further raise the sea-level by the addition of so large a volume
+of water to the ocean. To what extent superficial changes of this kind
+have operated in geological history remains an unsolved problem, but
+their probable occurrence in the past has to be recognized as one of the
+factors that must be considered in tracing the revolutions of the
+earth's surface.
+
+_The Age of the Earth._--Intimately connected with the relations of our
+globe to the sun and the other members of the solar system is the
+question of the planet's antiquity--a subject of great geological
+importance, regarding which much discussion has taken place since the
+middle of the 19th century. Though an account of this discussion
+necessarily involves allusion to departments of geology which are more
+appropriately referred to in later parts of this article, it may perhaps
+be most conveniently included here.
+
+Geologists were for many years in the habit of believing that no limit
+could be assigned to the antiquity of the planet, and that they were at
+liberty to make unlimited drafts on the ages of the past. In 1862 and
+subsequent years, however, Lord Kelvin (then Sir William Thomson)
+pointed out that these demands were opposed to known physical facts, and
+that the amount of time required for geological history was not only
+limited, but must have been comprised within a comparatively narrow
+compass. His argument rested on three kinds of evidence: (1) the
+internal heat and rate of cooling of the earth; (2) the tidal
+retardation of the earth's rotation; and (3) the origin and age of the
+sun's heat.
+
+1. Applying Fourier's theory of thermal conductivity, Lord Kelvin
+contended that in the known rate of increase of temperature downward and
+beneath the surface, and the rate of loss of heat from the earth, we
+have a limit to the antiquity of the planet. He showed, from the data
+available at the time, that the superficial consolidation of the globe
+could not have occurred less than 20 million years ago, or the
+underground heat would have been greater than it is; nor more than 400
+million years ago, otherwise the underground temperature would have
+shown no sensible increase downwards. He admitted that very wide limits
+were necessary. In subsequently discussing the subject, he inclined
+rather towards the lower than the higher antiquity, but concluded that
+the limit, from a consideration of all the evidence, must be placed
+within some such period of past time as 100 millions of years.
+
+2. The argument from tidal retardation proceeds on the admitted fact
+that, owing to the friction of the tide-wave, the rotation of the earth
+is retarded, and is, therefore, much slower now than it must have been
+at one time. Lord Kelvin affirmed that had the globe become solid some
+10,000 million years ago, or indeed any high antiquity beyond 100
+million years, the centrifugal force due to the more rapid rotation must
+have given the planet a very much greater polar flattening than it
+actually possesses. He admitted, however, that, though 100 million years
+ago that force must have been about 3% greater than now, yet "nothing
+we know regarding the figure of the earth, and the disposition of land
+and water, would justify us in saying that a body consolidated when
+there was more centrifugal force by 3% than now, might not now be in all
+respects like the earth, so far as we know it at present."
+
+3. The third argument, based upon the age of the sun's heat, is
+confessedly less to be relied on than the two previous ones. It proceeds
+upon calculations as to the amount of heat which would be available by
+the falling together of masses from space, which gave rise by their
+impact to our sun. The vagueness of the data on which this argument
+rests may be inferred from the fact that in one passage P.G. Tait placed
+the limit of time during which the sun has been illuminating the earth
+as, "on the very highest computation, not more than about 15 or 20
+millions of years"; while, in another sentence of the same volume, he
+admitted that, "by calculations in which there is no possibility of
+large error, this hypothesis [of the origin of the sun's heat by the
+falling together of masses of matter] is thoroughly competent to explain
+100 millions of years' solar radiation at the present rate, perhaps
+more." In more recently reviewing his argument, Lord Kelvin expressed
+himself in favour of more strictly limiting geological time than he had
+at first been disposed to do. He insists that the time "was more than 20
+and less than 40 millions of years and probably much nearer 20 than 40."
+Geologists appear to have reluctantly brought themselves to believe that
+perhaps, after all, 100 millions of years might suffice for the
+evolution of geological history. But when the time was cut down to 15 or
+20 millions they protested that such a restricted period was
+insufficient for that evolution, and though they did not offer any
+effective criticism of the arguments of the physicists they felt
+convinced that there must be some flaw in the premises on which these
+arguments were based.
+
+By degrees, however, there have arisen among the physicists themselves
+grave doubts as to the validity of the physical evidence on which the
+limitation of the earth's age has been founded, and at the same time
+greater appreciation has been shown of the signification and strength of
+the geological proofs of the high antiquity of our planet. In an address
+from the chair of the Mathematical Section of the British Association in
+1886, Professor (afterwards Sir) George Darwin reviewed the controversy,
+and pronounced the following deliberate judgment in regard to it: "In
+considering these three arguments I have adduced some reasons against
+the validity of the first [tidal friction], and have endeavoured to show
+that there are elements of uncertainty surrounding the second [secular
+cooling of the earth]; nevertheless, they undoubtedly constitute a
+contribution of the first importance to physical geology. Whilst, then,
+we may protest against the precision with which Professor Tait seeks to
+deduce results from them, we are fully justified in following Sir
+William Thomson, who says that 'the existing state of things on the
+earth, life on the earth--all geological history showing continuity of
+life--must be limited within some such period of past time as 100
+million years'." Lord Kelvin has never dealt with the geological and
+palaeontological objections against the limitation of geological time to
+a few millions of years. But Professor Darwin, in the address just
+cited, uttered the memorable warning: "At present our knowledge of a
+definite limit to geological time has so little precision that we should
+do wrong summarily to reject theories which appear to demand longer
+periods of time than those which now appear allowable." In his
+presidential address to the British Association at Cape Town in 1905 he
+returned to the subject, remarking that the argument derived from the
+increase of underground temperature "seems to be entirely destroyed" by
+the discovery of the properties of radium. He thinks that "it does not
+seem extravagant to suppose that 500 to 1000 million years may have
+elapsed since the birth of the moon." He has "always believed that the
+geologists were more nearly correct than the physicists, notwithstanding
+the fact that appearances were so strongly against them," and he
+concludes thus: "It appears, then, that the physical argument is not
+susceptible of a greater degree of certainty than that of the
+geologists, and the scale of geological time remains in great measure
+unknown" (see also Tide, chap. viii.).
+
+In an address to the mathematical section of the American Association
+for the Advancement of Science in 1889, the vice-president of the
+section, R.S. Woodward, thus expressed himself with regard to the
+physical arguments brought forward by Lord Kelvin and Professor Tait in
+limitation of geological time: "Having been at some pains to look into
+this matter, I feel bound to state that, although the hypothesis appears
+to be the best which can be formulated at present, the odds are against
+its correctness. Its weak links are the unverified assumptions of an
+initial uniform temperature and a constant diffusivity. Very likely
+these are approximations, but of what order we cannot decide.
+Furthermore, if we accept the hypothesis, the odds appear to be against
+the present attainment of trustworthy numerical results, since the data
+for calculation, obtained mostly from observations on continental areas,
+are far too meagre to give satisfactory average values for the entire
+mass of the earth."
+
+Still more emphatic is the protest made from the physical side by
+Professor John Perry. He has attacked each of the three lines of
+argument of Lord Kelvin, and has impugned the validity of the
+conclusions drawn from them. The argument from tidal retardation he
+dismisses as fallacious, following in this contention the previous
+criticism of the Rev. Maxwell Close and Sir George Darwin. In dealing
+with the argument based on the secular cooling of the earth, he holds it
+to be perfectly allowable to assume a much higher conductivity for the
+interior of the globe, and that such a reasonable assumption would
+enable us greatly to increase our estimate of the earth's antiquity. As
+for the third argument, from the age of the sun's heat, he points out
+that the sun may have been repeatedly fed by a supply of meteorites from
+outside, while the earth may have been protected from radiation, and
+been able to retain much of its heat by being enveloped in a dense
+atmosphere. Remarking that "almost anything is possible as to the
+present internal state of the earth," he concludes thus: "To sum up, we
+can find no published record of any lower maximum age of life on the
+earth, as calculated by physicists, than 400 millions of years. From the
+three physical arguments Lord Kelvin's higher limits are 1000, 400 and
+500 million years. I have shown that we have reasons for believing that
+the age, from all these, may be very considerably underestimated. It is
+to be observed that if we exclude everything but the arguments from mere
+physics, the _probable_ age of life on the earth is much less than any
+of the above estimates; but if the palaeontologists have good reasons
+for demanding much greater times, I see nothing from the physicists'
+point of view which denies them four times the greatest of these
+estimates."
+
+A fresh line of argument against Lord Kelvin's limitation of the
+antiquity of our globe has recently been started by the remarkable
+discoveries in radio-activity. From the ascertained properties of radium
+it appears to be possible that our estimates of solar heat, as derived
+from the theory of gravitation, may have to be augmented ten or twenty
+times; that stores of radium and similar bodies within the earth may
+have indefinitely deferred the establishment of the present temperature
+gradient from the surface inward; that consequently the earth may have
+remained for long ages at a temperature not greatly different from that
+which it now possesses, and hence that the times during which our globe
+has supported animal and vegetable life may be very much longer than
+that allowed in the estimates previously made by physicists from other
+data (see RADIOACTIVITY).
+
+The arguments from the geological side against the physical contention
+that would limit the age of our globe to some 10 or 20 millions of years
+are mainly based on the observed rates of geological and biological
+changes at the present time upon land and sea, and on the nature,
+physical history and organic contents of the stratified crust of the
+earth. Unfortunately, actual numerical data are not obtainable in many
+departments of geological activity, and even where they can be procured
+they do not yet rest on a sufficiently wide collection of accurate and
+co-ordinated observations. But in some branches of dynamical geology,
+material exists for, at least, a preliminary computation of the rate of
+change. This is more especially the case in respect of the wide domain
+of denudation. The observational records of the action of the sea, of
+springs, rivers and glaciers are becoming gradually fuller and more
+trustworthy. A method of making use of these records for estimating the
+rate of denudation of the land has been devised. Taking the Mississippi
+as a general type of river action, it has been shown that the amount of
+material conveyed by this stream into the sea in one year is equivalent
+to the lowering of the general surface of the drainage basin of the
+river by 1/6000 of a foot. This would amount to one foot in 6000 years
+and 1000 ft. in 6 million years. So that at the present rate of waste in
+the Mississippi basin a whole continent might be worn away in a few
+millions of years.
+
+It is evident that as deposition and denudation are simultaneous
+processes, the ascertainment of the rate at which solid material is
+removed from the surface of the land supplies some necessary information
+for estimating the rate at which new sedimentary formations are being
+accumulated on the floor of the sea, and for a computation of the length
+of time that would be required at the present rate of change for the
+deposition of all the stratified rocks that enter into the composition
+of the crust of our globe. If the thickness of these rocks be assumed to
+be 100,000 ft., and if we could suppose them to have been laid down over
+as wide an area as that of the drainage basins from the waste of which
+they were derived, then at the present rate of denudation their
+accumulation would require some 600 millions of years. But, as Dr A.R.
+Wallace has justly pointed out, the tract of sea-floor over which the
+material derived from the waste of the terrestrial surface is laid down
+is at present much less than that from which this material is worn away.
+We have no means, however, of determining what may have been the ratio
+between the two areas in past time. Certainly ancient marine sedimentary
+rocks cover at the present day a much more extensive area than that in
+which they are now being elaborated. If we take the ratio postulated by
+Dr Wallace--1 to 19--the 100,000 ft. of sedimentary strata would require
+31 millions of years for their accumulation. It is quite possible,
+however, that this ratio may be much too high. There are reasons for
+believing that the proportion of coast-line to land area has been
+diminishing during geological time; in other words, that in early times
+the land was more insular and is now more continental. So that the 31
+millions of years may be much less than the period that would be
+required, even on the supposition of continuous uninterrupted denudation
+and sedimentation, during the whole of the time represented by the
+stratified formations.
+
+But no one who has made himself familiar with the actual composition of
+these formations and the detailed structure of the terrestrial crust can
+fail to recognize how vague, imperfect and misleading are the data on
+which such computations are founded. It requires no prolonged
+acquaintance with the earth's crust to impress upon the mind that one
+all-important element is omitted, and indeed can hardly be allowed for
+from want of sufficiently precise data, but the neglect of which must
+needs seriously impair the value of all numerical calculations made
+without it. The assumption that the stratified formations can be treated
+as if they consisted of a continuous unbroken sequence of sediments,
+indicating a vast and uninterrupted process of waste and deposition, is
+one that is belied on every hand by the actual structure of these
+formations. It can only give us a minimum of the time required; for,
+instead of an unbroken series, the sedimentary formations are full of
+"unconformabilities"--gaps in the sequence of the chronological
+records--as if whole chapters and groups of chapters had been torn out
+of a historical work. It can often be shown that these breaks of
+continuity must have been of vast duration, and actually exceeded in
+chronological importance thick groups of strata lying below and above
+them (see Part VI.). Moreover, even among the uninterrupted strata,
+where no such unconformabilities exist, but where the sediments follow
+each other in apparently uninterrupted sequence, and might be thought to
+have been deposited continuously at the same general rate, and without
+the intervention of any pause, it can be demonstrated that sometimes an
+inch or two of sediment might, on certain horizons, represent the
+deposit of an enormously longer period than a hundred or a thousand
+times the same amount of sediment on other horizons. A prolonged study
+of these questions leads to a profound conviction that in many parts of
+the geological record the time represented by sedimentary deposits may
+be vastly less than the time which is not so represented.
+
+It has often been objected that the present rate of geological change
+ought not to be taken as a measure of the rate in past time, because the
+total sum of terrestrial energy has been steadily diminishing, and
+geological processes must consequently have been more vigorous in former
+ages than they are now. Geologists do not pretend to assert that there
+has been no variation or diminution in the activities of the various
+processes which they have to study. What they do insist on is that the
+present rate of change is the only one which we can watch and measure,
+and which will thus supply a statistical basis for any computations on
+the subject. But it has been dogmatically affirmed that because
+terrestrial energy has been diminishing therefore all kinds of
+geological work must have been more vigorously and more rapidly carried
+on in former times than now; that there were far more abundant and more
+stupendous volcanoes, more frequent and more destructive earthquakes,
+more gigantic upheavals and subsidences, more powerful oceanic waves and
+tides, more violent atmospheric disturbances with heavier rainfall and
+more active denudation.
+
+It is easy to make these assertions, and they look plausible; but, after
+all, they rest on nothing stronger than assumption. They can be tested
+by an appeal to the crust of the earth, in which the geological history
+of our planet has been so fully recorded. Had such portentous
+manifestations of geological activity ever been the normal condition of
+things since the beginning of that history, there ought to be a record
+of them in the rocks. But no evidence for them has been found there,
+though it has been diligently sought for in all quarters of the globe.
+We may confidently assert that while geological changes may quite
+possibly have taken place on a gigantic scale in the earliest ages of
+the earth's existence, of which no geological record remains, there is
+no proof that they have ever done so since the time when the very oldest
+of the stratified formations were deposited. There is no need to
+maintain that they have always been conducted precisely on the same
+scale as now, or to deny that they may have gradually become less
+vigorous as the general sum of terrestrial energy has diminished. But we
+may unhesitatingly affirm that no actual evidence of any such
+progressive diminution of activity has been adduced from the geological
+record in the crust of the earth: that, on the contrary, no appearances
+have been detected there which necessarily demand the assumption of
+those more powerful operations postulated by physicists, or which are
+not satisfactorily explicable by reference to the existing scale of
+nature's processes.
+
+That this conclusion is warranted even with regard to the innate energy
+of the globe itself will be seen if we institute a comparison between
+the more ancient and the more recent manifestations of that energy.
+Take, for example, the proofs of gigantic plication, fracture and
+displacement within the terrestrial crust. These, as they have affected
+the most ancient rocks of Europe, have been worked out in great detail
+in the north-west of Scotland. But they are not essentially different
+from or on a greater scale than those which have been proved to have
+affected the Alps, and to have involved strata of so recent a date as
+the older Tertiary formations. On the contrary, it may be doubted
+whether any denuded core of an ancient mountain-chain reveals traces of
+such stupendous disturbances of the crust as those which have given rise
+to the younger mountain-chains of the globe. It may, indeed, quite well
+have been the rule that instead of diminishing in intensity of effect,
+the consequences of terrestrial contraction have increased in magnitude,
+the augmenting thickness of the crust offering greater resistance to
+the stresses, and giving rise to vaster plications, faults,
+thrust-planes and metamorphism, as this growing resistance had to be
+overcome.
+
+The assertion that volcanic action must have been more violent and more
+persistent in ancient times than it is now has assuredly no geological
+evidence in its support. It is quite true that there are vastly more
+remains of former volcanoes scattered over the surface of the globe than
+there are active craters now, and that traces of copious eruptions of
+volcanic material can be followed back into some of the oldest parts of
+the geological record. But we have no proof that ever at any one time in
+geological history there have been more or larger or more vigorous
+volcanoes than those of recent periods. It may be said that the absence
+of such proof ought not to invalidate the assertion until a far wider
+area of the earth's surface has been geologically studied. But most
+assuredly, as far as geological investigation has yet gone, there is an
+overwhelming body of evidence to show that from the earliest epochs in
+geological history, as registered in the stratified rocks, volcanic
+action has manifested itself very much as it does now, but on a less
+rather than on a greater scale. Nowhere can this subject be more
+exhaustively studied than in the British Isles, where a remarkably
+complete series of volcanic eruptions has been chronicled ranging from
+the earliest Palaeozoic down to older Tertiary time. The result of a
+prolonged study of British volcanic geology has demonstrated that, even
+to minute points of detail, there has been a singular uniformity in the
+phenomena from beginning to end. The oldest lavas and ashes differ in no
+essential respect from the youngest. Nor have they been erupted more
+copiously or more frequently. Many successive volcanic periods have
+followed each other after prolonged intervals of repose, each displaying
+the same general sequence of phenomena and similar evidence of gradual
+diminution and extinction. The youngest, instead of being the feeblest,
+were the most extensive outbursts in the whole of this prolonged series.
+
+If now we turn for evidence of the alleged greater activity of all the
+epigene or superficial forces, and especially for proofs of more rapid
+denudation and deposition on the earth's surface, we search for it in
+vain among the stratified formations of the terrestrial crust. Had the
+oldest of these rocks been accumulated in a time of great atmospheric
+perturbation, of torrential rains, colossal tides and violent storms, we
+might surely expect to find among the sediments some proof of such
+disturbed meteorological and geographical conditions. We should look, on
+the one hand, for tumultuous accumulations of coarse unworn detritus,
+rapidly swept by rains, floods and waves from land to sea, and on the
+other hand, for an absence of any evidence of the tranquil and
+continuous deposit of such fine laminated silt as could only settle in
+quiet water. But an appeal to the geological record is made in vain for
+any such proofs. The oldest sediments, like the youngest, reveal the
+operation only of such agents and such rates of activity as are still to
+be witnessed in the accumulation of the same kind of deposits. If, for
+instance, we search the most ancient thick sedimentary formation in
+Britain--the Torridon Sandstone of north-west Scotland, which is older
+than the oldest fossiliferous deposits--we meet with nothing which might
+not be found in any Palaeozoic, Mesozoic or Cainozoic group of similar
+sediments. We see an accumulation, at least 8000 or 10,000 ft. thick, of
+consolidated sand, gravel and mud, such as may be gathering now on the
+floor of any large mountain-girdled lake. The conglomerates of this
+ancient series are not pell-mell heaps of angular detritus, violently
+swept away from the land and huddled promiscuously on the sea-floor.
+They are, in general, built up of pebbles that have been worn smooth,
+rounded and polished by prolonged attrition in running water, and they
+follow each other on successive platforms with intervening layers of
+finer sediment. The sandstones are composed of well water-worn sand,
+some of which has been laid down so tranquilly that its component grains
+have been separated out in layers according to their specific gravity,
+in such manner that they now present dark laminae in which particles of
+magnetic iron, zircon and other heavy minerals have been sifted out
+together, just as iron-sand may be seen gathered into thin sheets on
+sandy beaches at the present day. Again, the same series of primeval
+sediments includes intercalations of fine silt, which has been deposited
+as regularly and intermittently there as it has been among the most
+recent formations. These bands of shale have been diligently searched
+for fossils, as yet without success; but they may eventually disclose
+organic remains older than any hitherto found in Europe.
+
+We now come to the consideration of the palaeontological evidence as to
+the value of geological time. Here the conclusions derived from a study
+of the structure of the sedimentary formations are vastly strengthened
+and extended. In the first place, the organization of the most ancient
+plants and animals furnishes no indication that they had to contend with
+any greater violence of storm, flood, wave or ocean-current than is
+familiar to their modern descendants. The oldest trees, shrubs, ferns
+and club-mosses display no special structures that suggest a difference
+in the general conditions of their environment. The most ancient
+crinoids, sponges, crustaceans, arachnids and molluscs were as
+delicately constructed as those of to-day, and their remains are often
+found in such perfect preservation as to show that neither during their
+lifetime nor after their death were they subject to any greater violence
+of the elements than their living representatives now experience. Of
+much more cogency, however, is the evidence supplied by the grand upward
+succession of organic forms, from the most ancient stratified rocks up
+to the present day. No biologist now doubts for a moment that this
+marvellous succession is the result of a gradual process of evolution
+from lower to higher types of organization. There may be differences of
+opinion as to the causes which have governed this process and the order
+of the steps through which it has advanced, but no one who is conversant
+with the facts will now venture to deny that it has taken place, and
+that, on any possible explanation of its progress, it must have demanded
+an enormous lapse of time. In the Cambrian or oldest fossiliferous
+formations there is already a large and varied fauna, in which the
+leading groups of invertebrate life are represented. On no tenable
+hypothesis can these be regarded as the first organisms that came into
+being on our planet. They must have had a long ancestry, and as Darwin
+first maintained, the time required for their evolution may have been
+"as long as, or probably far longer than, the whole interval from the
+Silurian [Cambrian] age to the present day." The records of these
+earliest eras of organic development have unfortunately not survived the
+geological revolutions of the past; at least, they have not yet been
+recovered. But it cannot be doubted that they once existed and
+registered their testimony to the prodigious lapse of time prior to the
+deposition of the most ancient fossiliferous formations which have
+escaped destruction.
+
+The impressive character of the evidence furnished by the sequence of
+organic forms throughout the great series of fossiliferous strata can
+hardly be fully realized without a detailed and careful study of the
+subject. Professor E.B. Poulton, in an address to the zoological section
+of the British Association at the Liverpool Meeting in 1896, showed how
+overwhelming are the demands which this evidence makes for long periods
+of time, and how impossible it is of comprehension unless these demands
+be conceded. The history of life upon the earth, though it will probably
+always be surrounded with great and even insuperable difficulties,
+becomes broadly comprehensible in its general progress when sufficient
+time is granted for the evolution which it records; but it remains
+unintelligible on any other conditions.
+
+Taken then as a whole, the body of evidence, geological and
+palaeontological, in favour of the high antiquity of our globe is so
+great, so manifold, and based on such an ever-increasing breadth of
+observation and reflection, that it may be confidently appealed to in
+answer to the physical arguments which would seek to limit that
+antiquity to ten or twenty millions of years. In the present state of
+science it is out of our power to state positively what must be the
+lowest limit of the age of the earth. But we cannot assume it to be much
+less, and it may possibly have been much more, than the 100 millions of
+years which Lord Kelvin was at one time willing to concede.[2]
+
+
+PART III.--GEOGNOSY. THE INVESTIGATION OF THE NATURE AND COMPOSITION OF
+THE MATERIALS OF WHICH THE EARTH CONSISTS
+
+This division of the science is devoted to a description of the parts of
+the earth--of the atmosphere and ocean that surround the planet, and
+more especially of the solid materials that underlie these envelopes and
+extend downwards to an unknown distance into the interior. These various
+constituents of the globe are here considered as forms of matter capable
+of being analysed, and arranged according to their composition and the
+place they take in the general composition of the globe.
+
+Viewed in the simplest way the earth may be regarded as made up of three
+distinct parts, each of which ever since an early period of planetary
+history has been the theatre of important geological operations. (1) An
+envelope of air, termed the _atmosphere_, which surrounds the whole
+globe; (2) A lower and less extensive envelope of water, known as the
+_hydrosphere_ (Gr. [Greek: hydor], water) which, constituting the oceans
+and seas, covers nearly three-fourths of the underlying solid surface of
+the planet; (3) A globe, called the _lithosphere_ (Gr. [Greek: lithos],
+stone), the external part of which, consisting of solid stone, forms the
+_crust_, while underneath, and forming the vast mass of the interior,
+lies the _nucleus_, regarding the true constitution of which we are
+still ignorant.
+
+1. _The Atmosphere._--The general characters of the atmosphere are
+described in separate articles (see especially ATMOSPHERE; METEOROLOGY).
+Only its relations to geology have here to be considered. As this
+gaseous envelope encircles the whole globe it is the most universally
+present and active of all the agents of geological change. Its efficacy
+in this respect arises partly from its composition, and the chemical
+reactions which it effects upon the surface of the land, partly from its
+great variations in temperature and moisture, and partly from its
+movements.
+
+  Many speculations have been made regarding the chemical composition of
+  the atmosphere during former geological periods. There can indeed be
+  little doubt that it must originally have differed greatly from its
+  present condition. If the whole mass of the planet originally existed
+  in a gaseous state, there would be practically no atmosphere. The
+  present outer envelope of air may be considered to be the surviving
+  relic of this condition, after all the other constituents have been
+  incorporated into the hydrosphere and lithosphere. The oxygen, which
+  now forms fully a half of the outer crust of the earth, was doubtless
+  originally, whether free or in combination, part of the atmosphere.
+  So, too, the vast beds of coal found all over the world, in geological
+  formations of many different ages, represent so much carbonic acid
+  once present in the air. The chlorides and other salts in the sea may
+  likewise partly represent materials carried down out of the atmosphere
+  in the primitive condensation of the aqueous vapour, though they have
+  been continually increased ever since by contributions from the
+  drainage of the land. It has often been suggested that, during the
+  Carboniferous period, the atmosphere must have been warmer and more
+  charged with aqueous vapour and carbon dioxide than at the present
+  day, to admit of so luxuriant a flora as that from which the
+  coal-seams were formed. There seems, however, to be at present no
+  method of arriving at any certainty on this subject. Lastly, the
+  amount of carbonic acid absorbed in the weathering of rocks at the
+  surface, and the consequent production of carbonates, represents an
+  enormous abstraction of this gas.
+
+  As at present constituted, the atmosphere is regarded as a mechanical
+  mixture of nearly four volumes of nitrogen and one of oxygen, together
+  with an average of 3.5 parts of carbon dioxide in every 10,000 parts
+  of air, and minute quantities of various other gases and solid
+  particles. Of the vapours contained in it by far the most important is
+  that of water which, although always present, varies greatly in amount
+  according to variations in temperature. By condensation the water
+  vapour appears in visible form as dew, mist, cloud, rain, hail, snow
+  and ice, and in these forms includes and carries down some of the
+  other vapours, gases and solid particles present in the air. The
+  circulation of water from the atmosphere to the land, from the land to
+  the sea, and again from the sea to the land, forms the great
+  geological process whereby the habitable condition of the planet is
+  maintained and the surface of the land is sculptured (Part IV.).
+
+2. _The Hydrosphere._--The water envelope covers nearly three-fourths of
+the surface of the earth, and forms the various oceans and seas which,
+though for convenience of reference distinguished by separate names, are
+all linked together in one great body. The physical characters of this
+vast envelope are discussed in separate articles (see OCEAN and
+OCEANOGRAPHY). Viewed from the geological standpoint, the features of
+the sea that specially deserve attention are first the composition of
+its waters, and secondly its movements.
+
+  Sea-water is distinguished from that of ordinary lakes and rivers by
+  its greater specific gravity and its saline taste. Its average density
+  is about 1.026, but it varies even within the same ocean, being least
+  where large quantities of fresh water are added from rain or melting
+  snow and ice, and greatest where evaporation is most active. That
+  sea-water is heavier than fresh arises from the greater proportion of
+  salts which it contains in solution. These salts constitute about
+  three and a half parts in every hundred of water. They consist mainly
+  of chlorides of sodium and magnesium, the sulphates of magnesium,
+  calcium and potassium, with minuter quantities of magnesium bromide
+  and calcium carbonate. Still smaller proportions of other substances
+  have been detected, gold for example having been found in the
+  proportion of 1 part in 15,180,000.
+
+  That many of the salts have existed in the sea from the time of its
+  first condensation out of the primeval atmosphere appears to be
+  probable. It is manifest, however, that, whatever may have been the
+  original composition of the oceans, they have for a vast section of
+  geological time been constantly receiving mineral matter in solution
+  from the land. Every spring, brook and river removes various salts
+  from the rocks over which it moves, and these substances, thus
+  dissolved, eventually find their way into the sea. Consequently
+  sea-water ought to contain more or less traceable proportions of every
+  substance which the terrestrial waters can remove from the land, in
+  short, of probably every element present in the outer shell of the
+  globe, for there seems to be no constituent of this earth which may
+  not, under certain circumstances, be held in solution in water.
+  Moreover, unless there be some counteracting process to remove these
+  mineral ingredients, the ocean water ought to be growing, insensibly
+  perhaps, but still assuredly, saltier, for the supply of saline matter
+  from the land is incessant.
+
+  To the geologist the presence of mineral solutions in sea-water is a
+  fact of much importance, for it explains the origin of a considerable
+  part of the stratified rocks of the earth's crust. By evaporation the
+  water has given rise to deposits of rock-salt, gypsum and other
+  materials. The lime contained in solution, whether as sulphate or
+  carbonate, has been extracted by many tribes of marine animals, which
+  have thus built up out of their remains vast masses of solid
+  limestone, of which many mountain-chains largely consist.
+
+  Another important geological feature of the sea is to be seen in the
+  fact that its basins form the great receptacles for the detritus worn
+  away from the land. Besides the limestones, the visible parts of the
+  terrestrial crust are, in large measure, composed of sedimentary rocks
+  which were originally laid down on the sea-bottom. Moreover, by its
+  various movements, the sea occupies a prominent place among the
+  epigene or superficial agents which produce geological changes on the
+  surface of the globe.
+
+3. _The Lithosphere._--Beneath the gaseous and liquid envelopes lies the
+solid part of the planet, which is conveniently regarded as consisting
+of two parts,--(a) the crust, and (b) the interior or nucleus.
+
+
+  The crust.
+
+It was for a long time a prevalent belief that the interior of the globe
+is a molten mass round which an outer shell has gradually formed through
+cooling. Hence the term "crust" was applied to this external solid
+envelope, which was variously computed to be 10, 20, or more miles in
+thickness. The portion of this crust accessible to human observation was
+seen to afford abundant evidence of vast plications and corrugations of
+its substance, which were regarded as only explicable on the supposition
+of a thin solid collapsible shell floating on a denser liquid interior.
+When, however, physical arguments were adduced to show the great
+rigidity of the earth as a whole, the idea of a thin crust enclosing a
+molten nucleus was reluctantly abandoned by geologists, who found the
+problem of the earth's interior to be incapable of solution by any
+evidence which their science could produce. They continued, however, to
+use the term "crust" as a convenient word to denote the cool outer layer
+of the earth's mass, the structure and history of which form the main
+subjects of geological investigation. More recently, however, various
+lines of research have concurred in suggesting that, whatever may be the
+condition of the interior, its substance must differ greatly from that
+of the outer shell, and that there may be more reason than appeared for
+the retention of the name of crust. Observations on earthquake motion by
+Dr John Milne and others, show that the rate and character of the waves
+transmitted through the interior of the earth differ in a marked degree
+from those propagated along the crust. This difference indicates that
+rocky material, such as we know at the surface, may extend inwards for
+some 30 m., below which the earth's interior rapidly becomes fairly
+homogeneous and possesses a high rigidity. From measurements of the
+force of gravity in India by Colonel S.G. Burrard, it has been inferred
+that the variations in density of the outer parts of the earth do not
+descend farther than 30 or 40 m., which might be assumed to be the limit
+of the thickness of the crust. Recent researches in regard to the
+radio-active substances present in rocks suggest that the crust is not
+more than 50 m. thick, and that the interior differs from it in
+possessing little or no radio-active material.
+
+
+  The interior.
+
+Though we cannot hope ever to have direct acquaintance with more than
+the mere outside skin of our planet, we may be led to infer the
+irregular distribution of materials within the crust from the present
+distribution of land and water, and the observed differences in the
+amount of deflection of the plumb-line near the sea and near
+mountain-chains. The fact that the southern hemisphere is almost wholly
+covered with water appears explicable only on the assumption of an
+excess of density in the mass of that portion of the planet. The
+existence of such a vast sheet of water as that of the Pacific Ocean is
+to be accounted for, as Archdeacon J.H. Pratt pointed out, by the
+presence of "some excess of matter in the solid parts of the earth
+between the Pacific Ocean and the earth's centre, which retains the
+water in its place, otherwise the ocean would flow away to the other
+parts of the earth." A deflection of the plumb-line towards the sea,
+which has in a number of cases been observed, indicates that "the
+density of the crust beneath the mountains must be less than that below
+the plains, and still less than that below the ocean-bed." Apart
+therefore from the depression of the earth's surface in which the oceans
+lie, we must regard the internal density, whether of crust or nucleus,
+to be somewhat irregularly arranged, there being an excess of heavy
+materials in the water hemisphere, and beneath the ocean-beds, as
+compared with the continental masses.
+
+In our ignorance regarding the chemical constitution of the nucleus of
+our planet, an argument has sometimes been based upon the known fact
+that the specific gravity of the globe as a whole is about double that
+of the crust. This has been held by some writers to prove that the
+interior must consist of much heavier material and is therefore probably
+metallic. But the effect of pressure ought to make the density of the
+nucleus much higher, even if the interior consisted of matter no heavier
+than the crust. That the total density of the planet does not greatly
+exceed its observed amount seems only explicable on the supposition that
+some antagonistic force counteracts the effects of pressure. The only
+force we can suppose capable of so acting is heat. But comparatively
+little is yet known regarding the compression of gases, liquids and
+solids under such vast pressures as must exist within the nucleus.
+
+That the interior of the earth possesses a high temperature is inferred
+from the evidence of various sources. (1) Volcanoes, which are openings
+that constantly, or intermittently, give out hot vapours and molten lava
+from reservoirs beneath the crust. Besides active volcanoes, it is known
+that former eruptive vents have been abundantly and widely distributed
+over the globe from the earliest geological periods down to our own day.
+(2) Hot springs are found in many parts of the globe, with temperatures
+varying up to the boiling point of water. (3) From mines, tunnels and
+deep borings into the earth it has been ascertained that in all quarters
+of the globe below the superficial zone of invariable temperature, there
+is a progressive increase of heat towards the interior. The rate of this
+increase varies, being influenced, among other causes, by the varying
+conductivity of the rocks. But the average appears to be about 1 deg.
+Fahr. for every 50 or 60 ft. of descent, as far down as observations
+have extended. Though the increase may not advance in the same
+proportion at great depths, the inference has been confidently drawn
+that the temperature of the nucleus must be exceedingly high.
+
+The probable condition of the earth's interior has been a fruitful
+source of speculation ever since geology came into existence; but no
+general agreement has been arrived at on the subject. Three chief
+hypotheses have been propounded: (1) that the nucleus is a molten mass
+enclosed within a solid shell; (2) that, save in local vesicular spaces
+which may be filled with molten or gaseous material, the globe is solid
+and rigid to the centre; (3) that the great body of the nucleus consists
+of incandescent vapours and gases, especially vaporous iron, which under
+the gigantic pressure within the earth are so compressed as to confer
+practical rigidity on the globe as a whole, and that outside this main
+part of the nucleus the gases pass into a shell of molten magma, which,
+in turn, shades off outwards into the comparatively thin, cool
+solidified crust. Recent seismological observations have led to the
+inference that the outer crust, some 30 to 45 m. thick, must rapidly
+merge into a fairly homogeneous nucleus which, whatever be its
+constitution, transmits undulatory movements through its substance with
+uniform velocity and is believed to possess a high rigidity.
+
+The origin of the earth's high internal temperature has been variously
+accounted for. Most usually it has been assumed to be the residue of the
+original "tracts of fluent heat" out of which the planet shaped itself
+into a globe. According to another supposition the effects of the
+gradual gravitational compression of the earth's mass have been the main
+source of the high temperature. Recent researches in radio-activity, to
+which reference has already been made, have indicated another possible
+source of the internal heat in the presence of radium in the rocks of
+the crust. This substance has been detected in all igneous rocks,
+especially among the granites, in quantity sufficient, according to the
+Hon. R.J. Strutt, to account for the observed temperature-gradient in
+the crust, and to indicate that this crust cannot be more than 45 m.
+thick, otherwise the outflow of heat would be greater than the amount
+actually ascertained. Inside this external crust containing radio-active
+substances, it is supposed, as already stated, that the nucleus consists
+of some totally different matter containing little or no radium.
+
+  _Constitution of the Earth's Crust._--As the crust of the earth
+  contains the "geological record," or stony chronicle from which
+  geology interprets the history of our globe, it forms the main subject
+  of study to the geologist. The materials of which this crust consists
+  are known as minerals and rocks. From many chemical analyses, which
+  have been made of these materials, the general chemical constitution
+  of, at least, the accessible portion of the crust has been
+  satisfactorily ascertained. This information becomes of much
+  importance in speculations regarding the early history of the globe.
+  Of the elements known to the chemist the great majority form but a
+  small proportion of the composition of the crust, which is mainly
+  built up of about twenty of them. Of these by far the most important
+  are the non-metallic elements oxygen and silicon. The former forms
+  about 47% and the latter rather more than 28% of the original crust,
+  so that these two elements make up about three-fourths of the whole.
+  Next after them come the metals aluminium (8.16%), iron (4.64),
+  calcium (3.50), magnesium (2.62), sodium (2.63), and potassium (2.35).
+  The other twelve elements included in the twenty vary in amount from a
+  proportion of 0.41% in the case of titanium, to not more than 0.01% of
+  chlorine, fluorine, chromium, nickel and lithium. The other fifty or
+  more elements exist in such minute proportions in the crust that,
+  probably, not one of them amounts to as much as 0.01%, though they
+  include the useful metals, except iron. Taking the crust, and the
+  external envelopes of the ocean and the air, we thus perceive that
+  these outer parts of our planet consist of more than three-fourths of
+  non-metals and less than one-fourth of metals.
+
+  The combinations of the elements which are of most importance in the
+  constitution of the terrestrial crust consist of oxides. From the mean
+  of a large number of analyses of the rocks of the lower or primitive
+  portion of the crust, it has been ascertained that silica (SiO2) forms
+  almost 60% and alumina (Al2O3) upwards of 15% of the whole. The other
+  combinations in order of importance are lime (CaO) 4.90%, magnesia
+  (MgO) 4.36, soda (Na2O) 3.55, ferrous oxide (FeO) 3.52, potash (K2O)
+  2.80, ferric oxide (Fe2O3) 2.63, water (H2O) 1.52, titanium oxide
+  (TiO2) 0.60, phosphoric acid (P2O5) 0.22; the other combinations of
+  elements thus form less than 1% of the crust.
+
+  These different combinations of the elements enter into further
+  combinations with each other so as to produce the wide assortment of
+  simple minerals (see MINERALOGY). Thus, silica and alumina are
+  combined to form the aluminous silicates, which enter so largely into
+  the composition of the crust of the earth. The silicates of magnesia,
+  potash and soda constitute other important families of minerals. A
+  mass of material composed of one, but more usually of more than one
+  mineral, is known as a _rock_. Under this term geologists are
+  accustomed to class not only solid stone, such as granite and
+  limestone, but also less coherent materials such as clay, peat and
+  even loose sand. The accessible portion of the earth's crust consists
+  of various kinds of rocks, which differ from each other in structure,
+  composition and origin, and are therefore susceptible of diverse
+  classifications according to the point of view from which they are
+  considered. The details of this subject will be found in the article
+  PETROLOGY.
+
+  _Classification of Rocks._--Various systems of classification of rocks
+  have been proposed, but none of them is wholly satisfactory. The most
+  useful arrangement for most purposes of the geologist is one based on
+  the broad differences between them in regard to their mode of origin.
+  From this point of view they may be ranged in three divisions:
+
+  1. In the first place, a large number of rocks may be described as
+  original or underived, for it is not possible to trace them back to
+  any earlier source. They belong to the primitive constitution of the
+  planet, and, as they have all come up from below through the crust,
+  they serve to show the nature of the material which lies immediately
+  below the outer parts of that crust. They include the numerous
+  varieties of lava, which have been poured out in a molten state from
+  volcanic vents, also a great series of other rocks which, though they
+  may never have been erupted to the surface, have been forced upward in
+  a melted condition into the other rocks of the crust and have
+  solidified there. From their mode of origin this great class of rocks
+  has been called "igneous" or "eruptive." As they generally show no
+  definite internal structure save such as may result from joints, they
+  have been termed "massive" or "unstratified," to distinguish them from
+  those of the second division which are strongly marked out by the
+  presence of a stratified structure. The igneous rocks present a
+  considerable range of composition. For the most part they consist
+  mainly of aluminous silicates, some of them being highly acid
+  compounds with 75% or more of silica. But they also include highly
+  basic varieties wherein the proportion of silica sinks to 40%, and
+  where magnesia greatly predominates over alumina. The textures of
+  igneous rocks likewise comprise a wide series of varieties. On the one
+  hand, some are completely vitreous, like obsidian, which is a natural
+  glass. From this extreme every gradation may be traced through gradual
+  increase of the products of devitrification, until the mass may become
+  completely crystalline. Again, some crystalline igneous rocks are so
+  fine in grain as not to show their component crystals save under the
+  microscope, while in others the texture is so coarse as to present the
+  component minerals in separate crystals an inch or more in length.
+  These differences indicate that, at first, the materials of the rock
+  may have been as completely molten as artificial glass, and that the
+  crystalline condition has been subsequently developed by cooling, and
+  the separation of the chemical constituents into definite crystalline
+  minerals. Many of the characters of igneous rocks have been reproduced
+  experimentally by fusing together their minerals, or the constituents
+  of their minerals, in the proper proportion. But it has not yet been
+  found possible to imitate the structure of such rocks as granite.
+  Doubtless these rocks consolidated with extreme slowness at great
+  depths below the surface, under vast pressures and probably in the
+  presence of water or water-vapour--conditions which cannot be
+  adequately imitated in a laboratory.
+
+  Though the igneous rocks occupy extensive areas in some countries,
+  they nevertheless cover a much smaller part of the whole surface of
+  the land than is taken up by the second division or stratified rocks.
+  But they increase in quantity downwards and probably extend
+  continuously round the globe below the other rocks. This important
+  series brings before us the relations of the molten magma within the
+  earth to the overlying crust and to the outer surface. On the one
+  hand, it includes the oldest and most deep-seated extravasations of
+  that magma, which have been brought to light by ruptures and upheavals
+  of the crust and prolonged denudation. On the other, it presents to
+  our study the varied outpourings of molten and fragmentary materials
+  in the discharges of modern and ancient volcanoes. Between these two
+  extremes of position and age, we find that the crust has been, as it
+  were, riddled with injections of the magma from below. These features
+  will be further noticed in Part V. of this article.
+
+  2. The "sedimentary" or "stratified rocks" form by much the larger
+  part of the dry land of the globe, and they are prolonged to an
+  unknown distance from the shores under the bed of the sea. They
+  include those masses of mineral matter which, unlike the igneous
+  rocks, can be traced back to a definite origin on the surface of the
+  earth. Three distinct types may be recognized among them: (a) By far
+  the largest proportion of them consists of different kinds of sediment
+  derived from the disintegration of pre-existing rocks. In this
+  "fragmental" group are placed all the varieties of shingle, gravel,
+  sand, clay and mud, whether these materials remain in a loose
+  incoherent condition, or have been compacted into solid stone. (b)
+  Another group consists of materials that have been deposited by
+  chemical precipitation from solution in water. The white sinter laid
+  down by calcareous springs is a familiar example on a small scale.
+  Beds of rock-salt, gypsum and dolomite have, in some regions, been
+  accumulated to a thickness of many thousand feet, by successive
+  precipitations of the salt contained in the water of inland seas. (c)
+  An abundant and highly important series of sedimentary formations has
+  been formed from the remains of plants and animals. Such accumulations
+  may arise either from the transport and deposit of these remains, as
+  in the case of sheets of drift-wood, and banks of drifted sea-shells,
+  or from the growth and decay of the organisms on the spot, as happens
+  in peat bogs and in coral-reefs.
+
+  As the sedimentary rocks have for the most part been laid down under
+  water, and more especially on the sea-floor, they are often spoken of
+  as "aqueous," in contradistinction to the igneous rocks. Some of them,
+  however, are accumulated by the drifting action of wind upon loose
+  materials, and are known as "aeolian" formations. Familiar instances
+  of such wind-formed deposits are the sand-dunes along many parts of
+  the sea coast. Much more extensive in area are the sands of the great
+  deserts in the arid regions of the globe.
+
+  It is from the sedimentary rocks that the main portion of geological
+  history is derived. They have been deposited one over another in
+  successive strata from a remote period in the development of the globe
+  down to the present time. From this arrangement they have been termed
+  "stratified," in contrast to the unstratified or igneous series. They
+  have preserved memorials of the geographical revolutions which the
+  surface of the earth has undergone; and above all, in the abundant
+  fossils which they have enclosed, they furnish a momentous record of
+  the various tribes of plants and animals which have successively
+  flourished on land and sea. Their investigation is thus the most
+  important task which devolves upon the geologist.
+
+  3. In the third place comes a series of rocks which are not now in
+  their original condition, but have undergone such alteration as to
+  have acquired new characters that more or less conceal their first
+  structures. Some of them can be readily recognized as altered igneous
+  masses; others are as manifestly of sedimentary origin; while of many
+  it is difficult to decide what may have been their pristine character.
+  To this series the term "metamorphic" has been applied. Its members
+  are specially distinguished by a prevailing fissile, or schistose,
+  structure which they did not at first possess, and which differs from
+  anything found in unaltered igneous or sedimentary rocks. This
+  fissility is combined with a more or less pronounced crystalline
+  structure. These changes are believed to be the result of movements
+  within the crust of the earth, whereby the most solid rocks were
+  crushed and sheared, while, at the same time, under the influence of a
+  high temperature and the presence of water, they underwent internal
+  chemical reactions, which led to a rearrangement and recomposition of
+  their mineral constituents and the production of a crystalline
+  structure (see METAMORPHISM).
+
+  Among the less altered metamorphic rocks of sedimentary origin, the
+  successive laminae of deposit of the original sediment can be easily
+  observed; but they are also traversed by a new set of divisional
+  planes, along which they split across the original bedding. Together
+  with this superinduced cleavage there have been developed in them
+  minute hairs, scales and rudimentary crystals. Further stages of
+  alteration are marked by the increase of micaceous scales, garnets and
+  other minerals, especially along the planes of cleavage, until the
+  whole rock becomes crystalline, and displays its chief component
+  minerals in successive discontinuous folia which merge into each
+  other, and are often crumpled and puckered. Massive igneous rocks can
+  be observed to have undergone intense crushing and cleavage, and to
+  have ultimately assumed a crystalline foliated character. Rocks which
+  present this aspect are known as schists (q.v.). They range from the
+  finest silky slates, or phyllites, up to the coarsest gneisses, which
+  in hand-specimens can hardly be distinguished from granites. There is
+  indeed every reason to believe that such gneisses were probably
+  originally true granites, and that their foliation and
+  recrystallization have been the result of metamorphism.
+
+  The schists are more especially to be found in the heart of
+  mountain-chains, and in regions where the lowest and oldest parts of
+  the earth's crust have, in the course of geological revolutions, been
+  exposed to the light of day. They have been claimed by some writers
+  to be part of the original or primitive surface of our globe that
+  first consolidated on the molten nucleus. But the progress of
+  investigation all over the world has shown that this supposition
+  cannot be sustained. The oldest known rocks present none of the
+  characters of molten material that has cooled and hardened in the air,
+  like the various forms of recent lava. On the contrary, they possess
+  many of the features characteristic of bodies of eruptive material
+  that have been injected into the crust at some depth underground, and
+  are now visible at the surface, owing to the removal by denudation of
+  the rocks under which they consolidated. In their less foliated
+  portions they can be recognized as true eruptive rocks. In many places
+  gneisses that possess a thoroughly typical foliation have been found
+  to pierce ancient sedimentary formations as intrusive bosses and
+  veins.
+
+
+PART IV.--DYNAMICAL GEOLOGY
+
+This section of the science includes the investigation of those
+processes of change which are at present in progress upon the earth,
+whereby modifications are made on the structure and composition of the
+crust, on the relations between the interior and the surface, as shown
+by volcanoes, earthquakes and other terrestrial disturbances, on the
+distribution of oceans and continents, on the outlines of the land, on
+the form and depth of the sea-bottom, on climate, and on the races of
+plants and animals by which the earth is tenanted. It brings before us,
+in short, the whole range of activities which it is the province of
+geology to study, and leads us to precise notions regarding their
+relations to each other and the results which they achieve. A knowledge
+of this branch of the subject is thus the essential groundwork of a true
+and fruitful acquaintance with the principles of geology, seeing that it
+necessitates a study of the present order of nature, and thus provides a
+key for the interpretation of the past.
+
+The whole range of operations included within the scope of inquiry in
+this branch of the science may be regarded as a vast cycle of change,
+into which we may break at any point, and round which we may travel,
+only to find ourselves brought back to our starting-point. It is a
+matter of comparatively small moment at what part of the cycle we begin
+our inquiries. We shall always find that the changes we see in action
+have resulted from some that preceded, and give place to others which
+follow them.
+
+At an early time in the earth's history, anterior to any of the periods
+of which a record remains in the visible rocks, the chief sources of
+geological action probably lay within the earth itself. If, as is
+generally supposed, the planet still retained a great store of its
+initial heat, it was doubtless the theatre of great chemical changes,
+giving rise, perhaps, to manifestations of volcanic energy somewhat like
+those which have so marvellously roughened the surface of the moon. As
+the outer layers of the globe cooled, and the disturbances due to
+internal heat and chemical action became less marked, the conditions
+would arise in which the materials for geological history were
+accumulated. The influence of the sun, which must always have operated,
+would then stand out more clearly, giving rise to that wide circle of
+superficial changes wherein variations of temperature and the
+circulation of air and water over the surface of the earth come into
+play.
+
+In the pursuit of his inquiries into the past history and into the
+present _regime_ of the earth, the geologist must needs keep his mind
+ever open to the reception of evidence for kinds and especially for
+degrees of action which he had not before imagined. Human experience has
+been too short to allow him to assume that all the causes and modes of
+geological change have been definitively ascertained. On the earth
+itself there may remain for future discovery evidence of former
+operations by heat, magnetism, chemical change or otherwise, which may
+explain many of the phenomena with which geology has to deal. Of the
+influences, so many and profound, which the sun exerts upon our planet,
+we can as yet only perceive a little. Nor can we tell what other
+cosmical influences may have lent their aid in the evolution of
+geological changes.
+
+Much useful information regarding many geological processes has been
+obtained from experimental research in laboratories and elsewhere, and
+much more may be confidently looked for from future extensions of this
+method of inquiry. The early experiments of Sir James Hall, already
+noticed, formed the starting-point for numerous subsequent researches,
+which have elucidated many points in the origin and history of rocks. It
+is true that we cannot hope to imitate those operations of nature which
+demand enormous pressures and excessively high temperatures combined
+with a long lapse of time. But experience has shown that in regard to a
+large number of processes, it is possible to imitate nature's working
+with sufficient accuracy to enable us to understand them, and so to
+modify and control the results as to obtain a satisfactory solution of
+some geological problems.
+
+In the present state of our knowledge, all the geological energy upon
+and within the earth must ultimately be traced back to the primeval
+energy of the parent nebula or sun. There is, however, a certain
+propriety and convenience in distinguishing between that part of it
+which is due to the survival of some of the original energy of the
+planet and that part which arises from the present supply of energy
+received day by day from the sun. In the former case we have to deal
+with the interior of the earth, and its reaction upon the surface; in
+the latter, we deal with the surface of the earth and to some extent
+with its reaction on the interior. This distinction allows of a broad
+treatment of the subject under two divisions:
+
+I. Hypogene or Plutonic Action: The changes within the earth caused by
+internal heat, mechanical movement and chemical rearrangements.
+
+II. Epigene or Surface Action: The changes produced on the superficial
+parts of the earth, chiefly by the circulation of air and water set in
+motion by the sun's heat.
+
+
+_DIVISION I.--HYPOGENE OR PLUTONIC ACTION_
+
+In the discussion of this branch of the subject we must carry in our
+minds the conception of a globe still possessing a high internal
+temperature, radiating heat into space and consequently contracting in
+bulk. Portions of molten rocks from inside are from time to time poured
+out at the surface. Sudden shocks are generated by which destructive
+earthquakes are propagated through the diameter of the globe as well as
+to and along its surface. Wide geographical areas are pushed up or sink
+down. In the midst of these movements remarkable changes are produced
+upon the rocks of the crust; they are plicated, fractured, crushed,
+rendered crystalline and even fused.
+
+
+  (A) _Volcanoes and Volcanic Action._
+
+  This subject is discussed in the article VOLCANO, and only a general
+  view of its main features will be given here. Under the term volcanic
+  action (vulcanism, vulcanicity) are embraced all the phenomena
+  connected with the expulsion of heated materials from the interior of
+  the earth to the surface. A volcano may be defined as a conical hill
+  or mountain, built up wholly or mainly of materials which have been
+  ejected from below, and which have accumulated around the central vent
+  of eruption. As a rule its truncated summit presents a cup-shaped
+  cavity, termed the crater, at the bottom of which is the opening of
+  the main funnel or pipe whereby communication is maintained with the
+  heated interior. From time to time, however, in large volcanoes rents
+  are formed on the sides of the cone, whence steam and other hot
+  vapours and also streams of molten lava are poured forth. On such
+  rents smaller or parasitic cones are often formed, which imitate the
+  operations of the parent cone and, after repeated eruptions, may rise
+  to hills hundreds of feet in height. In course of centuries the result
+  of the constant outpouring of volcanic materials may be to build up a
+  large mountain like Etna, which towers above the sea to a height of
+  10,840 feet, and has some 200 minor cones along its flanks.
+
+  But all volcanic eruptions do not proceed from central orifices. In
+  Iceland it has been observed that, from fissures opened in the ground
+  and extending for long distances, molten material has issued in such
+  abundance as to be spread over the surrounding country for many miles,
+  while along the lines of fissure small cones or hillocks of
+  fragmentary material have accumulated round more active parts of the
+  rent. There is reason to believe that in the geological past this
+  fissure-type of eruption has repeatedly been developed, as well as the
+  more common form of central cones like Vesuvius or Etna.
+
+  In the operations of existing volcanoes only the superficial
+  manifestations of volcanic action are observable. But when the rocks
+  of the earth's crust are studied, they are found to enclose the relics
+  of former volcanic eruptions. The roots of ancient volcanoes have thus
+  been laid bare by geological revolutions; and some of the
+  subterranean phases of volcanic action are thereby revealed which are
+  wholly concealed in an active volcano. Hence to obtain as complete a
+  conception as possible of the nature and history of volcanic action,
+  regard must be had, not merely to modern volcanoes, but to the records
+  of ancient eruptions which have been preserved within the crust.
+
+  The substances discharged from volcanic vents consist of--(1) Gases
+  and vapours: which, dissolved in the molten magma of the interior,
+  take the chief share in volcanic activity. They include in greatest
+  abundance water-gas, which condenses into the clouds of steam so
+  conspicuous in volcanic eruptions. Hydrochloric acid and sulphuretted
+  hydrogen are likewise plentiful, together with many other substances
+  which, sublimed by the high internal temperature, take a solid form on
+  cooling at the surface. (2) Molten rock or lava: which ranges from the
+  extremely acid type of the obsidians and rhyolites with 70% or more of
+  silica, to the more basic and heavy varieties such as basalts and
+  leucite-lavas with much iron, and sometimes no more than 45% of
+  silica. The specific gravity of lavas varies between 2.37 and 3.22,
+  and the texture ranges from nearly pure glass, like obsidian, to a
+  coarse granitoid compound, as in some rhyolites. (3) Fragmentary
+  materials, which are sometimes discharged in enormous quantity and
+  dispersed over a wide extent of country, the finer particles being
+  transported by upper air-currents for hundreds of miles. These
+  materials arise either from the explosion of lava by the sudden
+  expansion of the dissolved vapours and gases, as the molten rock rises
+  to the surface, or from the breaking up and expulsion of portions of
+  the walls of the vent, or of the lava, which happens to have
+  solidified within these walls. They vary from the finest impalpable
+  dust and ashes, through increasing stages of coarseness up to huge
+  "bombs" torn from the upper surface of the molten rock in the vent,
+  and large blocks of already solidified lava, or of non-volcanic rock
+  detached from the sides of the pipe up which the eruptions take place.
+
+  Nothing is yet known as to the determining cause of any particular
+  volcanic eruption. Some vents, like that of Stromboli, in the
+  Mediterranean, are continually active, and have been so ever since man
+  has observed them. Others again have been only intermittently in
+  eruption, with intervals of centuries between their periods of
+  activity. We are equally in the dark as to what has determined the
+  sites on which volcanic action has manifested itself. There is reason,
+  indeed, to believe that extensive fractures of the terrestrial crust
+  have often provided passages up which the vapours, imprisoned in the
+  internal magma, have been able to make their way, accompanied by other
+  products. Where chains of volcanoes rise along definite lines, like
+  those of Sumatra, Java, and many other tracts both in the Old and the
+  New World, there appears to be little doubt that their linear
+  distribution should be attributed to this cause. But where a volcano
+  has appeared by itself, in a region previously exempt from volcanic
+  action, the existence of a contributing fissure cannot be so
+  confidently presumed. The study of certain ancient volcanoes, the
+  roots of which have been exposed by long denudation, has shown an
+  absence of any visible trace of their having availed themselves of
+  fractures in the crust. The inference has been drawn that volcanic
+  energy is capable of itself drilling an orifice through the crust,
+  probably at some weaker part, and ejecting its products at the
+  surface. The source of this energy is to be sought in the enormous
+  expansive force of the vapours and gases dissolved in the magma. They
+  are kept in solution by the enormous pressure within the earth; but as
+  the lava approaches the surface and this pressure is relieved these
+  dissolved vapours and gases rush out with explosive violence, blowing
+  the upper part of the lava column into dust, and allowing portions of
+  the liquid mass below to rise and escape, either from the crater or
+  from some fissure which the vigour of explosion has opened on the side
+  of the cone. So gigantic is the energy of these pent-up vapours, that,
+  after a long period of volcanic quiescence, they sometimes burst forth
+  with such violence as to blow off the whole of the upper part or even
+  one side of a large cone. The history of Vesuvius, and the great
+  eruptions of Krakatoa in 1883 and of Bandaizan in 1888 furnish
+  memorable examples of great volcanic convulsions. It has been observed
+  that such stupendous discharges of aeriform and fragmentary matter may
+  be attended with the emission of little or no lava. On the other hand,
+  some of the largest outflows of lava have been accompanied by
+  comparatively little fragmentary material. Thus, the great lava-floods
+  of Iceland in 1783 spread for 40 m. away from their parent fissure,
+  which was marked only by a line of little cones of slag.
+
+  The temperature of lava as it issues from underground has been
+  measured more or less satisfactorily, and affords an indication of
+  that existing within the earth. At Vesuvius it has been ascertained to
+  be more than 2000 deg. Fahr. At first the molten rock glows with a
+  white light, which rapidly reddens, and disappears under the rugged
+  brown and black crust that forms on the surface. Underneath this badly
+  conducting crust, the lava cools so slowly that columns of steam have
+  been noticed rising from its surface more than 80 years after its
+  eruption.
+
+  Considerable alteration in the topography of volcanic regions may be
+  produced by successive eruptions. The fragmentary materials are
+  sometimes discharged in such abundance as to cover the ground for many
+  miles around with a deposit of loose ashes, cinders and slag. Such a
+  deposit accumulating to a depth of many feet may completely bury
+  valleys and water-courses, and thus greatly affect the drainage. The
+  coarsest materials accumulate nearest to the vent that emits them. The
+  finer dust is not infrequently hurled forth with such an impetus as to
+  be carried for thousands of feet into the tracks of upper
+  air-currents, whereby it may be borne for hundreds of miles away from
+  the vent so as ultimately to fall to the ground in countries far
+  removed from any active volcano. Outflows of lava, from their greater
+  solidity and durability, produce still more serious and lasting
+  changes in the external features of the ground over which they flow.
+  As they naturally seek the lowest levels, they find their way into the
+  channels of streams. If they keep along the channels, they seal them
+  up under a mass of compact stone which the running water, if not
+  wholly diverted elsewhere, will take many long centuries to cut
+  through. If, on the other hand, the lava crosses a stream, it forms a
+  massive dam, above which the water is ponded back so as to form a
+  lake.
+
+  As the result of prolonged activity a volcanic cone is gradually built
+  up by successive outflows of lava and showers of dust and stones.
+  These materials are arranged in beds, or sheets, inclined outwards
+  from the central vent. On surrounding level ground the alternating
+  beds are flat. In course of time, deep gullies are cut on the outer
+  slopes of the cone by rain, and by the heavy showers that arise from
+  the condensation of the copious discharges of steam during eruptions.
+  Along the sides of these ravines instructive sections may be studied
+  of the volcanic strata. The larger rivers of some volcanic regions
+  have likewise eroded vast gorges in the more horizontal lavas and
+  ashes of the flatter country, and have thus laid bare stupendous
+  cliffs, along which the successive volcanic sheets can be seen piled
+  above each other for many hundred feet. On a small scale, some of
+  these features are well displayed among the rivers that drain the
+  volcanic tracts of central France; on a great scale, they are
+  presented in the course of the Snake river, and other streams that
+  traverse the great volcanic country of western North America. Similar
+  volcanic scenery has been produced in western Europe by the action of
+  denudation in dissecting the flat Tertiary lavas of Scotland, the
+  Faeroe Isles and Iceland.
+
+  Of special interest to the geologist are those volcanoes which have
+  taken their rise on the sea-bottom; for the volcanic intercalations
+  among the stratified formations of the earth's crust are almost
+  entirely of submarine origin. Many active volcanoes situated on
+  islands have begun their eruptions below sea-level. Both Vesuvius and
+  Etna sprang up on the floor of the Mediterranean sea, and have
+  gradually built up their cones into conspicuous parts of the dry land.
+  Examples of a similar history are to be found among the volcanic
+  islands of the Pacific Ocean. In some of these cases a movement of
+  elevation has carried the submarine lavas, tuffs and agglomerates
+  above sea-level, and has furnished opportunities of comparing these
+  materials with those of recent subaerial origin, and also with the
+  ancient records of submarine eruptions which have been preserved among
+  the stratified formations. From the evidence thus supplied, it can be
+  shown that the materials ejected from modern submarine volcanic vents
+  closely resemble those accumulated by subaerial volcanoes; that the
+  dust, ashes and stones become intermingled or interstratified with
+  coral-mud, or other non-volcanic deposit of the sea-bottom, that
+  vesicular lavas may be intercalated among them as on land, and that
+  between the successive sheets of volcanic origin, layers of limestone
+  may be laid down which are composed chiefly, or wholly, of the remains
+  of calcareous marine organisms.
+
+  Though active volcanoes are widely distributed over the globe, and are
+  especially abundant around the vast basin of the Pacific Ocean, they
+  afford an incomplete picture of the extent to which volcanic action
+  has displayed itself on the surface of our planet. When the rocks of
+  the land are attentively studied they disclose proofs of that action
+  in many districts where there is now no outward sign of it. Not only
+  so, but they reveal that volcanoes have been in eruption in some of
+  these districts during many different periods of the past, back to the
+  beginnings of geological history. The British Islands furnish a
+  remarkable example of such a series of ancient eruptions. From the
+  Cambrian period all through Palaeozoic times there rose at intervals
+  in that country a succession of volcanic centres from some of which
+  thousands of feet of lavas and tuffs were discharged. Again in older
+  Tertiary times the same region witnessed a stupendous outpouring of
+  basalt, the surviving relics of which are more than 3000 ft. thick,
+  and cover many hundreds of square miles. Similar evidence is supplied
+  in other countries both in the Old and the New world. Hence it is
+  proved that, in the geological past, volcanic action has been vigorous
+  at long intervals on the same sites during a vast series of ages,
+  though no active vents are to be seen there now. The volcanoes now
+  active form but a small proportion of the total number which has
+  appeared on the surface of the earth.
+
+  With regard to the cause of volcanic action much has been speculated,
+  but little can be confidently affirmed. That water in the form of
+  occluded gas plays the chief part in forcing the lava column up a
+  volcanic chimney, and in the violent explosions that accompany the
+  rise of the molten material, is generally admitted. But opinions
+  differ as to the source of this water. According to some
+  investigators, it should be regarded as in large measure of meteoric
+  origin, derived from the descent of rain into the earth, and its
+  absorption by the molten magma in the interior. Others, contending
+  that the supply so furnished, even if it could reach and be dissolved
+  in the magma, would yet be insufficient to furnish the prodigious
+  quantity of aqueous vapour discharged during an eruption, maintain
+  that the water belongs to the magma itself. They point to the admitted
+  fact that many substances, particularly metals in a state of fusion,
+  can absorb large quantities of vapours and gases without chemical
+  combination, and on cooling discharge them with eruptive phenomena
+  somewhat like those of volcanoes. This question must be regarded as
+  one of the still unsolved problems of geology.
+
+
+  (B) _Movements of the Earth's Crust._
+
+  Among the hypogene forces in geological dynamics an important place
+  must be assigned to movements of the terrestrial crust. Though the
+  expression "the solid earth" has become proverbial, it appears
+  singularly inappropriate in the light of the results obtained in
+  recent years by the use of delicate instruments of observation. With
+  the facilities supplied by these instruments (see SEISMOMETER), it has
+  been ascertained that the ground beneath our feet is subject to
+  continual slight tremors, and feeble pulsations of longer duration,
+  some of which may be due to daily or seasonal variations of
+  temperature, atmospheric pressure or other meteorological causes. The
+  establishment of self-recording seismometers all over the world has
+  led to the detection of many otherwise imperceptible shocks, over and
+  above the appreciable earth-waves propagated from earthquake centres
+  of disturbance. Moreover, it has been ascertained that some parts of
+  the surface of the land are slowly rising, while others are falling
+  with reference to the sea-level. From time to time the surface suffers
+  calamitous devastation from earthquakes, when portions of the crust
+  under great strain suddenly give way. Lastly, at intervals, probably
+  separated from each other by vast periods of time, the terrestrial
+  crust undergoes intense plication and fracture, and is consequently
+  ridged up into mountain-chains. No event of this kind has been
+  witnessed since man began to record his experiences. But from the
+  structure of mountains, as laid open by prolonged denudation, it is
+  possible to form a vivid conception of the nature and effects of these
+  most stupendous of all geological revolutions.
+
+  In considering this department of geological inquiry it will be
+  convenient to treat it under the following heads: (1) Slow depression
+  and upheaval; (2) Earthquakes; (3) Mountain-making; (4) Metamorphism
+  of rocks.
+
+  1. _Slow Depression and Upheaval._--On the west side of Japan the land
+  is believed to be sinking below the sea, for fields are replaced by
+  beaches of sand or shingle, while the depth of the sea off shore has
+  perceptibly increased. A subsidence of the south of Sweden has taken
+  place in comparatively recent times, for streets and foundations of
+  houses at successive levels are found below high-water mark. The west
+  coast of Greenland over an extent of more than 600 m. is sinking, and
+  old settlements are now submerged. Proofs of submergence of land are
+  furnished by "submerged forests," and beds of terrestrial peat now
+  lying at various depths below the level of the sea, of which many
+  examples have been collected along the shores of the British Isles,
+  Holland and France. Interesting evidence that the west of Europe now
+  stands at a lower level than it did at a late geological period is
+  supplied in the charts of the North Sea and Atlantic, which show that
+  the valleys of the land are prolonged under the sea. These valleys
+  have been eroded out of the rocks by the streams which flow in them,
+  and the depth of their submerged portions below the sea level affords
+  an indication of the extent of the subsidence.
+
+  The uprise of land has been detected in various parts of the world.
+  One of the most celebrated instances is that of the shores of the Gulf
+  of Bothnia, where, at Stockholm, the elevation, between the years 1774
+  and 1875, appears to have been 48 centimetres (18-1/2 in.) in a
+  century. But on the west side of Sweden, fronting the Skager Rak, the
+  coast, between the years 1820 and 1870, rose 30 centimetres, which is
+  at the rate of 60 centimetres, or nearly 2 ft. in a century. In the
+  region of the Great Lakes in the interior of Canada and the United
+  States it has been ascertained that the land is undergoing a slow tilt
+  towards the south-west, of which the mean rate appears to be rather
+  less than 6 in. in a century. If this rate of change should continue
+  the waters of Lake Michigan, owing to the progress of the tilt, will,
+  in some 500 or 600 years, submerge the city of Chicago, and eventually
+  the drainage of the lakes will be diverted into the basin of the
+  Mississippi. Proof of recent emergence of land is supplied by what are
+  called "raised beaches" or "strand-lines," that is, lines of former
+  shores marked by sheets of littoral deposits, or platforms cut by
+  shore-waves in rock and flanked by old sea-cliffs and lines of
+  sea-worn caves. Admirable examples of these features are to be seen
+  along the west coast of Europe from the south of England to the north
+  of Norway. These lines of old shores become fainter in proportion to
+  their antiquity. In Britain they occur at various heights, the
+  platforms at 25, 50 and 100 ft. being well marked.
+
+  The cause of these slow upward and downward movements of the crust of
+  the earth is still imperfectly understood. Upheaval might conceivably
+  be produced by an ascent of the internal magma, and the consequent
+  expansion of the overlying crust by heat; while depression might
+  follow any subsidence of the magma, or its displacement to another
+  district. If, as is generally believed, the globe is still
+  contracting, the shrinkage of the surface may cause both these
+  movements. Subsidence will be in excess, but between subsiding tracts
+  lateral thrust may suffice to push upward intervening more solid and
+  stable ground; but no solution of the problem yet proposed is wholly
+  satisfactory.
+
+  2. _Earthquakes._--As this subject is discussed in a separate article
+  it will be sufficient here to take note of its more important
+  geological bearings. It was for many centuries taken for granted that
+  earthquakes and volcanoes are due to a common cause. We have seen that
+  in classical antiquity they were looked on as the results of the
+  movements of wind imprisoned within the earth. Long after this notion
+  was discarded, and a more scientific appreciation of volcanic action
+  was reached, it was still thought that earthquakes should be regarded
+  as manifestations of the same source of energy as that which displays
+  itself in volcanic eruptions. It is true that earthquakes are frequent
+  in districts of active volcanoes, and they may undoubtedly be often
+  due there to the explosions of the magma, or to the rupture of rocks
+  caused by its ascent towards the surface. But such shocks are
+  comparatively local in their range and feeble in their effects. There
+  is now a general agreement that between the great world-shaking
+  earthquakes and volcanic phenomena, no immediate and intimate
+  relationship can be traced, though they may be connected in ways which
+  are not yet perceived. Some of the more recent great earthquakes on
+  land have proved that the waves of shock are produced by the sudden
+  rupture or collapse of rocks under great strain, either along lines of
+  previous fracture or of new rents in the terrestrial crust; and that
+  such ruptures may occur at a remote distance from any volcano. Thus
+  the recent disastrous San Francisco earthquake has been recognized to
+  have resulted from a slipping of ground along the line of an old
+  fault, which has been traced for a long distance in California
+  generally parallel to the coast. The position of this fault at the
+  surface has long been clearly followed by its characteristic
+  topography. After the earthquake these superficial features were found
+  to have been removed by the same cause that had originated them. For
+  some 300 m. on the track of this old fault-line a renewed slipping was
+  seen to have taken place along one or both sides, and the ground at
+  the surface was ruptured as well as displaced horizontally. Obviously,
+  the jar occasioned by the sudden and simultaneous subsidence of a
+  portion of the earth's crust several hundred miles long, must be far
+  more serious than could be produced by an earthquake radiating from a
+  single local volcanic focus.
+
+  From their disastrous effects on buildings and human lives, an
+  exaggerated importance has been imputed to earthquakes as agents of
+  geological change. Experience shows that even after a severe shock
+  which may have destroyed numerous towns and villages, together with
+  thousands of their inhabitants, the face of the country has suffered
+  scarcely any perceptible change, and that, in the course of a year or
+  two, when the ruined houses and prostrate trees have been cleared
+  away, little or no obvious trace of the catastrophe may remain. Among
+  the more enduring records of a great earthquake may be enumerated (a)
+  landslips, which lay bare hillsides, and sometimes pond back the
+  drainage of valleys so as to give rise to lakes; (b) alterations of
+  the topography, as in fissuring of the ground, or in the production of
+  inequalities whereby the drainage is affected; new valleys and new
+  lakes may thus be formed, while previously existing lakes may be
+  emptied; (c) permanent changes of level, either in an upward or
+  downward direction.
+
+  3. _Mountain-making._--This subject may be referred to here for the
+  striking evidence which it supplies of the importance of movements of
+  the earth's crust among geological processes. The structure of a great
+  mountain-chain such as the Alps proves that the crust of the earth has
+  been intensely plicated, crumpled and fractured. Vast piles of
+  sedimentary strata have been folded to such an extent as to occupy now
+  only half of their original horizontal extent. This compression in the
+  case of the Alps has been computed to amount to as much as 120,000
+  metres or 74 English miles, so that two points on the opposite sides
+  of that chain have been brought by so much nearer to each other than
+  they were originally before the movements. Besides such intense
+  plication, extensive rupturing of the crust has taken place in the
+  same range of mountains. Not only have the most ancient rocks been
+  squeezed up into the central axis of the chain, but huge slices of
+  them have been torn away from the main body, and thrust forward for
+  many miles, so as now actually to form the summits of mountains, which
+  are almost entirely composed of much younger formations. If these
+  colossal disturbances occurred rapidly, they would give rise to
+  cataclysms of inconceivable magnitude over the surface of the globe.
+  No record has been discovered of such accompanying devastation. But
+  whether sudden and violent, or prolonged and gradual, such stupendous
+  upturnings of the crust did undoubtedly take place, as is clearly
+  revealed in innumerable natural sections, which have been laid open by
+  the denudation of the crests and sides of the mountains.
+
+  4. _Metamorphism of Rocks_ (see METAMORPHISM).--During the movements
+  to which the crust of the earth has been subject, not only have the
+  rocks been folded and fractured, but they have likewise, in many
+  regions, acquired new internal structures, and have thus undergone a
+  process of "regional metamorphism." This rearrangement of their
+  substance has been governed by conditions which are probably not yet
+  all recognized, but among them we should doubtless include a high
+  temperature, intense pressure, mechanical movement resulting in
+  crushing, shearing and foliation, and the presence of water in their
+  pores. It is among igneous rocks that the progressive stages of
+  metamorphism can be most easily traced. Their definite original
+  structure and mineral composition afford a starting-point from which
+  the investigation may be begun and pursued. Where an igneous rock has
+  been invaded by metamorphic changes, it may be observed to have been
+  first broken down into separate lenticles, the cores of which may
+  still retain, with little or no alteration, the original
+  characteristic minerals and crystalline structure of the rock. Between
+  these lenticles, the intervening portions have been crushed down into
+  a powder or paste, which seems to have been squeezed round and past
+  them, and shows a laminated arrangement that resembles the
+  flow-structure in lavas. As the degree of metamorphism increases, the
+  lenticles diminish in size, and the intervening crushed and foliated
+  matrix increases in amount, until at last it may form the entire mass
+  of the rock. While the original minerals are thus broken down, new
+  varieties make their appearance. Of these, among the earliest to
+  present themselves are usually the micas, that impart their
+  characteristic silvery sheen to the surfaces of the folia along which
+  they spread. Younger felspars, as well as mica, are developed, and
+  there arise also sillimanite, garnet, andalusite and many others. The
+  texture becomes more coarsely crystalline, and the segregation of the
+  constituent minerals more definite along the lines of foliation. From
+  the finest silky phyllites a graduation may be traced through
+  successively coarser mica-schists, until we reach the almost granitic
+  texture of the coarsest gneisses.
+
+  Regional metamorphism has arisen in the heart of mountain-chains, and
+  in any other district where the deformation of the crust has been
+  sufficiently intense. There is another type of alteration termed
+  "contact-metamorphism," which is developed around masses of igneous
+  rock, especially where these have been intruded in large bosses among
+  stratified formations. It is particularly displayed around masses of
+  granite, where sandstones are found altered into quartzite, shales and
+  grits into schistose compounds, and where sometimes fossils are still
+  recognizable among the metamorphic minerals.
+
+
+_DIVISION II.--EPIGENE OR SUPERFICIAL ACTION_
+
+It is on the surface of the globe, and by the operation of agents
+working there, that at present the chief amount of visible geological
+change is effected. In considering this branch of inquiry, we are not
+involved in a preliminary difficulty regarding the very nature of the
+agencies as is the case in the investigation of plutonic action. On the
+contrary, the surface agents are carrying on their work under our very
+eyes. We can watch it in all its stages, measure its progress, and mark
+in many ways how accurately it represents similar changes which, for
+long ages previously, must have been effected by the same means. But in
+the systematic treatment of this subject we encounter a difficulty of
+another kind. We discover that while the operations to be discussed are
+numerous and readily observable, they are so interwoven into one great
+network that any separation of them under different subdivisions is sure
+to be more or less artificial and to convey an erroneous impression.
+While, therefore, under the unavoidable necessity of making use of such
+a classification of subjects, we must always bear in mind that it is
+employed merely for convenience, and that in nature superficial
+geological action must be continually viewed as a whole, since the work
+of each agent has constant reference to that of the others, and is not
+properly intelligible unless that connexion be kept in view.
+
+The movements of the air; the evaporation from land and sea; the fall of
+rain, hail and snow; the flow of rivers and glaciers; the tides,
+currents and waves of the ocean; the growth and decay of organized
+existence, alike on land and in the depths of the sea;--in short, the
+whole circle of movement, which is continually in progress upon the
+surface of our planet, are the subjects now to be examined. It is
+desirable to adopt some general term to embrace the whole of this range
+of inquiry. For this end the word epigene (Gr. [Greek: epi], upon) has
+been suggested as a convenient term, and antithetical to hypogene (Gr.
+[Greek: hypo], under), or subterranean action.
+
+A simple arrangement of this part of Geological Dynamics is in three
+sections:
+
+A. _Air._--The influence of the atmosphere in destroying and forming
+rocks.
+
+B. _Water._--The geological functions of the circulation of water
+through the air and between sea and land, and the action of the sea.
+
+C. _Life._--The part taken by plants and animals in preserving,
+destroying or reproducing geological formations.
+
+The words destructive, reproductive and conservative, employed in
+describing the operations of the epigene agents, do not necessarily
+imply that anything useful to man is destroyed, reproduced or preserved.
+On the contrary, the destructive action of the atmosphere may turn
+barren rock into rich soil, while its reproductive effects sometimes
+turn rich land into barren desert. Again, the conservative influence of
+vegetation has sometimes for centuries retained as barren morass what
+might otherwise have become rich meadow or luxuriant woodland. The
+terms, therefore, are used in a strictly geological sense, to denote the
+removal and re-deposition of material, and its agency in preserving what
+lies beneath it.
+
+
+  (A) _The Air._
+
+  As a geological agent, the air brings about changes partly by its
+  component gases and partly by its movements. Its destructive action is
+  both chemical and mechanical. The chemical changes are probably
+  mainly, if not entirely, due to the moisture of the air, and
+  particularly to the gases, vapours and organic matter which the
+  moisture contains. Dry air seems to have little or no appreciable
+  influence in promoting these reactions. As the changes in question are
+  similar to those much more abundantly brought about by rain they are
+  described in the following section under the division on rain.
+
+  Among the more recognizable mechanical changes effected in the
+  atmosphere, one of considerable importance is to be seen in the result
+  of great and rapid changes of temperature. Heat expands rocks, while
+  cold contracts them. In countries with a great annual range of
+  temperature, considerable difficulty is sometimes experienced in
+  selecting building materials liable to be little affected by the
+  alternate expansion and contraction, which prevents the joints of
+  masonry from remaining close and tight. In dry tropical climates,
+  where the days are intensely hot and the nights extremely cold, the
+  rapid nocturnal contraction produces a strain so great as to rival
+  frost in its influence upon the surface of exposed rocks,
+  disintegrating them into sand, or causing them to crack or peel off in
+  skins or irregular pieces. Dr Livingstone found in Africa (12 deg. S.
+  lat., 34 deg. E. long.) that surfaces of rock which during the day
+  were heated up to 137 deg. Fahr., cooled so rapidly by radiation at
+  night that, unable to sustain the strain of contraction, they split
+  and threw off sharp angular fragments from a few ounces to 100 or 200
+  [lb] in weight. In temperate regions this action, though much less
+  pronounced, still makes itself felt. In these climates, however, and
+  still more in high latitudes, somewhat similar results are brought
+  about by frost.
+
+  By its motion in wind the air drives loose sand over rocks, and in
+  course of time abrades and smoothes them. "Desert polish" is the name
+  given to the characteristic lustrous surface thus imparted. Holes are
+  said to be drilled in window glass at Cape Cod by the same agency.
+  Cavities are now and then hollowed out of rocks by the gyration in
+  them of little fragments of stone or grains of sand kept in motion by
+  the wind. Hurricanes form important geological agents upon land in
+  uprooting trees, and thus sometimes impeding the drainage of a country
+  and giving rise to the formation of peat mosses.
+
+  The reproductive action of the air arises partly from the effect of
+  the chemical and mechanical disintegration involved in the process of
+  "weathering," and partly from the transporting power of wind and of
+  aerial currents. The layer of soil, which covers so much of the
+  surface of the land, is the result of the decay of the underlying
+  rocks, mingled with mineral matter blown over the ground by wind, or
+  washed thither by rain, and with the mouldering remains of plants and
+  animals. The extent to which fine dust may be transported over the
+  surface of the land can hardly be realized in countries clothed with a
+  covering of vegetation, though even there, in dry weather during
+  spring, clouds of dust may often be seen blown away by wind from bare
+  ploughed fields. Intercepted by the leaves of plants and washed down
+  to their roots by rain, this dust goes to increase the soil below. In
+  arid climates, where dust clouds are dense and frequent, enormous
+  quantities of fine mineral particles are thus borne along and
+  accumulated. The remarkable deposit of "Loess," which is sometimes
+  more than 1500 ft. thick and covers extensive areas in China and other
+  countries, is regarded as due to the drifting of dust by wind. Again
+  the dunes of sand so abundant along the inner side of sandy
+  sea-beaches in many different parts of the world are attributable to
+  the same action.
+
+
+  (B) _Water._
+
+  In treating of the epigene action of water in geological processes it
+  will be convenient to deal first with its operations in traversing the
+  land, and then with those which it performs in the sea. The
+  circulation of water from land to sea and again from sea to land
+  constitutes the fundamental cause of most of the daily changes by
+  which the surface of the land is affected.
+
+  1. _Rain._--Rain effects two kinds of changes upon the surface of the
+  land. It acts _chemically_ upon soils and stones, and sinking under
+  ground continues a great series of similar reactions there. It acts
+  _mechanically_, by washing away loose materials, and thus powerfully
+  affecting the contours of the land. Its chemical action depends mainly
+  upon the nature and proportion of the substances which, in descending
+  to the earth, it abstracts from the atmosphere. Rain always absorbs a
+  little air, which, in addition to its nitrogen and oxygen, contains
+  carbonic acid, and in minute proportions, sodium chloride, sulphuric
+  acid and other ingredients, especially inorganic dust, organic
+  particles and living germs. Probably the most generally efficient of
+  these constituents are oxygen, carbonic acid and organic matter. Armed
+  with these reagents, rain effects a chemical decomposition of the
+  rocks on which it falls, and through which it sinks underground. The
+  principal changes thus produced are as follows: (a) Oxidation.--Owing
+  to the prominence of oxygen in rain-water, and its readiness to unite
+  with any substance which can contain more of it, a thin oxidized
+  pellicle is formed on the surface of many rocks on which rain falls,
+  and this oxidized layer if not at once washed off, sinks deeper until
+  a crust is formed over the stone. A familiar illustration of this
+  action is afforded by the rust, or oxide, which forms on iron when
+  exposed to moisture, though this iron may be kept long bright if
+  allowed to remain screened from moist air and rain. (b)
+  Deoxidation.--Organic matter having an affinity for more oxygen
+  decomposes peroxides by depriving them of some part of their share of
+  that element and reducing them to protoxides. These changes are
+  especially noticeable among the iron oxides so abundantly diffused
+  among rocks. Hence rain-water, in sinking through soil and obtaining
+  such organic matter, becomes thereby a reducing agent. (c)
+  Solution.--This may take place either by the simple action of the
+  water, as in the solution of rock-salt, or by the influence of the
+  carbonic acid present in the rain. (d) Formation of Carbonates.--A
+  familiar example of the action of carbonic acid in rain is to be seen
+  in the corrosion of exposed marble slabs. The carbonic acid dissolves
+  some of the lime, which, as a bicarbonate, is held in solution in the
+  carbonated water, but is deposited again when the water loses its
+  carbonic acid or evaporates. It is not merely carbonates, however,
+  which are liable to this kind of destruction. Even silicates of lime,
+  potash and soda, combinations existing abundantly as constituents of
+  rocks, are attacked; their silica is liberated, and their alkalis or
+  alkaline earths, becoming carbonates, are removed in solution. (e)
+  Hydration.--Some minerals, containing little or no water, and
+  therefore called anhydrous, when exposed to the action of the
+  atmosphere, absorb water, or become hydrous, and are then usually more
+  prone to further change. Hence the rocks of which they form part
+  become disintegrated.
+
+  Besides the reactions here enumerated, a considerable amount of decay
+  may be observed as the result of the presence of sulphuric and nitric
+  acid in the air, especially in that of large towns and manufacturing
+  districts, where much coal is consumed. Metallic surfaces, as well as
+  various kinds of stone, are there corroded, while the mortar of walls
+  may often be observed to be slowly swelling out and dropping off,
+  owing to the conversion of the lime into sulphate. Great injury is
+  likewise done from a similar cause to marble monuments in exposed
+  graveyards.
+
+  The general result of the disintegrating action of the air and of
+  rain, including also that of plants and animals, to be noticed in the
+  sequel, is denoted by the term "weathering." The amount of decay
+  depends partly on conditions of climate, especially the range of
+  temperature, the abundance of moisture, height above the sea and
+  exposure to prevalent winds. Many rocks liable to be saturated with
+  rain and rapidly dried under a warm sun are apt to disintegrate at the
+  surface with comparative rapidity. The nature and progress of the
+  weathering are mainly governed by the composition and texture of the
+  rocks exposed to it. Rocks composed of particles liable to little
+  chemical change from the influence of moisture are best fitted to
+  resist weathering, provided they possess sufficient cohesion to
+  withstand the mechanical processes of disintegration. Siliceous
+  sandstones are excellent examples of this permanence. Consisting
+  wholly or mainly of the durable mineral quartz, they are sometimes
+  able so to withstand decay that buildings made of them still retain,
+  after the lapse of centuries, the chisel-marks of the builders. Some
+  rocks, which yield with comparative rapidity to the chemical attacks
+  of moisture, may show little or no mark of disintegration on their
+  surface. This is particularly the case with certain calcareous rocks.
+  Limestone when pure is wholly soluble in acidulated water. Rain
+  falling on such a rock removes some of it in solution, and will
+  continue to do so until the whole is dissolved away. But where a
+  limestone is full of impurities, a weathered crust of more or less
+  insoluble particles remains after the solution of the calcareous part
+  of the stone. Hence the relative purity of limestones may be roughly
+  determined by examining their weathered surfaces, where, if they
+  contain much sand, the grains will be seen projecting from the
+  calcareous matrix, and where, should the rock be very ferruginous, the
+  yellow hydrous peroxide, or ochre, will be found as a powdery crust.
+  In limestones containing abundant encrinites, shells, or other organic
+  remains, the weathered surface commonly presents the fossils standing
+  out in relief. The crystalline arrangement of the lime in the organic
+  structures enables them to resist disintegration better than the
+  general mechanically aggregated matrix of the rock. An experienced
+  fossil collector will always search well such weathered surfaces, for
+  he often finds there, delicately picked out by the weather, minute
+  and frail fossils which are wholly invisible on a freshly broken
+  surface of the stone. Many rocks weather with a thick crust, or even
+  decay inwards for many feet or yards. Basalt, for example, often shows
+  a yellowish-brown ferruginous layer on its surface, formed by the
+  conversion of its felspar into kaolin, and the removal of its calcium
+  silicate as carbonate, by the hydration of its olivine and augite and
+  their conversion into serpentine, or some other hydrous magnesian
+  silicate, and by the conversion of its magnetite into limonite.
+  Granite sometimes shows in a most remarkable way the distance to which
+  weathering can reach. It may occasionally be dug into for a depth of
+  20 or 30 ft., the quartz crystals and veins retaining their original
+  positions, while the felspar is completely kaolinized. It is to the
+  endlessly varied effects of weathering that the abundant fantastic
+  shapes assumed by crags and other rocky masses are due. Most varieties
+  of rock have their own characteristic modes of weathering, whereby
+  they may be recognized even from a distance. To some of these features
+  reference will be made in Part VIII.
+
+  The mechanical action of rain, which is intimately bound up with its
+  chemical action, consists in washing off the fine superficial
+  particles of rocks which have been corroded and loosened by the
+  process of weathering, and in thus laying open fresh portions to the
+  same influences of decay. The detritus so removed is partly carried
+  down into the soil which is thereby enriched, partly held in
+  suspension in the little runnels into which the rain-drops gather as
+  they begin to flow over the land, partly pushed downwards along the
+  surface of sloping ground. A good deal of it finds its way into the
+  nearest brooks and rivers, which are consequently made muddy by heavy
+  rain.
+
+  It is natural that a casual consideration of the subject should lead
+  to an impression that, though the general result of the fall of rain
+  upon a land-surface must lead to some amount of disintegration and
+  lowering of that surface, the process must be so slow and slight as
+  hardly to be considered of much importance among geological
+  operations. But further attention will show such an impression to be
+  singularly erroneous. It loses sight of the fact that a change which
+  may be hardly appreciable within a human lifetime, or even within the
+  comparatively brief span of geological time embraced in the compass of
+  human history, may nevertheless become gigantic in its results in the
+  course of immensely protracted periods. An instructive lesson in the
+  erosive action of rain may be found in the pitted and channelled
+  surface of ground lying under the drip of the eaves of a cottage. The
+  fragments of stone and pebbles of gravel that form part of the soil
+  can there be seen sticking out of the ground, because being hard they
+  resist the impetus of the falling drops, protecting for a time the
+  earth beneath them, while that which surrounded and covered them is
+  washed away. From this familiar illustration the observer may advance
+  through every stage in the disappearance of material which once
+  covered the surface, until he comes to examples where once continuous
+  and thick sheets of solid rock have been reduced to a few fragments or
+  have been entirely removed. Since the whole land surface over which
+  rain falls is exposed to this waste, the superficial covering of
+  decayed rock or soil, as Hutton insisted, is constantly, though
+  imperceptibly, travelling outward and downward to the sea. In this
+  process of transport rain is an important carrying agent, while at the
+  same time it serves to connect the work of the other disintegrating
+  forces, and to make it conducive to the general degradation of the
+  land. Though this decay is general and constant, it is obviously not
+  uniform. In some places where, from the nature of the rock, from the
+  flatness of the ground, or from other causes, rain works under great
+  difficulties, the rate of waste may be extremely slow. In other places
+  it may be rapid enough to be appreciable from year to year. A survey
+  of this department of geological activity shows how unequal wasting by
+  rain, combined with the operations of brooks and rivers, has produced
+  the details of the present relief of the land, those tracts where the
+  destruction has been greatest forming hollows and valleys, others,
+  where it has been less, rising into ridges and hills (Part VIII.).
+
+  Rain-action is not merely destructive, but is accompanied with
+  reproductive effects, chief of which is the formation of soil. In
+  favourable situations it has gathered together accumulations of loam
+  and earth from neighbouring higher ground, such as the "brick-earth,"
+  "head," and "rain-wash" of the south of England--earthy deposits,
+  sometimes full of angular stones, derived from the subaerial waste of
+  the rocks of the neighbourhood.
+
+  2. _Underground Water._--Of the rain which falls upon the land one
+  portion flows off into brooks and rivers by which the water is
+  conducted back to the ocean; the larger part, however, sinks into the
+  ground and disappears. It is this latter part which has now to be
+  considered. Over and above the proportion of the rainfall which is
+  absorbed by living vegetation and by the soil, there is a continual
+  filtering down of the water from the surface into the rocks that lie
+  below, where it partly lodges in pores and interstices, and partly
+  finds its way into subterranean joints and fissures, in which it
+  performs an underground circulation, and ultimately issues once more
+  at the surface in the form of springs (q.v.). In the course of this
+  circulation the water performs an important geological task. Not only
+  carrying down with it the substances which the rain has abstracted
+  from the air, but obtaining more acids and organic matter from the
+  soil, it is enabled to effect chemical changes in the rocks
+  underneath, and especially to dissolve limestone and other calcareous
+  formations. So considerable is the extent of this solution in some
+  places that the springs which come to the surface, and begin there to
+  evaporate and lose some of their carbonic acid, contain more dissolved
+  lime than they can hold. They consequently deposit it in the form of
+  calcareous tuff or sinter (q.v.). Other subterranean waters issue with
+  a large proportion of iron-salts in solution which form deposits of
+  ochre. The various mineral springs so largely made use of for the
+  mitigation or cure of diseases owe their properties to the various
+  salts which they have dissolved out of rocks underground. As the
+  result of prolonged subterranean solution in limestone districts,
+  passages and caves (q.v.), sometimes of great width and length, are
+  formed. When these lie near the surface their roofs sometimes fall in
+  and engulf brooks and rivers, which then flow for some way underground
+  until the tunnels conduct them back again to daylight on some lower
+  ground.
+
+  Besides its chemical activity water exerts among subterranean rocks a
+  mechanical influence which leads to important changes in the
+  topography of the surface. In removing the mineral matter, either in
+  solution or as fine sediment, it sometimes loosens the support of
+  overlying masses of rock which may ultimately give way on sloping
+  ground, and rush down the declivities in the form of landslips. These
+  destructive effects are specially frequent on the sides of valleys in
+  mountainous countries and on lines of sea-cliff.
+
+  3. _Brooks and Rivers._--As geological agents the running waters on
+  the face of the land play an important part in epigene changes. Like
+  rain and springs they have both a chemical and a mechanical action.
+  The latter receives most attention, as it undoubtedly is the more
+  important; but the former ought not to be omitted in any survey of the
+  general waste of the earth's surface. The water of rivers must possess
+  the powers of a chemical solvent like rain and springs, though its
+  actual work in this respect can be less easily measured, seeing that
+  river water is directly derived from rain and springs, and necessarily
+  contains in solution mineral substances supplied to it by them and not
+  by its own operation. Nevertheless, it is sometimes easy to prove that
+  streams dissolve chemically the rocks of their channels. Thus, in
+  limestone districts the base of the cliffs of river ravines may be
+  found eaten away into tunnels, arches, and overhanging projections,
+  presenting in their smooth surfaces a great contrast to the angular
+  jointed faces of the same rock, where now exposed to the influence
+  only of the weather on the higher parts of the cliff.
+
+  The mechanical action of rivers consists (a) in transporting mud,
+  sand, gravel and blocks of stone from higher to lower levels; (b) in
+  using these loose materials to widen and deepen their channels by
+  erosion; (c) in depositing their load of detritus wherever possible
+  and thus to make new geological formations.
+
+  (a) _Transporting Power._--River-water is distinguished from that of
+  springs by being less transparent, because it contains more or less
+  mineral matter in suspension, derived mainly from what is washed down
+  by rain, or carried in by brooks, but partly also from the abrasion of
+  the water-channels by the erosive action of the rivers themselves. The
+  progress of this burden of detritus may be instructively followed from
+  the mountain-tributaries of a river down to the mouth of the main
+  stream. In the high grounds the water-courses may be observed to be
+  choked with large fragments of rock disengaged from the cliffs and
+  crags on either side. Traced downwards the blocks are seen to become
+  gradually smaller and more rounded. They are ground against each
+  other, and upon the rocky sides and bottom of the channel, getting
+  more and more reduced as they descend, and at the same time abrading
+  the rocks over or against which they are driven. Hence a great deal of
+  debris is produced, and is swept along by the onward and downward
+  movement of the water. The finer portions, such as mud and fine sand,
+  are carried in suspension, and impart the characteristic turbidity to
+  river-water; the coarser sand and gravel are driven along the
+  river-bottom. The proportion of suspended mineral matter has been
+  ascertained with more or less precision for a number of rivers. As an
+  illustrative example of a river draining a vast area with different
+  climates, forms of surface and geological structure the Mississippi
+  may be cited. The average proportion of sediment in its water was
+  ascertained by Humphreys and Abbot to be 1/1500 by weight or 1/2900 by
+  volume. These engineers found that, in addition to this suspended
+  material, coarse detritus is constantly being pushed forward along the
+  bed of the river into the Gulf of Mexico, to an amount which they
+  estimated at about 750,000,000 cubic ft. of sand, earth and gravel;
+  they concluded that the Mississippi carries into the gulf every year
+  an amount of mechanically transported sediment sufficient to make a
+  prism one square mile in area and 268 ft. in height.
+
+  (b) _Excavating Power._--It is by means of the sand, gravel and stones
+  which they drive against the sides and bottoms of their channels that
+  streams have hollowed out the beds in which they flow. Not only is the
+  coarse detritus reduced in size by the friction of the stones against
+  each other, but, at the same time, these materials abrade the rocks
+  against which they are driven by the current. Where, owing to the
+  shape of the bottom of the channel, the stones are caught in eddies,
+  and are kept whirling round there, they become more and more worn down
+  themselves, and at the same time scour out basin-shaped cavities, or
+  "pot-holes," in the solid rock below. The uneven bed of a swiftly
+  flowing stream may in this way be honeycombed with such eroded basins
+  which coalesce and thus appreciably lower the surface of the bed. The
+  steeper the channel, other conditions being equal, the more rapid will
+  be the erosion. Geological structure also affects the character and
+  rate of the excavation. Where the rocks are so arranged as to favour
+  the formation and persistence of a waterfall, a long chasm may be
+  hollowed out like that of the Niagara below the falls, where a hard
+  thick bed of nearly flat limestone lies on softer and more easily
+  eroded shales. The latter are scooped out from underneath the
+  limestone, which from time to time breaks off in large masses and the
+  waterfall gradually retreats up stream, while the ravine is
+  proportionately lengthened. To the excavating power of rivers the
+  origin of the valley systems of the dry land must be mainly assigned
+  (see Part VIII.).
+
+  (c) _Reproductive Power._--So long as a stream flows over a steep
+  declivity its velocity suffices to keep the sediment in suspension,
+  but when from any cause, such as a diminution of slope, the velocity
+  is checked, the transporting power is lessened and the sediment begins
+  to fall to the bottom and to remain there. Hence various river-formed
+  or "alluvial" deposits are laid down. These sometimes cover
+  considerable spaces at the foot of mountains. The floors of valleys
+  are strewn with detritus, and their level may thereby be sensibly
+  raised. In floods the ground inundated on either side of a stream
+  intercepts some part of the detritus, which is then spread over the
+  flood-plain and gradually heightens it. At the same time the stream
+  continues to erode the channel, and ultimately is unable to reach the
+  old flood-plain. It consequently forms a new plain at a lower level,
+  and thus, by degrees, it comes to be flanked on either side by a
+  series of successive terraces or platforms, each of which marks one of
+  its former levels. Where a river enters a large body of water its
+  current is checked. Some of its sediment is consequently dropped, and
+  by slow accumulation forms a delta (q.v.). On land, every lake in
+  mountain districts furnishes instances of this kind of alluvium. But
+  the most important deltas are those formed in the sea at the mouths of
+  the larger rivers of the globe. Off many coast-lines the detritus
+  washed from the land gathers into bars, which enclose long strips of
+  water more or less completely separated from the sea outside and known
+  as lagoons. A chain of such lagoon-barriers stretches for hundreds of
+  miles round the Gulf of Mexico and the eastern shores of the United
+  States.
+
+  4. _Lakes._--These sheets of water, considered as a whole, do not
+  belong to the normal system of drainage on the land whereby valleys
+  are excavated. On the contrary they are exceptional to it; for the
+  constant tendency of running water is to fill them up, or to drain
+  them by wearing down the barriers that contain them at their outflow.
+  Some of them are referable to movements of the terrestrial crust
+  whereby depressions arise on the surface of the land, as has been
+  noted after earthquakes. Others have arisen from solution such as that
+  of rock-salt or of limestone, the removal of which by underground
+  water causes a subsidence of the ground above. A third type of
+  lake-basin occurs in regions that are now or have once been subject to
+  the erosive action of glaciers (see under next subdivision,
+  _Terrestrial Ice_). Many small lakes or tarns have been caused by the
+  deposit of debris across a valley as by landslips or moraines.
+  Considered from a geological point of view, lakes perform an important
+  function in regulating the drainage of the ground below their outfall
+  and diminishing the destructive effects of floods, in filtering the
+  water received from their affluent streams, and in providing
+  undisturbed areas of deposit in which thick and extensive lacustrine
+  formations may be accumulated. In the inland basins of some dry
+  climates the lakes are salt, owing to excess of evaporation, and their
+  bottoms become the sites of chemical deposits, particularly of
+  chlorides of sodium and magnesium, and calcium sulphate and carbonate.
+
+  5. _Terrestrial Ice._--Each of the forms assumed by frozen water has
+  its own characteristic action in geological processes. Frost has a
+  powerful influence in breaking up damp soils and surfaces of stone in
+  the pores or cracks of which moisture has lodged. The water in
+  freezing expands, and in so doing pushes asunder the component
+  particles of soil or stone, or widens the space between the walls of
+  joints or crevices. When the ice melts the loosened grains remain
+  apart ready to be washed away by rain or blown off by wind, while by
+  the widening of joints large blocks of rock are detached from the
+  faces of cliffs. Where rivers or lakes are frozen over the ice exerts
+  a marked pressure on their banks; and when it breaks up large sheets
+  of it are driven ashore, pushing up quantities of gravel and stones
+  above the level of the water. The piling up of the disrupted ice
+  against obstructions in rivers ponds back the water, and often leads
+  to destructive floods when the ice barriers break. Where the ice has
+  formed round boulders in shallow water, or at the bottom
+  ("anchor-ice"), it may lift these up when the frost gives way, and may
+  transport them for some distance. Ice formed in the atmosphere, and
+  descending to the ground in the form of hail, often causes great
+  destruction to vegetation and not infrequently to animal life. Where
+  the frozen moisture reaches the earth as snow, it serves to protect
+  rock, soil and vegetation from the effects of frost; but on sloping
+  ground it is apt to give rise to destructive avalanches or landslips,
+  while indirectly, by its rapid melting, it may cause serious floods in
+  rivers.
+
+  But the most striking geological work performed by terrestrial ice is
+  that achieved by glaciers (q.v.) and ice-sheets. These vast masses of
+  moving ice, when they descend from mountains where the steeper rocks
+  are clear of snow, receive on their surface the debris detached by
+  frost from the declivities above, and bear these materials to lower
+  levels or to the sea. Enormous quantities of rock-rubbish are thus
+  transported in the Alps and other high mountain ranges. When the ice
+  retreats the boulders carried by it are dropped where it melts, and
+  left there as memorials of the former extension of the glaciers.
+  Evidence of this nature proves the much wider extent of the Alpine ice
+  at a comparatively recent geological date. It can also be shown that
+  detritus from Scandinavia has been ice-borne to the south-east of
+  England and far into the heart of Europe.
+
+  The ice, by means of grains of sand and pieces of stone which it drags
+  along, scores, scratches and polishes the surfaces of rock underneath
+  it, and, in this way, produces the abundant fine sediment that gives
+  the characteristic milky appearance to the rivers that issue from the
+  lower ends of glaciers. By such long-continued attrition the rocks are
+  worn down, portions of them of softer nature, or where the ice acts
+  with especial vigour, are hollowed out into cavities which, on the
+  disappearance of the ice, may be filled with water and become tarns or
+  lakes. Rocks over which land-ice has passed are marked by a peculiar
+  smooth, flowing outline, which forms a contrast to the more rugged
+  surface produced by ordinary weathering. They are covered with
+  groovings, which range from the finest striae left by sharp grains of
+  sand to deep ruts ground out by blocks of stone. The trend of these
+  markings shows the direction in which the ice flowed. By their
+  evidence the position and movement of former glaciers in countries
+  from which the ice has entirely vanished may be clearly determined
+  (see GLACIAL PERIOD).
+
+  6. _The Sea._--The physical features of the sea are discussed in
+  separate articles (see OCEAN AND OCEANOGRAPHY). The sea must be
+  regarded as the great regulator of temperature and climate over the
+  globe, and as thus exerting a profound influence on the distribution
+  of plant and animal life. Its distinctly geological work is partly
+  erosive and partly reproductive. As an eroding agent it must to some
+  extent effect chemical decompositions in the rocks and sediments over
+  which it spreads; but these changes have not yet been satisfactorily
+  studied. Undoubtedly, its chief destructive power is of a mechanical
+  kind, and arises from the action of its waves in beating upon
+  shore-cliffs. By the alternate compression and expansion of the air in
+  crevices of the rocks on which heavy breakers fall, and by the
+  hydraulic pressure which these masses of sea-water exert on the walls
+  of the fissures into which they rush, large masses of rock are
+  loosened and detached, and caves and tunnels are drilled along the
+  base of sea-cliffs. Probably still more efficacious are the blows of
+  the loose shingle, which, caught up and hurled forward by the waves,
+  falls with great force upon the shore rocks, battering them as with a
+  kind of artillery until they are worn away. The smooth surfaces of the
+  rocks within reach of the waves contrasted with their angular forms
+  above that limit bear witness to the amount of waste, while the
+  rounded forms of the boulders and shingle show that they too are being
+  continually reduced in size. Thus the sea, by its action on the
+  coasts, produces much sediment, which is swept away by its waves and
+  currents and strewn over its floor. Besides this material, it is
+  constantly receiving the fine silt and sand carried down by rivers. As
+  the floor of the ocean is thus the final receptacle for the waste of
+  the land, it becomes the chief era on the surface of the globe for the
+  accumulation of new stratified formations. And such has been one of
+  its great functions since the beginning of geological time, as is
+  proved by the rocks that form the visible part of the earth's crust,
+  and consist in great part of marine deposits. Chemical precipitates
+  take place more especially in enclosed parts of the sea, where
+  concentration of the water by evaporation can take place, and where
+  layers of sodium chloride, calcium sulphate and carbonate, and other
+  salts are laid down. But the chief marine accumulations are of
+  detrital origin. Near the land and for a variable distance extending
+  sometimes to 200 or 300 m. from shore the deposits consist chiefly of
+  sediments derived from the waste of the land, the finer silts being
+  transported farthest from their source. At greater depths and
+  distances the ocean floor receives a slow deposit of exceedingly fine
+  clay, which is believed to be derived from the decomposition of pumice
+  and volcanic dust from insular or submarine volcanoes. Wide tracts of
+  the bottom are covered with various forms of ooze derived from the
+  accumulation of the remains of minute organisms.
+
+
+  (C) _Life._
+
+  Among the agents by which geological changes are carried on upon the
+  surface of the globe living organisms must be enumerated. Both plants
+  and animals co-operate with the inorganic agents in promoting the
+  degradation of the land. In some cases, on the other hand, they
+  protect rocks from decay, while, by the accumulation of their remains,
+  they give rise to extensive formations both upon the land and in the
+  sea. Their operations may hence be described as alike destructive,
+  conservative and reproductive. Under this heading also the influence
+  of Man as a geological agent deserves notice.
+
+  (a) _Plants._--Vegetation promotes the disintegration of rocks and
+  soil in the following ways: (1) By keeping the surfaces of stone
+  moist, and thus promoting both mechanical and chemical dissolution, as
+  is especially shown by liverworts, mosses and other moisture-loving
+  plants. (2) By producing through their decay carbonic and other
+  acids, which, together with decaying organic matter taken up by
+  passing moisture, become potent in effecting the chemical
+  decomposition of rocks and in promoting the disintegration of soils.
+  (3) By inserting their roots or branches between joints of rock, which
+  are thereby loosened, so that large slices may be eventually wedged
+  off. (4) By attracting rain, as thick woods, forests and peat-mosses
+  do, and thus accelerating the general waste of a country by running
+  water. (5) By promoting the decay of diseased and dead plants and
+  animals, as when fungi overspread a damp rotting tree or the carcase
+  of a dead animal.
+
+  That plants also exert a conservative influence on the surface of the
+  land is shown in various ways. (1) The formation of a stratum of turf
+  protects the soil and rocks underneath from being rapidly
+  disintegrated and washed away by atmospheric action. (2) Many plants,
+  even without forming a layer of turf, serve by their roots or branches
+  to protect the loose sand or soil on which they grow from being
+  removed by wind. The common sand-carex and other arenaceous plants
+  bind the loose sand-dunes of our coasts, and give them a permanence,
+  which would at once be destroyed were the sand laid bare again to
+  storms. The growth of shrubs and brushwood along the course of a
+  stream not only keeps the alluvial banks from being so easily
+  undermined and removed as would otherwise be the case, but serves to
+  arrest the sediment in floods, filtering the water and thereby adding
+  to the height of the flood plain. (3) Some marine plants, like the
+  calcareous nullipores, afford protection to shore rocks by covering
+  them with a hard incrustation. The tangles and smaller Fuci which grow
+  abundantly on the littoral zone break the force of the waves or
+  diminish the effects of ground swell. (4) Forests and brushwood
+  protect the soil, especially on slopes, from being washed away by rain
+  or ploughed up by avalanches.
+
+  Plants contribute by the aggregation of their remains to the formation
+  of stratified deposits. Some marine algae which secrete carbonate of
+  lime not only encrust rocks but give rise to sheets of submarine
+  limestone. An analogous part is played in fresh-water lakes by various
+  lime-secreting plants, such as _Chara_. Long-continued growth of
+  vegetation has, in some regions, produced thick accumulations of a
+  dark loam, as in the black cotton soil (_regur_) of India, and the
+  black earth (_tchernozom_) of Russia. Peat-mosses are formed in
+  temperate and arctic climates by the growth of marsh-loving plants,
+  sometimes to a thickness of 40 or 50 ft. In tropical regions the
+  mangrove swamps on low moist shores form a dense jungle, sometimes 20
+  m. broad, which protects these shores from the sea until, by the
+  arrest of sediment and the constant contribution of decayed
+  vegetation, the spongy ground is at last turned into firm soil. Some
+  plants (diatoms) can abstract silica and build it into their
+  framework, so that their remains form a siliceous deposit or ooze
+  which covers spaces of the deep sea-floor estimated at more than ten
+  millions of square miles in extent.
+
+  (b) _Animals._--These exert a destructive influence in the following
+  ways: (1) By seriously affecting the composition and arrangement of
+  the vegetable soil. Worms bring up the lower portions of the soil to
+  the surface, and while thus promoting its fertility increase its
+  liability to be washed away by rain. Burrowing animals, by throwing up
+  the soil and subsoil, expose these to be dried and blown away by the
+  wind. At the same time their subterranean passages serve to drain off
+  the superficial water and to injure the stability of the surface of
+  the ground above them. In Britain the mole and rabbit are familiar
+  examples. (2) By interfering with or even diverting the flow of
+  streams. Thus beaver-dams check the current of water-courses,
+  intercept floating materials, and sometimes turn streams into new
+  channels. The embankments of the Mississippi are sometimes weakened to
+  such an extent by the burrowings of the cray-fish as to give way and
+  allow the river to inundate the surrounding country. Similar results
+  have happened in Europe from subterranean operations of rats. (3) Some
+  mollusca bore into stone or wood and by the number of contiguous
+  perforations greatly weaken the material. (4) Many animals exercise a
+  ruinously destructive influence upon vegetation. Of the numerous
+  plagues of this kind the locust, phylloxera and Colorado beetle may be
+  cited.
+
+  The most important geological function performed by animals is the
+  formation of new deposits out of their remains. It is chiefly by the
+  lower grades of the animal kingdom that this work is accomplished,
+  especially by molluscs, corals and foraminifera. Shell-banks are
+  formed abundantly in such comparatively shallow and enclosed basins as
+  that of the North Sea, and on a much more extensive scale on the floor
+  of the West Indian seas. By the coral polyps thick masses of
+  limestones have been built up in the warmer seas of the globe (see
+  CORAL REEFS). The floor of the Atlantic and other oceans is covered
+  with a fine calcareous ooze derived mainly from the remains of
+  foraminifera, while in other regions the bottom shows a siliceous ooze
+  formed almost entirely of radiolaria. Vertebrate animals give rise to
+  phosphatic deposits formed sometimes of their excrement, as in guano
+  and coprolites, sometimes of an accumulation of their bones.
+
+  (c) _Man._--No survey of the geological workings of plant and animal
+  life upon the surface of the globe can be complete which does not take
+  account of the influence of man--an influence of enormous and
+  increasing consequence in physical geography, for man has introduced,
+  as it were, an element of antagonism to nature. His interference shows
+  itself in his relations to climate, where he has affected the
+  meteorological conditions of different countries: (1) By removing
+  forests, and laying bare to the sun and winds areas which were
+  previously kept cool and damp under trees, or which, lying on the lee
+  side, were protected from tempests. It is supposed that the wholesale
+  destruction of the woodlands formerly existing in countries bordering
+  the Mediterranean has been in part the cause of the present
+  desiccation of these districts. (2) By drainage, whereby the
+  discharged rainfall is rapidly removed, and the evaporation is
+  lessened, with a consequent diminution of rainfall and some increase
+  in the general temperature of a country. (3) By the other processes of
+  agriculture, such as the transformation of moor and bog into
+  cultivated land, and the clothing of bare hillsides with green crops
+  or plantations of coniferous and hardwood trees.
+
+  Still more obvious are the results of human interference with the flow
+  of water: (1) By increasing or diminishing the rainfall man directly
+  affects the volume of rivers. (2) By his drainage operations he makes
+  the rain to run off more rapidly than before, and thereby increases
+  the magnitude of floods and of the destruction caused by them. (3) By
+  wells, bores, mines, or other subterranean works he interferes with
+  the underground waters, and consequently with the discharge of
+  springs. (4) By embanking rivers he confines them to narrow channels,
+  sometimes increasing their scour, and enabling them to carry their
+  sediment further seaward, sometimes causing them to deposit it over
+  the plains and raise their level. (5) By his engineering operations
+  for water-supply he abstracts water from its natural basins and
+  depletes the streams.
+
+  In many ways man alters the aspect of a country: (1) By changing
+  forest into bare mountain, or clothing bare mountains with forest. (2)
+  By promoting the growth or causing the removal of peat-mosses. (3) By
+  heedlessly uncovering sand-dunes, and thereby setting in motion a
+  process of destruction which may convert hundreds of acres of fertile
+  land into waste sand, or by prudently planting the dunes with
+  sand-loving vegetation and thus arresting their landward progress. (4)
+  By so guiding the course of rivers as to make them aid him in
+  reclaiming waste land, and bringing it under cultivation. (5) By piers
+  and bulwarks, whereby the ravages of the sea are stayed, or by the
+  thoughtless removal from the beach of stones which the waves had
+  themselves thrown up, and which would have served for a time to
+  protect the land. (6) By forming new deposits either designedly or
+  incidentally. The roads, bridges, canals, railways, tunnels, villages
+  and towns with which man has covered the surface of the land will in
+  many cases form a permanent record of his presence. Under his hand the
+  whole surface of civilized countries is very slowly covered with a
+  stratum, either formed wholly by him or due in great measure to his
+  operations and containing many relics of his presence. The soil of
+  ancient towns has been increased to a depth of many feet by their
+  successive destructions and renovations.
+
+  Perhaps the most subtle of human influences are to be seen in the
+  distribution of plant and animal life upon the globe. Some of man's
+  doings in this domain are indeed plain enough, such as the extirpation
+  of wild animals, the diminution or destruction of some forms of
+  vegetation, the introduction of plants and animals useful to himself,
+  and especially the enormous predominance given by him to the cereals
+  and to the spread of sheep and cattle. But no such extensive
+  disturbance of the normal conditions of the distribution of life can
+  take place without carrying with it many secondary effects, and
+  setting in motion a wide cycle of change and of reaction in the animal
+  and vegetable kingdoms. For example, the incessant warfare waged by
+  man against birds and beasts of prey in districts given up to the
+  chase leads sometimes to unforeseen results. The weak game is allowed
+  to live, which would otherwise be killed off and give more room for
+  the healthy remainder. Other animals which feed perhaps on the same
+  materials as the game are by the same cause permitted to live
+  unchecked, and thereby to act as a further hindrance to the spread of
+  the protected species. But the indirect results of man's interference
+  with the regime of plants and animals still require much prolonged
+  observation.
+
+
+PART V.--GEOTECTONIC OR STRUCTURAL GEOLOGY
+
+From a study of the nature and composition of minerals and rocks, and an
+investigation of the different agencies by which they are formed and
+modified, the geologist proceeds to inquire how these materials have
+been put together so as to build up the visible part of the earth's
+crust. He soon ascertains that they have not been thrown together wholly
+at random, but that they show a recognizable order of arrangement. Some
+of them, especially those of most recent growth, remain in their
+original condition and position, but, in proportion to their antiquity,
+they generally present increasing alteration, until it may no longer be
+possible to tell what was their pristine state. As by far the largest
+accessible portion of the terrestrial crust consists of stratified
+rocks, and as these furnish clear evidence of most of the modifications
+to which they have been subjected in the long course of geological
+history, it is convenient to take them into consideration first. They
+possess a number of structures which belong to the original conditions
+in which they were accumulated. They present in addition other
+structures which have been superinduced upon them, and which they share
+with the unstratified or igneous rocks.
+
+
+1. ORIGINAL STRUCTURES
+
+(a) _Stratified Rocks._--This extensive and important series is above
+all distinguished by possessing a prevailing stratified arrangement.
+Their materials have been laid down in laminae, layers and strata, or
+beds, pointing generally to the intermittent deposition of the sediments
+of which they consist. As this stratification was, as a rule, originally
+nearly or quite horizontal, it serves as a base from which to measure
+any subsequent disturbance which the rocks have undergone. The
+occurrence of false-bedding, i.e. bands of inclined layers between the
+normal planes of stratification, does not form any real exception; but
+indicates the action of shifting currents whereby the sediment was
+transported and thrown down. Other important records of the original
+conditions of deposit are supplied by ripple-marks, sun-cracks,
+rain-prints and concretions.
+
+  From the nature of the material further light is cast on the
+  geographical conditions in which the strata were accumulated. Thus,
+  conglomerates indicate the proximity of old shore-lines, sandstones
+  mark deposits in comparatively shallow water, clays and shales point
+  to the tranquil accumulation of fine silt at a greater depth and
+  further from land, while fossiliferous limestones bear witness to
+  clearer water in which organisms flourished at some distance from
+  deposits of sand and mud. Again, the alternation of different kinds of
+  sediment suggests a variability in the conditions of deposition, such
+  as a shifting of the sediment-bearing currents and of the areas of
+  muddy and clear water. A thick group of conformable strata, that is, a
+  series of deposits which show no discordance in their stratification,
+  may usually be regarded as having been laid down on a sea-floor that
+  was gently sinking. Here and there evidence is obtainable of the
+  limits or of the progress of the subsidence by what is called
+  "overlap." Of the absolute length of time represented by any strata or
+  groups of strata no satisfactory estimates can yet be formed. Certain
+  general conclusions may indeed be drawn, and comparisons may be made
+  between different series of rocks. Sandstones full of false-bedding
+  were probably accumulated more rapidly than finely-laminated shales or
+  clays. It is not uncommon in certain Carboniferous formations to find
+  coniferous and other trunks embedded in sandstone. Some of these trees
+  seem to have been carried along and to have sunk, their heavier or
+  root end touching the bottom and their upper end slanting upward in
+  the direction of the current, exactly as in the case of the snags of
+  the Mississippi. In other cases the trees have been submerged while
+  still in their positions of growth. The continuous deposit of sand at
+  last rose above the level of the trunks and buried them. It is clear
+  then that the rate of deposit must have been sometimes sufficiently
+  rapid to allow sand to accumulate to a depth of 30 ft. or more before
+  the decay of the wood. Modern instances are known where, under certain
+  circumstances, submerged trees may last for some centuries, but even
+  the most durable must decay in what, after all, is a brief space of
+  geological time. Since continuous layers of the same kind of deposit
+  suggest a persistence of geological conditions, while numerous
+  alternations of different kinds of sedimentary matter point to
+  vicissitudes or alternations of conditions, it may be supposed that
+  the time represented by a given thickness of similar strata was less
+  than that shown by the same thickness of dissimilar strata, because
+  the changes needed to bring new varieties of sediment into the area of
+  deposit would usually require the lapse of some time for their
+  completion. But this conclusion may often be erroneous. It will be
+  best supported when, from the very nature of the rocks, wide
+  variations in the character of the water-bottom can be established.
+  Thus a group of shales followed by a fossiliferous limestone would
+  almost always mark the lapse of a much longer period than an equal
+  depth of sandy strata. A thick mass of limestone, made up of organic
+  remains which lived and died upon the spot, and whose remains are
+  crowded together generation above generation, must have demanded many
+  years or centuries for its formation.
+
+  But in all speculations of this kind we must bear in mind that the
+  length of time represented by a given depth of strata is not to be
+  estimated merely from their thickness or lithological character. The
+  interval between the deposit of two successive laminae of shale may
+  have been as long as, or even longer than, that required for the
+  formation of one of the laminae. In like manner the interval needed
+  for the transition from one stratum or kind of strata to another may
+  often have been more than equal to the time required for the formation
+  of the strata on either side. But the relative chronological
+  importance of the bars or lines in the geological record can seldom be
+  satisfactorily discussed merely on lithological grounds. This must
+  mainly be decided on the evidence of organic remains, as shown in
+  Part VI., where the grouping of the stratified rocks into formations
+  and systems is described.
+
+(b) _Igneous Rocks._--As part of the earth's crust these rocks present
+characters by which they are strongly differentiated from the stratified
+series. While the broad petrographical distinctions of their several
+varieties remain persistent, they present sufficient local variations of
+type to point to the existence of what have been called petrographic
+provinces, in each of which the eruptive masses are connected by a
+general family relationship, differing more or less from that of a
+neighbouring province. In each region presenting a long chronological
+series of eruptive rocks a petrographical sequence can be traced, which
+is observed to be not absolutely the same everywhere, though its general
+features may be persistent. The earliest manifestations of eruptive
+material in any district appear to have been most frequently of an
+intermediate type between acid and basic, passing thence into a
+thoroughly acid series and concluding with an effusion of basic
+material.
+
+Considered as part of the architecture of the crust of the earth,
+igneous rocks are conveniently divisible into two great series: (1)
+those bodies of material which have been injected into the crust and
+have solidified there, and (2) those which have reached the surface and
+have been ejected there, either in a molten state as lava or in a
+fragmental form as dust, ashes and scoriae. The first of these divisions
+represents the plutonic, intrusive or subsequent phase of eruptivity;
+the second marks the volcanic, interstratified or contemporaneous phase.
+
+  1. The plutonic or intrusive rocks, which have been forced into the
+  crust and have consolidated there, present a wide range of texture
+  from the most coarse-grained granites to the most perfect natural
+  glass. Seeing that they have usually cooled with extreme slowness
+  underground, they are as a general rule more largely crystalline than
+  the volcanic series. The form assumed by each individual body of
+  intrusive material has depended upon the shape of the space into which
+  it has been injected, and where it has cooled and become solid. This
+  shape has been determined by the local structure of the earth's crust
+  on the one hand and by the energy of the eruptive force on the other.
+  It offers a convenient basis for the classification of the intrusive
+  rocks, which, as part of the framework of the crust, may thus be
+  grouped according to the shape of the cavity which received them, as
+  bosses, sills, dikes and necks.
+
+  Bosses, or stocks, are the largest and most shapeless extravasations
+  of erupted material. They include the great bodies of granite which,
+  in most countries of the world, have risen for many miles through the
+  stratified formations and have altered the rocks around them by
+  contact-metamorphism. Sills, or intrusive sheets, are bed-like masses
+  which have been thrust between the planes of sedimentary or even of
+  igneous rocks. The term laccolite has been applied to sills which are
+  connected with bosses. Intrusive sheets are distinguishable from true
+  contemporaneously intercalated lavas by not keeping always to the same
+  platform, but breaking across and altering the contiguous strata, and
+  by the closeness of their texture where they come in contact with the
+  contiguous rocks, which, being cold, chilled the molten material and
+  caused it to consolidate on its outer margins more rapidly than in its
+  interior. Dikes or veins are vertical walls or ramifying branches of
+  intrusive material which has consolidated in fissures or irregular
+  clefts of the crust. Necks are volcanic chimneys which have been
+  filled up with erupted material, and have now been exposed at the
+  surface after prolonged denudation has removed not only the
+  superficial volcanic masses originally associated with them, but also
+  more or less of the upper part of the vents. Plutonic rocks do not
+  present evidence of their precise geological age. All that can be
+  certainly affirmed from them is that they must be younger than the
+  rocks into which they have been intruded. From their internal
+  structure, however, and from the evidence of the rocks associated with
+  them, some more or less definite conjectures may be made as to the
+  limits of time within which they were probably injected.
+
+  2. The interstratified or volcanic series is of special importance in
+  geology, inasmuch as it contains the records of volcanic action during
+  the past history of the globe. It was pointed out in Part I. that
+  while towards the end of the 18th and in the beginning of the 19th
+  century much attention was paid by Hutton and his followers to the
+  proofs of intrusion afforded by what they called the "unerupted lavas"
+  within the earth's crust, these observers lost sight of the
+  possibility that some of these rocks might have been erupted at the
+  surface, and might thus be chronicles of volcanic action in former
+  geological periods. It is not always possible to satisfactorily
+  discriminate between the two types of contemporaneously intercalated
+  and subsequently injected material. But rocks of the former type have
+  not broken into or involved the overlying strata, and they are usually
+  marked by the characteristic structures of superficial lavas and by
+  their association with volcanic tuffs. By means of the evidence which
+  they supply, it has been ascertained that volcanic action has been
+  manifested in the globe since the earliest geological periods. In the
+  British Isles, for example, the volcanic record is remarkably full for
+  the long series of ages from Cambrian to Permian time, and again for
+  the older Tertiary period.
+
+
+2. SUBSEQUENTLY INDUCED STRUCTURES
+
+After their accumulation, whether as stratified or eruptive masses, all
+kinds of rocks have been subject to various changes, and have acquired
+in consequence a variety of superinduced structures. It has been pointed
+out in the part of this article dealing with dynamical geology that one
+of the most important forms of energy in the evolution of geological
+processes is to be found in the movements that take place within the
+crust of the earth. Some of these movements are so slight as to be only
+recognizable by means of delicate instruments; but from this inferior
+limit they range up to gigantic convulsions by which mountain-chains are
+upheaved. The crust must be regarded as in a perpetual state of strain,
+and its component materials are therefore subject to all the effects
+which flow from that condition. It is the one great object of the
+geotectonic division of geology to study the structures which have been
+developed in consequence of earth-movements, and to discover from this
+investigation the nature of the processes whereby the rocks of the crust
+have been brought into the condition and the positions in which we now
+find them. The details of this subject will be found in separate
+articles descriptive of each of the technical terms applied to the
+several kinds of superinduced structures. All that need be offered here
+is a general outline connecting the several portions of the subject
+together.
+
+  One of the most universal of these later structures is to be seen in
+  the divisional planes, usually vertical or highly inclined, by which
+  rocks are split into quadrangular or irregularly shaped blocks. To
+  these planes the name of joints has been given. They are of prime
+  importance from an industrial point of view, seeing that the art of
+  quarrying consists mainly in detecting and making proper use of them.
+  Their abundance in all kinds of rocks, from those of recent date up to
+  those of the highest antiquity, affords a remarkable testimony to the
+  strains which the terrestrial crust has suffered. They have arisen
+  sometimes from tension, such as that caused by contraction from the
+  drying and consolidation of an aqueous sediment or from the cooling of
+  a molten mass; sometimes from torsion during movements of the crust.
+
+  Although the stratified rocks were originally deposited in a more or
+  less nearly horizontal position on the floor of the sea, where now
+  visible on the dry land they are seldom found to have retained their
+  flatness. On the contrary, they are seen to have been generally tilted
+  up at various angles, sometimes even placed on end (crop, dip,
+  strike). When a sufficiently large area of ground is examined, the
+  inclination into which the strata have been thrown may be observed not
+  to continue far in the same direction, but to turn over to the
+  opposite or another quarter. It can then be seen that in reality the
+  rocks have been thrown into undulations. From the lowest and flattest
+  arches where the departure from horizontality may be only trifling,
+  every step may be followed up to intense curvature, where the strata
+  have been compressed and plicated as if they had been piles of soft
+  carpets (anticline, syncline, monocline, geo-anticline, geo-syncline,
+  isoclinal, plication, curvature, quaquaversal). It has further
+  happened abundantly all over the surface of the globe that relief from
+  internal strain in the crust has been obtained by fracture, and the
+  consequent subsidence or elevation of one or both sides of the
+  fissure. The differential movement between the two sides may be
+  scarcely perceptible in the feeblest dislocation, but in the extreme
+  cases it may amount to many thousand feet (fault, fissure,
+  dislocation, hade, slickensides). The great faults in a country are
+  among its most important structural features, and as they not
+  infrequently continue to be lines of weakness in the crust along which
+  sudden slipping may from time to time take place, they become the
+  lines of origin of earthquakes. The San Francisco earthquake of 1906,
+  already cited, affords a memorable illustration of this connexion.
+
+  It is in a great mountain-chain that the extraordinary complication of
+  plicated and faulted structures in the crust of the earth can be most
+  impressively beheld. The combination of overturned folds with rupture
+  has been already referred to as a characteristic feature in the Alps
+  (Part IV.). The gigantic folds have in many places been pushed over
+  each other so as to lie almost flat, while the upper limb has not
+  infrequently been driven for many miles beyond the lower by a rupture
+  along the axis. In this way successive slices of a thick series of
+  formations have been carried northwards on the northern slope of the
+  Alps, and have been piled so abnormally above each other that some of
+  their oldest members recur several times on different thrust-planes,
+  the whole being underlain by Tertiary strata (see ALPS). Further
+  proof of the colossal compression to which the rocks have been
+  subjected is afforded by their intense crumpling and corrugation, and
+  by the abundantly faulted and crushed condition to which they have
+  been reduced. Similar evidence as to stresses in the terrestrial crust
+  and the important changes which they produce among the rocks may also
+  be obtained on a smaller scale in many non-mountainous countries.
+
+  Another marked result of the compression of the terrestrial crust has
+  been induced in some rocks by the production of the fissile structure
+  which is typically shown in roofing-slate (cleavage). Closely
+  connected with this internal rearrangement has been the development of
+  microscopic microlites or crystals (rutile, mica, &c.) in argillaceous
+  slates which were undoubtedly originally fine marine mud and silt.
+  From this incipient form of metamorphism successive stages may be
+  traced through the various kinds of argillite and phyllite into
+  mica-schist, and thence into more crystalline gneissoid varieties
+  (foliation, slate, mica-schist, gneiss). The Alps afford excellent
+  illustrations of these transformations.
+
+  The fissures produced in the crust are sometimes clean, sharply
+  defined divisional planes, like cracks across a pane of glass. Much
+  more usually, however, the rocks on either side have been broken up by
+  the friction of movement, and the fault is marked by a variable
+  breadth of this broken material. Sometimes the walls have separated
+  and molten rock has risen from below and solidified between them as a
+  dike. Occasionally the fissures have opened to the surface, and have
+  been filled in from above with detritus, as in the sandstone-dikes of
+  Colorado and California. In mineral districts the fissures have been
+  filled with various spars and ores, forming what are known as mineral
+  veins.
+
+  Where one series of rocks is covered by another without any break or
+  discordance in the stratification they are said to be conformable. But
+  where the older series has been tilted up or visibly denuded before
+  being overlain by the younger, the latter is termed unconformable.
+  This relation is one of the greatest value in structural geology, for
+  it marks a gap in the geological record, which may represent a vast
+  lapse of time not there recorded by strata.
+
+
+PART VI.--PALEONTOLOGICAL GEOLOGY
+
+This division of the science deals with fossils, or the traces of plants
+and animals preserved in the rocks of the earth's crust, and endeavours
+to gather from them information as to the history of the globe and its
+inhabitants. The term "fossil" (Lat. _fossilis_, from _fodere_, to dig
+up), meaning literally anything "dug up," was formerly applied
+indiscriminately to any mineral substance taken out of the earth's
+crust, whether organized or not. Since the time of Lamarck, however, the
+meaning of the word has been restricted, so as to include only the
+remains or traces of plants and animals preserved in any natural
+formation whether hard rock or superficial deposit. It includes not
+merely the petrified structures of organisms, but whatever was directly
+connected with or produced by these organisms. Thus the resin which was
+exuded from trees of long-perished forests is as much a fossil as any
+portion of the stem, leaves, flowers or fruit, and in some respects is
+even more valuable to the geologist than more determinable remains of
+its parent trees, because it has often preserved in admirable perfection
+the insects which flitted about in the woodlands. The burrows and trails
+of a worm preserved in sandstone and shale claim recognition as fossils,
+and indeed are commonly the only indications to be met with of the
+existence of annelid life among old geological formations. The droppings
+of fishes and reptiles, called coprolites, are excellent fossils, and
+tell their tale as to the presence and food of vertebrate life in
+ancient waters. The little agglutinated cases of the caddis-worm remain
+as fossils in formations from which, perchance, most other traces of
+life may have passed away. Nay, the very handiwork of man, when
+preserved in any natural manner, is entitled to rank among fossils; as
+where his flint-implements have been dropped into the pre-historic
+gravels of river-valleys or where his canoes have been buried in the
+silt of lake-bottoms.
+
+  A study of the land-surfaces and sea-floors of the present time shows
+  that there are so many chances against the conservation of the remains
+  of either terrestrial or marine animals and plants that if, as is
+  probable, the same conditions existed in former geological periods, we
+  should regard the occurrence of organic remains among the stratified
+  formations of the earth's crust as generally the result of various
+  fortunate accidents.
+
+  Let us consider, in the first place, the chances for the preservation
+  of remains of the present fauna and flora of a country. The surface of
+  the land may be densely clothed with forest and abundantly peopled
+  with animal life. But the trees die and moulder into soil. The
+  animals, too, disappear, generation after generation, and leave few or
+  no perceptible traces of their existence. If we were not aware from
+  authentic records that central and northern Europe were covered with
+  vast forests at the beginning of our era, how could we know this fact?
+  What has become of the herds of wild oxen, the bears, wolves and other
+  denizens of primeval Europe? How could we prove from the examination
+  of the surface soil of any country that those creatures had once
+  abounded there? The conditions for the preservation of any relics of
+  the plant and animal life of a terrestrial surface must obviously be
+  always exceptional. They are supplied only where the organic remains
+  can be protected from the air and superficial decay. Hence they may be
+  observed in (1) the deposits on the floors of lakes; (2) in
+  peat-mosses; (3) in deltas at river-mouths; and (4) under the
+  stalagmite of caverns in limestone districts. But in these and other
+  favourable places a mere infinitesimal fraction of the fauna or flora
+  of a land-surface is likely to be entombed or preserved.
+
+  In the second place, although in the sea the conditions for the
+  preservation of organic remains are in many respects more favourable
+  than on land, they are apt to be frustrated by many adverse
+  circumstances. While the level of the land remains stationary, there
+  can be but little effective entombment of marine organisms in littoral
+  deposits; for only a limited accumulation of sediment will be formed
+  until subsidence of the sea-floor takes place. In the trifling beds of
+  sand or gravel thrown up on a stationary shore, only the harder and
+  more durable forms of life, such as gastropods and lamellibranchs,
+  which can withstand the triturating effects of the beach waves, are
+  likely to remain uneffaced.
+
+  Below tide-marks, along the margin of the land where sediment is
+  gradually deposited, the conditions are more favourable for the
+  preservation of marine organisms. In the sheets of sand and mud there
+  laid down the harder parts of many forms of life may be entombed and
+  protected from decay. But only a small proportion of the total marine
+  fauna may be expected to appear in such deposits. At the best, merely
+  littoral and shallow-water forms will occur, and, even under the most
+  favourable conditions, they will represent but a fraction of the whole
+  assemblage of life in these juxta-terrestrial parts of the ocean. As
+  we recede from the land the rate of deposition of sediment on the
+  sea-floor must become feebler, until, in the remote central abysses,
+  it reaches a hardly appreciable minimum. Except, therefore, where some
+  kind of ooze or other deposit is accumulating in these more pelagic
+  regions, the conditions must be on the whole unfavourable for the
+  preservation of any adequate representation of the deep-sea fauna.
+  Hard durable objects, such as teeth and bones, may slowly accumulate,
+  and be protected by a coating of peroxide of manganese, or of some of
+  the silicates now forming here and there over the deep-sea bottom; or
+  the rate of growth of the abysmal deposit may be so tardy that most of
+  the remains of at least the larger animals will disappear, owing to
+  decay, before they can be covered up and preserved. Any such deep-sea
+  formation, if raised into land, would supply but a meagre picture of
+  the whole life of the sea.
+
+  It would thus appear that the portion of the sea-floor best suited for
+  receiving and preserving the most varied assemblage of marine organic
+  remains is the area in front of the land, to which rivers and currents
+  bring continual supplies of sediment. The most favourable conditions
+  for the accumulation of a thick mass of marine fossiliferous strata
+  will arise when the area of deposit is undergoing a gradual
+  subsidence. If the rate of depression and that of deposit were equal,
+  or nearly so, the movement might proceed for a vast period without
+  producing any great apparent change in marine geography, and even
+  without seriously affecting the distribution of life over the
+  sea-floor within the area of subsidence. Hundreds or thousands of feet
+  of sedimentary strata might in this way be heaped up round the
+  continents, containing a fragmentary series of organic remains
+  belonging to those forms of comparatively shallow-water life which had
+  hard parts capable of preservation. There can be little doubt that
+  such has, in fact, been the history of the main mass of stratified
+  formations in the earth's crust. By far the largest proportion of
+  these piles of marine strata has unquestionably been laid down in
+  water of no great depth within the area of deposit of terrestrial
+  sediment. The enormous thickness to which they attain seems only
+  explicable by prolonged and repeated movements of subsidence,
+  interrupted, however, as we know, by other movements of a contrary
+  kind.
+
+  Since the conditions for the preservation of organic remains exist
+  more favourably under the sea than on land, marine organisms must be
+  far more abundantly conserved than those of the land. This is true
+  to-day, and has, as far as known, been true in all past geological
+  time. Hence for the purposes of the geologist the fossil remains of
+  marine forms of life far surpass all others in value. Among them there
+  will necessarily be a gradation of importance, regulated chiefly by
+  their relative abundance. Now, of all the marine tribes which live
+  within the juxta-terrestrial belt of sedimentation, unquestionably the
+  Mollusca stand in the place of pre-eminence as regards their aptitude
+  for becoming fossils. They almost all possess a hard, durable shell,
+  capable of resisting considerable abrasion and readily passing into a
+  mineralized condition. They are extremely abundant both as to
+  individuals and genera. They occur on the shore within tide mark, and
+  range thence down into the abysses. Moreover, they appear to have
+  possessed these qualifications from early geological times. In the
+  marine Mollusca, therefore, we have a common ground of comparison
+  between the stratified formations of different periods. They have been
+  styled the alphabet of palaeontological inquiry.
+
+There are two main purposes to which fossils may be put in geological
+research: (1) to throw light upon former conditions of physical
+geography, such as the presence of land, rivers, lakes and seas, in
+places where they do not now exist, changes of climate, and the former
+distribution of plants and animals; and (2) to furnish a guide in
+geological chronology whereby rocks may be classified according to
+relative date, and the facts of geological history may be arranged and
+interpreted as a connected record of the earth's progress.
+
+  1. As examples of the first of these two directions of inquiry
+  reference may be made to (a) former land-surfaces revealed by the
+  occurrence of layers of soil with tree-stumps and roots still in the
+  position of growth (see PURBECKIAN); (b) ancient lakes proved by beds
+  of marl or limestone full of lacustrine shells; (c) old sea-bottoms
+  marked by the occurrence of marine organisms; (d) variations in the
+  quality of the water, such as freshness or saltness, indicated by
+  changes in the size and shape of the fossils; (e) proximity to former
+  land, suggested by the occurrence of abundant drift-wood in the
+  strata; (f) former conditions of climate, different from the present,
+  as evidenced by such organisms as tropical types of plants and animals
+  intercalated among the strata of temperate or northern countries.
+
+  2. In applying fossils to the determination of geological chronology
+  it is first necessary to ascertain the order of superposition of the
+  rocks. Obviously, in a continuous series of undisturbed sedimentary
+  deposits the lowest must necessarily be the oldest, and the plants or
+  animals which they contain must have lived and died before any of the
+  organisms that occur in the overlying strata. This order of
+  superposition having been settled in a series of formations, it is
+  found that the fossils at the bottom are not quite the same as those
+  at the top of the series. Tracing the beds upward, we discover that
+  species after species of the lowest platforms disappears, until
+  perhaps not one of them is found. With the cessation of these older
+  species others make their entrance. These, in turn, are found to die
+  out, and to be replaced by newer forms. After patient examination of
+  the rocks, it has been ascertained that every well-marked "formation,"
+  or group of strata, is characterized by its own species or genera, or
+  by a general assemblage, or _facies_, of organic forms. Such a
+  generalization can only, of course, be determined by actual practical
+  experience over an area of some size. When the typical fossils of a
+  formation are known, they serve to identify that formation in its
+  progress across a country. Thus, in tracts where the true order of
+  superposition cannot be determined, owing to the want of sections or
+  to the disturbed condition of the rocks, fossils serve as a means of
+  identification and furnish a guide to the succession of the rocks.
+  They even demonstrate that in some mountainous ground the beds have
+  been turned completely upside down, where it can be shown that the
+  fossils in what are now the uppermost strata ought properly to lie
+  underneath those in the beds below them.
+
+  It is by their characteristic fossils that the stratified rocks of the
+  earth's crust can be most satisfactorily subdivided into convenient
+  groups of strata and classed in chronological order. Each "formation"
+  is distinguished by its own peculiar assemblage of organic remains, by
+  means of which it can be followed and recognized, even amid the
+  crumplings and dislocations of a disturbed region. The same general
+  succession of organic types can be observed over a large part of the
+  world, though, of course, with important modifications in different
+  countries. This similarity of succession has been termed _homotaxis_,
+  a term which expresses the fact that the order in which the leading
+  types of organized existence have appeared upon the earth has been
+  similar even in widely separated regions. It is evident that, in this
+  way, a reliable method of comparison is furnished, whereby the
+  stratified formations of different parts of the earth's crust can be
+  brought into relation with each other. Had the geologist continued to
+  remain, as in the days of Werner, hampered by the limitations imposed
+  by a reliance on mere lithological characters, he would have made
+  little or no progress in deciphering the record of the successive
+  phases of the history of the globe chronicled in the crust. Just as,
+  at the present time, sheets of gravel in one place are contemporaneous
+  with sheets of mud at another, so in the past all kinds of
+  sedimentation have been in progress simultaneously, and those of one
+  period may not be distinguishable in themselves from those of another.
+  Little or no reliance can be placed upon lithological resemblances or
+  differences in comparing the sedimentary formations of different
+  countries.
+
+  In making use of fossil evidence for the purpose of subdividing the
+  stratified rocks of the earth's crust, it is found to be applicable to
+  the smaller details of stratigraphy as well as to the definition of
+  large groups of strata. Thus a particular stratum may be marked by the
+  occurrence in it of various fossils, one or more of which may be
+  distinctive, either from occurring in no other bed above and below or
+  from special abundance in that stratum. One or more of these species
+  is therefore used as a guide to the occurrence of the bed in
+  question, which is called by the name of the most abundant species. In
+  this way what is called a "geological horizon," or "zone," is marked
+  off, and its exact position in the series of formations is fixed.
+
+  Perhaps the most distinctive feature in the progress of
+  palaeontological geology during the last half century has been the
+  recognition and wide application of this method of zonal stratigraphy,
+  which, in itself, was only a further development of William Smith's
+  famous idea, "Strata identified by Organized Fossils." It was first
+  carried out in detail by various palaeontologists in reference to the
+  Jurassic formations, notably by F.A. von Quenstedt and C.A. Oppel in
+  Germany and A.D. d'Orbigny in France. The publication of Oppel's
+  classic work _Die Juraformation Englands, Frankreichs und des
+  sudwestlichen Deutschlands_ (1856-1858) marked an epoch in the
+  development of stratigraphical geology. Combining what had been done
+  by various observers with his own laborious researches in France,
+  England, Wurttemberg and Bavaria, he drew up a classification of the
+  Jurassic system, grouping its several formations into zones, each
+  characterized by some distinctly predominant fossil after which it was
+  named (see LIAS). The same method of classification was afterwards
+  extended to the Cretaceous series by A.D. d'Orbigny, E. Hebert and
+  others, until the whole Mesozoic rocks from the Trias to the top of
+  the Chalk has now been partitioned into zones, each named after some
+  characteristic species or genus of fossils. More recently the
+  principle has been extended to the Palaeozoic formations, though as
+  yet less fully than to the younger parts of the geological record. It
+  has been successfully applied by Professor C. Lapworth to the
+  investigation of the Silurian series (see SILURIAN; ORDOVICIAN
+  SYSTEM). He found that the species of graptolites have each a
+  comparatively narrow vertical range, and they may consequently be used
+  for stratigraphical purposes. Applying the method, in the first
+  instance, to the highly plicated Silurian rocks of the south of
+  Scotland, he found that by means of graptolites he was able to work
+  out the structure of the ground. Each great group of strata was seen
+  to possess its own graptolitic zones, and by their means could be
+  identified not only in the original complex Scottish area, but in
+  England and Wales and in Ireland. It was eventually ascertained that
+  the succession of zones in Great Britain could be recognized on the
+  Continent, in North America and even in Australia. The brachiopods and
+  trilobites have likewise been made use of for zonal purposes among the
+  oldest sedimentary formations. The most ancient of the Palaeozoic
+  systems has as its fitting base the _Olenellus_ zone.
+
+  Within undefined and no doubt variable geographical limits
+  palaeontological zones have been found to be remarkably persistent.
+  They follow each other in the same general order, but not always with
+  equal definiteness. The type fossil may appear in some districts on a
+  higher or a lower platform than it does in others. Only to a limited
+  degree is there any coincidence between lithological variations in the
+  strata and the sequence of the zones. In the Jurassic formations,
+  indeed, where frequent alternations of different sedimentary materials
+  are to be met with, it is in some cases possible to trace a definite
+  upward or downward limit for a zone by some abrupt change in the
+  sedimentation, such as from limestone to shale. But such a precise
+  demarcation is impossible where no distinct bands of different
+  sediments are to be seen. The zones can then only be vaguely
+  determined by finding their characteristic fossils, and noting where
+  these begin to appear in the strata and where they cease. It would
+  seem, therefore, that the sequence of palaeontological zones, or
+  life-horizons, has not depended merely upon changes in the nature of
+  the conditions under which the organisms lived. We should naturally
+  expect that these changes would have had a marked influence; that, for
+  instance, a difference should be perceptible between the character of
+  the fossils in a limestone and that of those in a shale or a
+  sandstone. The environment, when a limestone was in course of
+  deposition, would generally be one of clear water, favourable for a
+  more vigorous and more varied fauna than where a shale series was
+  accumulating, when the water would be discoloured, and only such
+  animals would continue to live in it, or on the bottom, as could
+  maintain themselves in the midst of mud. But no such lithological
+  reason, betokening geographical changes that would affect living
+  creatures, can be adduced as a universally applicable explanation of
+  the occurrence and limitation of palaeontological zones. One of these
+  zones may be only a few inches, or feet or yards in vertical extent,
+  and no obvious lithological or other cause can be seen why its
+  specially characteristic fossils should not be found just as
+  frequently in the similar strata above and below. There is often
+  little or no evidence of any serious change in the conditions of
+  sedimentation, still less of any widespread physical disturbance, such
+  as the catastrophes by which the older geologists explained the
+  extinction of successive types of life.
+
+  It has been suggested that, where the life-zones are well defined,
+  sedimentation has been extremely slow, and that though these zones
+  follow each other with no break in the sedimentation, they were really
+  separated by prolonged intervals of time during which organic
+  evolution could come effectively into play. But it is not easy to
+  explain how, for example in the Lower Lias, there could have been a
+  succession of prodigious intervals, when practically no sediment was
+  laid down, and yet that the strata should show no sign of
+  contemporaneous disturbance or denudation, but succeed each other as
+  if they had been accumulated by one continuous process of deposit. It
+  must be admitted that the problem of life-zones in stratigraphical
+  geology has not yet been solved.
+
+  As Darwin first cogently showed, the history of life has been very
+  imperfectly registered in the stratified parts of the earth's crust.
+  Apart from the fact that, even under the most favourable conditions,
+  only a small proportion of the total flora and fauna of any period
+  would be preserved in the fossil state, enormous gaps occur where no
+  record has survived at all. It is as if whole chapters and books were
+  missing from a historical work. Some of these lacunae are sufficiently
+  obvious. Thus, in some cases, powerful dislocations have thrown
+  considerable portions of the rocks out of sight. Sometimes extensive
+  metamorphism has so affected them that their original characters,
+  including their organic contents, have been destroyed. Oftenest of
+  all, denudation has come into play, and vast masses of fossiliferous
+  rock have been entirely worn away, as is demonstrated by the abundant
+  unconformabilities in the structure of the earth's crust.
+
+  While the mere fact that one series of rocks lies unconformably on
+  another proves the lapse of a considerable interval between their
+  respective dates, the relative length of this interval may sometimes
+  be proved by means of fossil evidence, and by this alone. Let us
+  suppose, for example, that a certain group of formations has been
+  disturbed, upraised, denuded and covered unconformably by a second
+  group. In lithological characters the two may closely resemble each
+  other, and there may be nothing to show that the gap represented by
+  their unconformability is of an important character. In many cases,
+  indeed, it would be quite impossible to pronounce any well-grounded
+  judgment as to the amount of interval, even measured by the vague
+  relative standards of geological chronology. But if each group
+  contains a well-preserved suite of organic remains, it may not only be
+  possible, but easy, to say exactly how much of the geological record
+  has been left out between the two sets of formations. By comparing the
+  fossils with those obtained from regions where the geological record
+  is more complete, it may be ascertained, perhaps, that the lower rocks
+  belong to a certain platform or stage in geological history which for
+  our present purpose we may call D, and that the upper rocks can in
+  like manner be paralleled with stage H. It would be then apparent that
+  at this locality the chronicles of three great geological periods E,
+  F, and G were wanting, which are elsewhere found to be intercalated
+  between D and H. The lapse of time represented by this
+  unconformability would thus be equivalent to that required for the
+  accumulation of the three missing formations in those regions where
+  sedimentation was more continuous.
+
+  Fossil evidence may be made to prove the existence of gaps which are
+  not otherwise apparent. As has been already remarked, changes in
+  organic forms must, on the whole, have been extremely slow in the
+  geological past. The whole species of a sea-floor could not pass
+  entirely away, and be replaced by other forms, without the lapse of
+  long periods of time. If then among the conformable stratified
+  formations of former ages we encounter sudden and abrupt changes in
+  the _facies_ of the fossils, we may be certain that these must mark
+  omissions in the record, which we may hope to fill in from a more
+  perfect series elsewhere. The complete biological contrasts between
+  the fossil contents of unconformable strata are sufficiently
+  explicable. It is not so easy to give a satisfactory account of those
+  which occur where the beds are strictly conformable, and where no
+  evidence can be observed of any considerable change of physical
+  conditions at the time of deposit. A group of strata having the same
+  general lithological characters throughout may be marked by a great
+  discrepance between the fossils above and below a certain line. A few
+  species may pass from the one into the other, or perhaps every species
+  may be different. In cases of this kind, when proved to be not merely
+  local but persistent over wide areas, we must admit, notwithstanding
+  the apparently undisturbed and continuous character of the original
+  deposition of the strata, that the abrupt transition from the one
+  _facies_ of fossils to the other represents a long interval of time
+  which has not been recorded by the deposit of strata. A.C. Ramsay, who
+  called attention to these gaps, termed them "breaks in the succession
+  of organic remains." He showed that they occur abundantly among the
+  Palaeozoic and Secondary rocks of England. It is obvious, of course,
+  that such breaks, even though traceable over wide regions, were not
+  general over the whole globe. There have never been any universal
+  interruptions in the continuity of the chain of being, so far as
+  geological evidence can show. But the physical changes which caused
+  the breaks may have been general over a zoological district or minor
+  region. They no doubt often caused the complete extinction of genera
+  and species which had a small geographical range.
+
+  From all these facts it is clear that the geological record, as it now
+  exists, is at the best but an imperfect chronicle of geological
+  history. In no country is it complete. The lacunae of one region must
+  be supplied from another. Yet in proportion to the geographical
+  distance between the localities where the gaps occur and those whence
+  the missing intervals are supplied, the element of uncertainty in our
+  reading of the record is increased. The most desirable method of
+  research is to exhaust the evidence for each area or province, and to
+  compare the general order of its succession as a whole with that which
+  can be established for other provinces.
+
+
+PART VII.--STRATIGRAPHICAL GEOLOGY
+
+This branch of the science arranges the rocks of the earth's crust in
+the order of their appearance, and interprets the sequence of events of
+which they form the records. Its province is to cull from the other
+departments of geology the facts which may be needed to show what has
+been the progress of our planet, and of each continent and country, from
+the earliest times of which the rocks have preserved any memorial. Thus
+from mineralogy and petrography it contains information regarding the
+origin and subsequent mutations of minerals and rocks. From dynamical
+geology it learns by what agencies the materials of the earth's crust
+have been formed, altered, broken, upheaved and melted. From geotectonic
+geology it understands the various processes whereby these materials
+were put together so as to build up the complicated crust of the earth.
+From palaeontological geology it receives in well-determined fossil
+remains a clue by which to discriminate the different stratified
+formations, and to trace the grand onward march of organized existence
+upon this planet. Stratigraphical geology thus gathers up the sum of all
+that is made known by the other departments of the science, and makes it
+subservient to the interpretation of the geological history of the
+earth.
+
+The leading principles of stratigraphy may be summed up as follows:
+
+1. In every stratigraphical research the fundamental requisite is to
+establish the order of superposition of the strata. Until this is
+accomplished it is impossible to arrange the dates, and make out the
+sequence of geological history.
+
+2. The stratified portion of the earth's crust, or what has been called
+the "geological record," can be subdivided into natural groups, or
+series of strata, characterized by distinctive organic remains and
+recognizable by these remains, in spite of great changes in lithological
+character from place to place. A bed, or a number of beds, linked
+together by containing one or more distinctive species or genera of
+fossils is termed a _zone_ or _horizon_, and usually bears the name of
+one of its more characteristic fossils, as the _Planorbis_-zone of the
+Lower Lias, which is so called from the prevalence in it of the ammonite
+_Psiloceras planorbis_. Two or more such zones related to each other by
+the possession of a number of the same characteristic species or genera
+have been designated _beds_ or an _assise_. Two or more sets of beds or
+assises similarly related form a _group_ or _stage_; a number of groups
+or stages make a _series_, _formation_ or _section_, and a succession of
+formations may be united into a _system_.
+
+3. Some living species of plants and animals can be traced downwards
+through the more recent geological formations; but the number which can
+be so followed grows smaller as the examination is pursued into more
+ancient deposits. With their disappearance other species or genera
+present themselves which are no longer living. These in turn may be
+traced backward into earlier formations, till they too cease and their
+places are taken by yet older forms. It is thus shown that the
+stratified rocks contain the records of a gradual progression of organic
+forms. A species which has once died out does not seem ever to have
+reappeared.
+
+4. When the order of succession of organic remains among the stratified
+rocks has been determined, they become an invaluable guide in the
+investigation of the relative age of rocks and the structure of the
+land. Each zone and formation, being characterized by its own species or
+genera, may be recognized by their means, and the true succession of
+strata may thus be confidently established even in a country wherein the
+rocks have been shattered by dislocation, folded, inverted or
+metamorphosed.
+
+5. Though local differences exist in regard to the precise zone in which
+a given species of organism may make its first appearance, the general
+order of succession of the organic forms found in the rocks is never
+inverted. The record is nowhere complete in any region, but the portions
+represented, even though extremely imperfect, always follow each other
+in their proper chronological order, unless where disturbance of the
+crust has intervened to destroy the original sequence.
+
+6. The relative chronological value of the divisions of the geological
+record is not to be measured by mere depth of strata. While it may be
+reasonably assumed that, in general, a great thickness of stratified
+rock must mark the passage of a long period of time, it cannot safely be
+affirmed that a much less thickness elsewhere must represent a
+correspondingly diminished period. The need for this caution may
+sometimes be made evident by an unconformability between two sets of
+rocks, as has already been explained. The total depth of both groups
+together may be, say 1000 ft. Elsewhere we may find a single unbroken
+formation reaching a depth of 10,000 ft.; but it would be unwarrantable
+to assume that the latter represents ten times the length of time
+indicated by the former two. So far from this being the case, it might
+not be difficult to show that the minor thickness of rock really denotes
+by far the longer geological interval. If, for instance, it could be
+proved that the upper part of both the sections lies on one and the same
+geological platform, but that the lower unconformable series in the one
+locality belongs to a far lower and older system of rocks than the base
+of the thick conformable series in the other, then it would be clear
+that the gap marked by the unconformability really indicates a longer
+period than the massive succession of deposits.
+
+7. Fossil evidence furnishes the chief means of comparing the relative
+value of formations and groups of rock. A "break in the succession of
+organic remains," as already explained, marks an interval of time often
+unrepresented by strata at the place where the break is found. The
+relative importance of these breaks, and therefore, probably, the
+comparative intervals of time which they mark, may be estimated by the
+difference of the _facies_ or general character of the fossils on each
+side. If, for example, in one case we find every species to be
+dissimilar above and below a certain horizon, while in another locality
+only half of the species on each side are peculiar, we naturally infer,
+if the total number of species seems large enough to warrant the
+inference, that the interval marked by the former break was much longer
+than that marked by the second. But we may go further and compare by
+means of fossil evidence the relation between breaks in the succession
+of organic remains and the depth of strata between them.
+
+  Three formations of fossiliferous strata, A, C, and H, may occur
+  conformably above each other. By a comparison of the fossil contents
+  of all parts of A, it may be ascertained that, while some species are
+  peculiar to its lower, others to its higher portions, yet the majority
+  extend throughout the formation. If now it is found that of the total
+  number of species in the upper portion of A only one-third passes up
+  into C, it may be inferred with some plausibility that the time
+  represented by the break between A and C was really longer than that
+  required for the accumulation of the whole of the formation A. It
+  might even be possible to discover elsewhere a thick intermediate
+  formation B filling up the gap between A and C. In like manner were it
+  to be discovered that, while the whole of the formation C is
+  characterized by a common suite of fossils, not one of the species and
+  only one half of the genera pass up into H, the inference could hardly
+  be resisted that the gap between the two formations marks the passage
+  of a far longer interval than was needed for the deposition of the
+  whole of C. And thus we reach the remarkable conclusion that, thick
+  though the stratified formations of a country may be, in some cases
+  they may not represent so long a total period of time as do the gaps
+  in their succession,--in other words, that non-deposition was more
+  frequent and prolonged than deposition, or that the intervals of time
+  which have been recorded by strata have not been so long as those
+  which have not been so recorded.
+
+In all speculations of this nature, however, it is necessary to reason
+from as wide a basis of observation as possible, seeing that so much of
+the evidence is negative. Especially needful is it to bear in mind that
+the cessation of one or more species at a certain line among the rocks
+of a particular district may mean nothing more than that, onward from
+the time marked by that line, these species, owing to some change in the
+conditions of life, were compelled to migrate or became locally extinct
+or, from some alteration in the conditions of fossilization, were no
+longer imbedded and preserved as fossils. They may have continued to
+flourish abundantly in neighbouring districts for a long period
+afterward. Many examples of this obvious truth might be cited. Thus in a
+great succession of mingled marine, brackish-water and terrestrial
+strata, like that of the Carboniferous Limestone series of Scotland,
+corals, crinoids and brachiopods abound in the limestones and
+accompanying shales, but disappear as the sandstones, ironstones, clays,
+coals and bituminous shales supervene. An observer meeting for the first
+time with an instance of this disappearance, and remembering what he had
+read about breaks in succession, might be tempted to speculate about the
+extinction of these organisms, and their replacement by other and later
+forms of life, such as the ferns, lycopods, estuarine or fresh-water
+shells, ganoid fishes and other fossils so abundant in the overlying
+strata. But further research would show him that high above the
+plant-bearing sandstones and coals other limestones and shales might be
+observed, once more charged with the same marine fossils as before, and
+still farther overlying groups of sandstones, coals and carbonaceous
+beds followed by yet higher marine limestones. He would thus learn that
+the same organisms, after being locally exterminated, returned again and
+again to the same area. After such a lesson he would probably pause
+before too confidently asserting that the highest bed in which we can
+detect certain fossils marks their final appearance in the history of
+life. Some breaks in the succession may thus be extremely local, one set
+of organisms having been driven to a different part of the same region,
+while another set occupied their place until the first was enabled to
+return.
+
+8. The geological record is at the best but an imperfect chronicle of
+the geological history of the earth. It abounds in gaps, some of which
+have been caused by the destruction of strata owing to metamorphism,
+denudation or otherwise, others by original non-deposition, as above
+explained. Nevertheless from this record alone can the progress of the
+earth be traced. It contains the registers of the appearance and
+disappearance of tribes of plants and animals which have from time to
+time flourished on the earth. Only a small proportion of the total
+number of species which have lived in past time have been thus
+chronicled, yet by collecting the broken fragments of the record an
+outline at least of the history of life upon the earth can be
+deciphered.
+
+It cannot be too frequently stated, nor too prominently kept in view,
+that, although gaps occur in the succession of organic remains as
+recorded in the rocks, they do not warrant the conclusion that any such
+blank intervals ever interrupted the progress of plant and animal life
+upon the globe. There is every reason to believe that the march of life
+has been unbroken, onward and upward. Geological history, therefore, if
+its records in the stratified formations were perfect, ought to show a
+blending and gradation of epoch with epoch. But the progress has been
+constantly interrupted, now by upheaval, now by volcanic outbursts, now
+by depression. These interruptions serve as natural divisions in the
+chronicle, and enable the geologist to arrange his history into periods.
+As the order of succession among stratified rocks was first made out in
+Europe, and as many of the gaps in that succession were found to be
+widespread over the European area, the divisions which experience
+established for that portion of the globe came to be regarded as
+typical, and the names adopted for them were applied to the rocks of
+other and far distant regions. This application has brought out the fact
+that some of the most marked breaks in the European series do not exist
+elsewhere, and, on the other hand, that some portions of that series are
+much more complete than the corresponding sections in other regions.
+Hence, while the general similarity of succession may remain, different
+subdivisions and nomenclature are required as we pass from continent to
+continent.
+
+The nomenclature adopted for the subdivisions of the geological record
+bears witness to the rapid growth of geology. It is a patch-work in
+which no system nor language has been adhered to, but where the
+influences by which the progress of the science has been moulded may be
+distinctly traced. Some of the earliest names are lithological, and
+remind us of the fact that mineralogy and petrography preceded geology
+in the order of birth--Chalk, Oolite, Greensand, Millstone Grit. Others
+are topographical, and often recall the labours of the early geologists
+of England--London Clay, Oxford Clay, Purbeck, Portland, Kimmeridge
+beds. Others are taken from local English provincial names, and remind
+us of the debt we owe to William Smith, by whom so many of them were
+first used--Lias, Gault, Crag, Cornbrash. Others of later date recognize
+an order of superposition as already established among formations--Old
+Red Sandstone, New Red Sandstone. By common consent it is admitted that
+names taken from the region where a formation or group of rocks is
+typically developed are best adapted for general use. Cambrian,
+Silurian, Devonian, Permian, Jurassic are of this class, and have been
+adopted all over the globe.
+
+But whatever be the name chosen to designate a particular group of
+strata, it soon comes to be used as a chronological or homotaxial term,
+apart altogether from the stratigraphical character of the strata to
+which it is applied. Thus we speak of the Chalk or Cretaceous system,
+and embrace under that term formations which may contain no chalk; and
+we may describe as Silurian a series of strata utterly unlike in
+lithological characters to the formations in the typical Silurian
+country. In using these terms we unconsciously allow the idea of
+relative date to arise prominently before us. Hence such a word as
+"chalk" or "cretaceous" does not suggest so much to us the group of
+strata so called as the interval of geological history which these
+strata represent. We speak of the Cretaceous, Jurassic, and Cambrian
+periods, and of the Cretaceous fauna, the Jurassic flora, the Cambrian
+trilobites, as if these adjectives denoted simply epochs of geological
+time.
+
+The stratified formations of the earth's crust, or geological record,
+are classified into five main divisions, which in their order of
+antiquity are as follows: (1) Archean or Pre-Cambrian, called also
+sometimes Azoic (lifeless) or Eozoic (dawn of life); (2) Palaeozoic
+(ancient life) or Primary; (3) Mesozoic (middle life) or Secondary; (4)
+Cainozoic (recent life) or Tertiary; (5) Quaternary or Post-Tertiary.
+These divisions are further ranged into systems, formations, groups or
+stages, assises and zones. Accounts of the various subdivisions named
+are given in separate articles under their own headings. In order,
+however, that the sequence of the formations and their parallelism in
+Europe and North America may be presented together a stratigraphical
+table is given on next page.
+
+
+PART VIII.--PHYSIOGRAPHICAL GEOLOGY
+
+This department of geological inquiry investigates the origin and
+history of the present topographical features of the land. As these
+features must obviously be related to those of earlier time which are
+recorded in the rocks of the earth's crust, they cannot be
+satisfactorily studied until at least the main outlines of the history
+of these rocks have been traced. Hence physiographical research comes
+appropriately after the other branches of the science have been
+considered.
+
+From the stratigraphy of the terrestrial crust we learn that by far the
+largest part of the area of dry land is built up of marine formations;
+and therefore that the present land is not an aboriginal portion of the
+earth's surface, but has been overspread by the sea in which its rocks
+were mainly accumulated. We further discover that this submergence of
+the land did not happen once only, but again and again in past ages and
+in all parts of the world. Yet although the terrestrial areas varied
+much from age to age in their extent and in their distribution, being at
+one time more continental, at another more insular, there is reason to
+believe that these successive diminutions and expansions have on the
+whole been effected within, or not far outside, the limits of the
+existing continents. There is no evidence that any portion of the
+present land ever lay under the deeper parts of the ocean. The abysmal
+deposits of the ocean-floor have no true representatives among the
+sedimentary formations anywhere visible on the land. Nor, on the other
+hand, can it be shown that any part of the existing ocean abysses ever
+rose above sea-level into dry land. Hence geologists have drawn the
+inference that the ocean basins have probably been always where they now
+are; and that although the continental areas have often been narrowed by
+submergence and by denudation, there has probably seldom or never been a
+complete disappearance of land. The fact that the sedimentary formations
+of each successive geological period consist to so large an extent of
+mechanically formed terrigenous detritus, affords good evidence of the
+coexistence of tracts of land as well as of extensive denudation.
+
+
+  _The Geological Record or Order of Succession of the Stratified
+  Formations of the Earth's Crust._
+
+  +---+---+-------------------------------------------+----------------------------------+
+  |   |   |                  Europe.                  |          North America.          |
+  +---+---+-------------------------------------------+----------------------------------+
+  | Q |    \      Historic, up to the present time.   | Similar to the European          |
+  | u |     \     Prehistoric, comprising deposits of |   development, but with scantier |
+  | a |      \     the Iron, Bronze, and later        |   traces of the presence of man. |
+  | t |       \     Stone Ages.                       |                                  |
+  | e |        \    Neolithic--alluvium, peat, lake-  |                                  |
+  | r | Recent, \   dwellings, loess, &c.             |                                  |
+  | n | Post-   | Palaeolithic--river-gravels, cave-  |                                  |
+  | a | glacial |   deposits, &c.                     |                                  |
+  | r | or      |                                     |                                  |
+  | y | Human.  |                                     |                                  |
+  |   |         |                                     |                                  |
+  | o |         |                                     |                                  |
+  | r +---------+-------------------------------------+----------------------------------+
+  |   | Pleist- | Older Loess and valley-gravels;     | As in Europe, it is hardly       |
+  | P | ocene   |   cave-deposits.                    |   possible to assign a definite  |
+  | o | or      | Strand-lines or raised beaches;     |   chronological place to each of |
+  | s | Glacial.|   youngest moraines.                |   the various deposits of this   |
+  | t |         | Upper Boulder-clays; eskers; marine |   period, terrestrial and marine.|
+  | | |         |   sands and clays.                  |   They generally resemble the    |
+  | T |         | Interglacial deposits.              |   European series. The           |
+  | e |         | Lower boulder-clay or Till, with    |   characteristic marine,         |
+  | r |         |   striated rock-surfaces below.     |   fluviatile and lacustrine      |
+  | t |         |                                     |   terraces, which overlie the    |
+  | i |        /                                      |   older drifts, have been        |
+  | a |       /                                       |   classed as the Champlain Group.|
+  | r |      /                                        |                                  |
+  | y |     /                                         |                                  |
+  | . |    /                                          |                                  |
+  +---+---+-------------------------------------------+----------------------------------+
+  |   | P | Newer:--English Forest-Bed Group; Red and | On the Atlantic border           |
+  |   | l |   Norwich Crag; Amstelian and Scaldesian  |   represented by the marine      |
+  |   | i |   groups of Belgium and Holland; Sicilian |   Floridian series; in the       |
+  |   | o |   and Astian of France and Italy.         |   interior by a subaerial and    |
+  |   | c | Older:--English Coralline Crag; Diestian  |   lacustrine series; and on the  |
+  |   | e |   of Belgium; Plaisancian of southern     |   Pacific border by the thick    |
+  |   | n |   France and Italy.                       |   marine series of San Francisco.|
+  |   | e |                                           |                                  |
+  |   | . |                                           |                                  |
+  |   +---+-------------------------------------------+----------------------------------+
+  |   | M | Wanting in Britain; well developed in     | Represented in the Eastern States|
+  |   | i |   France, S. E. Europe and Italy;         |   by a marine series (Yorktown or|
+  | C | o |   divisible into the following groups in  |   Chesapeake, Chipola and        |
+  | a | c |   descending order: (1) Pontian; (2)      |   Chattahoochee groups), and in  |
+  | i | e |   Sarmatian; (3) Tortonian; (4) Helvetian;|   the interior by the lacustrine |
+  | n | n |   (5) Langhian (Burdigalian).             |   Loup Fork (Nebraska), Deep     |
+  | o | e |                                           |   River, and John Day groups.    |
+  | z | . |                                           |                                  |
+  | o +---+-------------------------------------------+----------------------------------+
+  | i |   | In Britain the "fluvio-marine series" of  | On the Atlantic border no        |
+  | c | O |   the Isle of Wight; also the volcanic    |   equivalents have been          |
+  |   | l |   plateaux of Antrim and Inner Hebrides   |   satisfactorily recognised, but |
+  | o | i |   and those of the Faeroe Isles and       |   on the Pacific side there are  |
+  | r | g |   Iceland. In continental Europe the      |   marine deposits in N. W.       |
+  |   | o |   following subdivisions have been        |   Oregon, which may represent    |
+  | T | c |   established in descending order: (1)    |   this division. In the interior |
+  | e | e |   Aquitanian, (2) Stampian (Rupelian),    |   the equivalent is believed to  |
+  | r | n |   (3) Tongrain (Sannoisian).              |   be the fresh-water White River |
+  | t | e |                                           |   series, including (1)          |
+  | i | . |                                           |   _Protoceras_ beds, (2)         |
+  | a |   |                                           |   _Oreodon_ beds, and (3)        |
+  | r |   |                                           |   _Titanothervum_ beds.          |
+  | y +---+-------------------------------------------+----------------------------------+
+  | . |   | Barton sands and clays; Ludian series of  | Woodstock and Aquia Creek groups |
+  |   |   |   France.                                 |   of Potomac River; Vicksburg,   |
+  |   |   | Bracklesham Beds; Lutetian (Calcaire      |   Jackson, Claiborne, Buhrstone, |
+  |   | E |   grossier and Caillasses) of Paris       |   and Lignitic groups of         |
+  |   | o |   basin.                                  |   Mississippi.                   |
+  |   | c | London clay, Woolwich and Reading Beds;   | In the interior a thick series of|
+  |   | e |   Thanet sands; Ypresian or Londinian of  |   fresh-water formations,        |
+  |   | n |   N. France and Belgium; Sparnacian and   |   comprising, in descending      |
+  |   | e |   Thanetian groups.                       |   order, the Uinta, Bridger,     |
+  |   | . |                                           |   Wind River, Wasatch, Torrejon, |
+  |   |   |                                           |   and Puerco groups.             |
+  |   |   |                                           | On the Pacific side the marine   |
+  |   |   |                                           |   Tejon series of Oregon and     |
+  |   |   |                                           |   California.                    |
+  |---+---+-------------------------------------------+----------------------------------|
+  |   |   |     Upper                                 | On the Atlantic border both      |
+  |   |   |     =====                                 |   marine strata and others       |
+  |   |   | Danian--wanting in Britain; uppermost     |   containing a terrestrial flora |
+  |   |   |   limestone of Denmark.                   |   represent the Cretaceous series|
+  |   |   | Senonian--Upper Chalk with Flints of      |   of formations.                 |
+  |   |   |   England; Aturian and Emscherian stages  | In the interior there is also a  |
+  |   |   |   on the European continent.              |   commingling of marine with     |
+  |   |   | Turonian--Middle Chalk with few flints,   |   lacustrine deposits. At the top|
+  |   |   |   and comprising the Angoumian and stages.|   lies the Laramie or Lignitic   |
+  |   | C | Cenomanian--Lower Chalk and Chalk Marl.   |   series with an abundant        |
+  |   | r |                                           |   terrestrial flora, passing down|
+  |   | e |     Lower                                 |   into the lacustrine and        |
+  |   | t |     =====                                 |   brackish-water Montana series. |
+  |   | a | Albian--Upper Greensand and Gault.        |   Of older date, the Colorado    |
+  |   | c | Aptian--Lower Greensand; Marls and        |   series contains an abundant    |
+  |   | e |   limestones of Provence, &c.             |   marine fauna, yet includes also|
+  |   | o | Urgonian (Barremian)--Atherfield clay;    |   some Niobrara marls and        |
+  |   | u |   massive Hippurite limestones of         |   limestones are likewise of     |
+  |   | s |   southern France.                        |   marine origin, but the lower   |
+  |   | . | Neocomian--Weald clay and Hastings sand;  |   members of the series (Benton  |
+  |   |   |   Hauterivian and Valanginian sub-stages  |   and Dakota) show another great |
+  |   |   |   of Switzerland and France.              |   representation of fresh-water  |
+  | M |   |                                           |   sedimentation with lignites and|
+  | e |   |                                           |   coals.                         |
+  | s |   |                                           | In California a vast succession  |
+  | o |   |                                           |   of marine deposits (Shasta-    |
+  | z |   |                                           |   Chico) represents the          |
+  | o |   |                                           |   Cretaceous system; and in      |
+  | i |   |                                           |   western British N. America     |
+  | c |   |                                           |   coal-seams also occur.         |
+  |   +---+-------------------------------------------+----------------------------------+
+  | o |   | Purbeckian--Purbeck beds; Munder Mergel;  | Representatives of the Middle and|
+  | r |   |   largely present in Westphalia.          |   lower Jurassic formations have |
+  |   |   | Portlandian--Portland group of England,   |   been found in California and   |
+  | S |   |   represented in S. France by the thick   |   Oregon, and farther north among|
+  | e |   |   Tithonian limestones.                   |   the Arctic islands.            |
+  | c |   | Kimmeridgian--Kimmeridge Clay of England; | Strata containing Lower Jurassic |
+  | o |   |   Virgulian and Pterocerian groups of N.  |   marine fossils appear in       |
+  | n | J |   France; represented by thick limestones |   Wyoming and Dakota; and above  |
+  | d | u |   in the Mediterranean basin.             |   them come the _Atlantosaurus_  |
+  | a | r | Corallian--Coral Rag, Coralline Oolite;   |   and _Baptanodon_ beds, which   |
+  | r | a |   Sequanian stages of the Continent,      |   have yielded so large a        |
+  | y | s |   comprising the sub-stages of Astartian  |   variety of deinosaurs and other|
+  | . | s |   and Rauracian.                          |   vertebrates, and especially the|
+  |   | i | Oxfordian--Oxford Clay; Axgovian and      |   remains of a number of genera  |
+  |   | c |   Neuvizyan stages.                       |   of small mammals.              |
+  |   | . | Callovian--Kellaways Rock, Divesian       |                                  |
+  |   |   |   sub-stage of N. France.                 |                                  |
+  |   |   | Bathonian--series of English strata from  |                                  |
+  |   |   |   Cornbrash down to Fuller's Earth.       |                                  |
+  |   |   | Bajocian--Inferior Oolite of England.     |                                  |
+  |   |   | Lassic--divisible into (1) Upper Lias     |                                  |
+  |   |   |   or Toarcian, (2) Middle Lias, Marlstone |                                  |
+  |   |   |   or Charmouthian, (3) Lower Lias of      |                                  |
+  |   |   |   Sinemurian and Hettangian.              |                                  |
+  |   +---+-------------------------------------------+----------------------------------+
+  |   |   | In Germany and western Europe this        | In New York, Connecticut, New    |
+  |   | T |   division represents the deposits of     |   Brunswick, and Nova Scotia     |
+  |   | r |   inland seas or lagoons, and is divisible|   a series of red sandstone      |
+  |   | i |   into the following stages in descending |   (Newark series) contains land- |
+  |   | a |   order: (1) Rhaetic, (2) Keuper, (3)     |   plants and labyrinthodonts     |
+  |   | s |   Muschelkalk, (4) Bunter.  In the        |   like the lagoon type of central|
+  |   | s |   eastern Alps and the Mediterranean      |   and western Europe. On the     |
+  |   | i |   basin the contemporaneous sedimentary   |   Pacific slope, however, marine |
+  |   | c |   formations are those of open clear      |   equivalents occur, representing|
+  |   | . |   sea, in which a thickness of many       |   the pelagic type of south-     |
+  |   |   |   thousand feet of strata was accumulated.|   eastern Europe.                |
+  +---+---+-------------------------------------------+----------------------------------+
+  |   | P | Thuringian--Zechstein, Magnesian          | To this division of the geologi- |
+  |   | e |   Limestone; named from its development   |   cal record the Upper Barren    |
+  |   | r |   in Thuringia; well represented          |   Measures of the coal-fields of |
+  |   | m |   also in Saxony, Bavaria and Bohemia.    |   Pennsylvania, Prince Edward    |
+  |   | i | Saxonian--Rothliegendes Group; Red        |   Island, Nova Scotia and        |
+  |   | a |   Sandstones, &c.                         |   New Brunswick have been        |
+  |   | n | Autunian--where the strata present the    |   assigned.                      |
+  |   | . |   lagoon facies, well displayed at Autun  | Farther south in Kansas, Texas,  |
+  |   |   |   in France; where the marine type is     |   and Nebraska the representa-   |
+  |   |   |   predominant, as in Russia, the group    |   tives of the division have an  |
+  |   |   |   has been termed Artinskian.             |   abundant marine fauna.         |
+  |   +---+-------------------------------------------+----------------------------------+
+  |   | C | Stephanian or Uralian--represented in     | Upper productive Coal-measures.  |
+  |   | a |   Russia by marine formations, and in     | Lower Barren measures.           |
+  |   | r |   central and western Europe by numerous  | Lower productive Coal-measures.  |
+  |   | b |   small basins containing a peculiar      | Pottsville conglomerate.         |
+  |   | o |   flora and in some places a great variety| Mauch Chunk shales; limestones   |
+  |   | n |   of insects.                             |   of Chester, St Louis, &c.      |
+  |   | i | Westphalian or Moscovian--Coal-measures,  | Pocono series; Kinderhook        |
+  |   | f |   Millstone Grit.                         |   limestone.                     |
+  |   | e | Culm or Dinantian--Carboniferous Limestone|                                  |
+  |   | r |   and Calciferous Sandstone series.       |                                  |
+  |   | o |                                           |                                  |
+  |   | u |                                           |                                  |
+  |   | s |                                           |                                  |
+  |   | . |                                           |                                  |
+  |   +---+-------------------------------------------+----------------------------------+
+  |   |                            Devonian and Old Red Sandstone.                       |
+  | P +----------------------+------------------------+----------------------------------+
+  | a |     Devonian type.   |  Old Red Sandstone     |                                  |
+  | l |                      |       type.            |                                  |
+  | a +----------------------+------------------------+ / Catskill red sandstone; Old    |
+  | e |         / Famennian. | Yellow and red         | |   Red Sandstone type: the      |
+  | o | Upper  <             |   sandstone with       |<    strata below show the        |
+  | z |         \ Frasnian.  |   _Holoptychius_,      | |   Devonian type.               |
+  | o |                      |   _Bothriolepis_,&c.   | | Chemung Group.                 |
+  | i |                      |                        | \ Genesee   "                    |
+  | c |                      |                        |                                  |
+  |   |         / Givetian.  | Caithness Flagstones   |                                  |
+  | o | Middle <             |   with _Osteolepus_,   | / Hamilton Group.                |
+  | r |         \ Eifelian.  |   _Dipterus_,          | \ Marcellus  "                   |
+  |   |                      |   _Homosteus_, &c.     |                                  |
+  | P |                      |                        |                                  |
+  | r |                      | Red and purple         | / Corniferous Limestone. / Upper |
+  | i |        /Coblentizian.|   sandstones and       | |                        | Held- |
+  | m | Lower <              |   conglomerates with   |<  Onondaga Limestone.   <  erberg|
+  | a |        \Gedinnian.   |   _Cephalaspis_,       | |                        \ Group.|
+  | r |                      |   _Pteraspis_, &c.     | \ Oriskany Sandstone.            |
+  | y +---+------------------+------------------------+----------------------------------+
+  | . |   |                                           |  / Lower Helderberg Group.       |
+  |   | S |               / Ludlow  Group.            |  | Water-Lime.                   |
+  |   | i |   Upper      <  Wenlock   "               | <  Niagara Shale and Limestone.  |
+  |   | l |               \ Llandovery"               |  | Clinton Group.                |
+  |   | u |                                           |  \ Medina    "                   |
+  |   | r |                                           |                                  |
+  |   | i |                                           |  / Cincinnati Group.             |
+  |   | a |   Lower       / Caradoc or Bala Group.    |  | Utica        "                |
+  |   | n | (Ordovician) <  Llandeilo         "       | <  Trenton      "                |
+  |   | . |               \ Arenig            "       |  | Chazy        "                |
+  |   |   |                                           |  \ Calciferous  "                |
+  |   +---+-------------------------------------------+----------------------------------+
+  |   | C | Upper or _Olenus_ series--Tremadoc        | Upper or Potsdam series with     |
+  |   | a |   slates and _Lingula_ Flags.             |   _Olenus_ and _Dicelocephalus_  |
+  |   | m | Middle or _Pardoxides_ series--Menevian   |   fauna.                         |
+  |   | b |   Group.                                  | Middle or Acadian series with    |
+  |   | r | Lower or _Olenellus_ series--Llanberis    |   _Paradoxides_ fauna.           |
+  |   | i |   and Harlech Group, and _Olenellus_-     | Lower or Georgian series with    |
+  |   | a |   zone.                                   |   _Olenellus_ fauna.             |
+  |   | n |                                           |                                  |
+  |   | . |                                           |                                  |
+  +---+---+-------------------------------------------+----------------------------------+
+  |   |   |                       Archean, Pre-Cambrian, Eozoic.                         |
+  +---+---+-------------------------------------------+----------------------------------+
+  |   |   | In Scotland, underneath the Cambrian      | In Canada and the Lake Superior  |
+  |   |   |   Olenellus group, lies unconformably     |   region of the United States    |
+  |   |   |   a mass of red sandstone and con-        |   a vast succession of rocks of  |
+  |   |   |   glomerate (Torridonian) 8000 or 10,000  |   Pre-Cambrian age has been      |
+  |   |   |   ft. thick, which rests with a strong    |   grouped into the following     |
+  |   |   |   gneisses and schists (Lewisian).  A     |   subdivisions in descending     |
+  |   |   |   thick series of slates and phyllites    |   order: (1) Keweenwan, lying    |
+  |   |   |   lies below the oldest Palaeozoic rocks  |   unconformably on (2) Animikie, |
+  |   |   |   in central Europe, with coarse          |   separated by a strong          |
+  |   |   |   gneisses below.                         |   unconformability from (3) Upper|
+  |   |   |                                           |   Huronian, (4) Lower Huronian   |
+  |   |   |                                           |   with an unconformable base, (5)|
+  |   |   |                                           |   Goutchiching, (6) Laurentian.  |
+  |   |   |                                           |   In the eastern part of Canada, |
+  |   |   |                                           |   Newfoundland, &c., and also in |
+  |   |   |                                           |   Montana, sedimentary formations|
+  |   |   |                                           |   of great thickness below the   |
+  |   |   |                                           |   lowest Cambrian zone have been |
+  |   |   |                                           |   found to contain some obscure  |
+  |   |   |                                           |   organisms.                     |
+  +---+---+-------------------------------------------+----------------------------------+
+
+From these general considerations we proceed to inquire how the existing
+topographical features of the land arose. Obviously the co-operation of
+the two great geological agencies of hypogene and epigene energy, which
+have been at work from the beginning of our globe's decipherable
+history, must have been the cause to which these features are to be
+assigned; and the task of the geologist is to ascertain, if possible,
+the part that has been taken by each. There is a natural tendency to see
+in a stupendous piece of scenery, such as a deep ravine, a range of
+hills, a line of precipice or a chain of mountains, evidence only of
+subterranean convulsion; and before the subject was taken up as a matter
+of strict scientific induction, an appeal to former cataclysms was
+considered a sufficient solution of the problems presented by such
+features of landscape. The rise of the modern Huttonian school, however,
+led to a more careful examination of these problems. The important share
+taken by erosion in the determination of the present features of
+landscape was then recognized, while a fuller appreciation of the
+relative parts played by the hypogene and epigene causes has gradually
+been reached.
+
+1. The study of the progress of denudation at the present time has led
+to the conclusion that even if the rate of waste were not more rapid
+than it is to-day, it would yet suffice in a comparatively brief
+geological period to reduce the dry land to below the sea-level. But not
+only would the area of the land be diminished by denudation, it could
+hardly fail to be more or less involved in those widespread movements of
+subsidence, during which the thick sedimentary formations of the crust
+appear to have been accumulated. It is thus manifest that there must
+have been from time to time during the history of our globe upward
+movements of the crust, whereby the balance between land and sea was
+redressed. Proofs of such movements have been abundantly preserved among
+the stratified formations. We there learn that the uplifts have usually
+followed each other at long intervals between which subsidence
+prevailed, and thus that there has been a prolonged oscillation of the
+crust over the great continental areas of the earth's surface.
+
+An examination of that surface leads to the recognition of two great
+types of upheaval. In the one, the sea-floor, with all its thick
+accumulations of sediment, has been carried upwards, sometimes for
+several thousand feet, so equably that the strata retain their original
+flatness with hardly any sensible disturbance for hundreds of square
+miles. In the other type the solid crust has been plicated, corrugated
+and dislocated, especially along particular lines, and has attained its
+most stupendous disruption in lofty chains of mountains. Between these
+two phases of uplift many intermediate stages have been developed,
+according to the direction and intensity of the subterranean force and
+the varying nature and disposition of the rocks Of the crust.
+
+(a) Where the uplift has extended over wide spaces, without appreciable
+deformation of the crust, the flat strata have given rise to low plains,
+or if the amount of uprise has been great enough, to high plains,
+plateaux or tablelands. The plains of Russia, for example, lie for the
+most part on such tracts of equably uplifted strata. The great plains of
+the western interior of the United States form a great plateau or
+tableland, 5000 or 6000 ft. above the sea, and many thousands of square
+miles in extent, on which the Rocky Mountains have been ridged up.
+
+(b) It is in a great mountain-chain that the complicated structures
+developed during disturbances of the earth's crust can best be studied
+(see Parts IV. and V. of this article), and where the influence of these
+structures on the topography of the surface is most effectively
+displayed. Such a chain may be the result of one colossal disturbance;
+but those of high geological antiquity usually furnish proofs of
+successive uplifts with more or less intervening denudation. Formed
+along lines of continental displacement in the crust, they have again
+and again given relief from the strain of compression by fresh
+crumpling, fracture and uprise. The chief guide in tracing these
+successive stages of growth is supplied by unconformability. If, for
+example, a mountain-range consists of upraised Silurian rocks, upon the
+upturned and denuded edges of which the Carboniferous Limestone lies
+transgressively, it is clear that its original upheaval must have taken
+place in the period of geological time represented by the interval
+between the Silurian and the Carboniferous Limestone formations. If, as
+the range is followed along its course, the Carboniferous Limestone is
+found to be also highly inclined and covered unconformably by the Upper
+Coal-measures, a second uplift of that portion of the ground can be
+proved to have taken place between the time of the Limestone and that of
+the Upper Coal-measures. By this simple and obvious kind of evidence the
+relative ages of different mountain-chains may be compared. In most
+great chains, however, the rocks have been so intensely crumpled, and
+even inverted, that much labour may be required before their true
+relations can be determined.
+
+The Alps furnish an instructive example of the long series of
+revolutions through which a great mountain-system may have passed before
+reaching its present development. The first beginnings of the chain may
+have been upraised before the oldest Palaeozoic formations were laid
+down. There are at least traces of land and shore-lines in the
+Carboniferous period. Subsequent submergences and uplifts appear to have
+occurred during the Mesozoic periods. There is evidence that thereafter
+the whole region sank deep under the sea, in which the older Tertiary
+sediments were accumulated, and which seems to have spread right across
+the heart of the Old World. But after the deposition of the Eocene
+formations came the gigantic disruptions whereby all the rocks of the
+Alpine region were folded over each other, crushed, corrugated,
+fractured and displaced, some of their older portions, including the
+fundamental gneisses and schists, being squeezed up, torn off, and
+pushed horizontally for many miles over the younger rocks. But this
+upheaval, though the most momentous, was not the last which the chain
+has undergone, for at a later epoch in Tertiary time renewed disturbance
+gave rise to a further series of ruptures and plications. The chain thus
+successively upheaved has been continuously exposed to denudation and
+has consequently lost much of its original height. That it has been left
+in a state of instability is indicated by the frequent earthquakes of
+the Alpine region, which doubtless arise from the sudden snapping of
+rocks under intense strain.
+
+A distinct type of mountain due to direct hypogene action is to be seen
+in a volcano. It has been already pointed out (Part IV. sect. 1) that at
+the vents which maintain a communication between the molten magma of the
+earth's interior and the surface, eruptions take place whereby
+quantities of lava and fragmentary materials are heaped round each
+orifice of discharge. A typical volcanic mountain takes the form of a
+perfect cone, but as it grows in size and its main vent is choked, while
+the sides of the cone are unable to withstand the force of the
+explosions or the pressure of the ascending column of lava, eruptions
+take place laterally, and numerous parasitic cones arise on the flanks
+of the parent mountain. Where lava flows out from long fissures, it may
+pile up vast sheets of rock, and bury the surrounding country under
+several thousand feet of solid stone, covering many hundreds of square
+miles. In this way volcanic tablelands have been formed which, attacked
+by the denuding forces, are gradually trenched by valleys and ravines,
+until the original level surface of the lava-field may be almost or
+wholly lost. As striking examples of this physiographical type reference
+may be made to the plateau of Abyssinia, the Ghats of India, the
+plateaux of Antrim, the Inner Hebrides and Iceland, and the great
+lava-plains of the western territories of the United States.
+
+2. But while the subterranean movements have upraised portions of the
+surface of the lithosphere above the level of the ocean, and have thus
+been instrumental in producing the existing tracts of land, the detailed
+topographical features of a landscape are not solely, nor in general
+even chiefly, attributable to these movements. From the time that any
+portion of the sea-floor appears above sea-level, it undergoes erosion
+by the various epigene agents. Each climate and geological region has
+its own development of these agents, which include air, aridity, rapid
+and frequent alternations of wetness and dryness or of heat and cold,
+rain, springs, frosts, rivers, glaciers, the sea, plant and animal life.
+In a dry climate subject to great extremes of temperature the character
+and rate of decay will differ from those of a moist or an arctic
+climate. But it must be remembered that, however much they may vary in
+activity and in the results which they effect, the epigene forces work
+without intermission, while the hypogene forces bring about the upheaval
+of land only after long intervals. Hence, trifling as the results during
+a human life may appear, if we realize the multiplying influence of time
+we are led to perceive that the apparently feeble superficial agents
+can, in the course of ages, achieve stupendous transformations in the
+aspect of the land. If this efficacy may be deduced from what can be
+seen to be in progress now, it may not less convincingly be shown, from
+the nature of the sedimentary rocks of the earth's crust, to have been
+in progress from the early beginnings of geological history. Side by
+side with the various upheavals and subsidences, there has been a
+continuous removal of materials from the land, and an equally persistent
+deposit of these materials under water, with the consequent growth of
+new rocks. Denudation has been aptly compared to a process of
+sculpturing wherein, while each of the implements employed by nature,
+like a special kind of graving tool, produces its own characteristic
+impress on the land, they all combine harmoniously towards the
+achievement of their one common task. Hence the present contours of the
+land depend partly on the original configuration of the ground, and the
+influence it may have had in guiding the operations of the erosive
+agents, partly on the vigour with which these agents perform their work,
+and partly on the varying structure and powers of resistance possessed
+by the rocks on which the erosion is carried on.
+
+Where a new tract of land has been raised out of the sea by such an
+energetic movement as broke up the crust and produced the complicated
+structure and tumultuous external forms of a great mountain chain, the
+influence of the hypogene forces on the topography attains its highest
+development. But even the youngest existing chain has suffered so
+greatly from denudation that the aspect which it presented at the time
+of its uplift can only be dimly perceived. No more striking illustration
+of this feature can be found than that supplied by the Alps, nor one
+where the geotectonic structures have been so fully studied in detail.
+On the outer flanks of these mountains the longitudinal ridges and
+valleys of the Jura correspond with lines of anticline and syncline. Yet
+though the dominant topographical elements of the region have obviously
+been produced by the plication of the stratified formations, each ridge
+has suffered so large an amount of erosion that the younger rocks have
+been removed from its crest where the older members of the series are
+now exposed to view, while on every slope proofs may be seen of
+extensive denudation. If from these long wave-like undulations of the
+ground, where the relations between the disposition of the rocks below
+and the forms of the surface are so clearly traceable, the observer
+proceeds inwards to the main chain, he finds that the plications and
+displacements of the various formations assume an increasingly
+complicated character; and that although proofs of great denudation
+continue to abound, it becomes increasingly difficult to form any
+satisfactory conjecture as to the shape of the ground when the upheaval
+ended or any reliable estimate of the amount of material which has since
+then been removed. Along the central heights the mountains lift
+themselves towards the sky like the storm-swept crests of vast
+earth-billows. The whole aspect of the ground suggests intense
+commotion, and the impression thus given is often much intensified by
+the twisted and crumpled strata, visible from a long distance, on the
+crags and crests. On this broken-up surface the various agents of
+denudation have been ceaselessly engaged since it emerged from the sea.
+They have excavated valleys, sometimes along depressions provided for
+them by the subterranean disturbances, sometimes down the slopes of the
+disrupted blocks of ground. So powerful has been this erosion that
+valleys cut out along lines of anticline, which were natural ridges,
+have sometimes become more important than those in lines of syncline,
+which were structurally depressions. The same subaerial forces have
+eroded lake-basins, dug out corries or cirques, notched the ridges,
+splintered the crests and furrowed the slopes, leaving no part of the
+original surface of the uplifted chain unmodified.
+
+It has often been noted with surprise that features of underground
+structure which, it might have been confidently anticipated, should have
+exercised a marked influence on the topography of the surface have not
+been able to resist the levelling action of the denuding agents, and do
+not now affect the surface at all. This result is conspicuously seen in
+coal-fields where the strata are abundantly traversed by faults. These
+dislocations, having sometimes a displacement of several hundred feet,
+might have been expected to break up the surface into a network of
+cliffs and plains; yet in general they do not modify the level character
+of the ground above. One of the most remarkable faults in Europe is the
+great thrust which bounds the southern edge of the Belgian coal-field
+and brings the Devonian rocks above the Coal-measures. It can be traced
+across Belgium into the Boulonnais, and may not improbably run beneath
+the Secondary and Tertiary rocks of the south of England. It is crossed
+by the valleys of the Meuse and other northerly-flowing streams. Yet so
+indistinctly is it marked in the Meuse valley that no one would suspect
+its existence from any peculiarity in the general form of the ground,
+and even an experienced geologist, until he had learned the structure of
+the district, would scarcely detect any fault at all.
+
+Where faults have influenced the superficial topography, it is usually
+by giving rise to a hollow along which the subaerial agents and
+especially running water can act effectively. Such a hollow may be
+eventually widened and deepened into a valley. On bare crags and crests,
+lines of fault are apt to be marked by notches or clefts, and they thus
+help to produce the pinnacles and serrated outlines of these exposed
+uplands.
+
+It was cogently enforced by Hutton and Playfair, and independently by
+Lamarck, that no co-operation of underground agency is needed to produce
+such topography as may be seen in a great part of the world, but that if
+a tract of sea-floor were upraised into a wide plain, the fall of rain
+and the circulation of water over its surface would in the end carve out
+such a system of hills and valleys as may be seen on the dry land now.
+No such plain would be a dead-level. It would have inequalities on its
+surface which would serve as channels to guide the drainage from the
+first showers of rain. And these channels would be slowly widened and
+deepened until they would become ravines and valleys, while the ground
+between them would be left projecting as ridges and hills. Nor would the
+erosion of such a system of water-courses require a long series of
+geological periods for its accomplishment. From measurements and
+estimates of the amount of erosion now taking place in the basin of the
+Mississippi river it has been computed that valleys 800 ft. deep might
+be carved out in less than a million years. In the vast tablelands of
+Colorado and other western regions of the United States an impressive
+picture is presented of the results of mere subaerial erosion on
+undisturbed and nearly level strata. Systems of stream-courses and
+valleys, river gorges unexampled elsewhere in the world for depth and
+length, vast winding lines of escarpment, like ranges of sea-cliffs,
+terraced slopes rising from plateau to plateau, huge buttresses and
+solitary stacks standing like islands out of the plains, great
+mountain-masses towering into picturesque peaks and pinnacles cleft by
+innumerable gullies, yet everywhere marked by the parallel bars of the
+horizontal strata out of which they have been carved--these are the
+orderly symmetrical characteristics of a country where the scenery is
+due entirely to the action of subaerial agents on the one hand and the
+varying resistance of perfectly regular stratified rocks on the other.
+
+The details of the sculpture of the land have mainly depended on the
+nature of the materials on which nature's erosive tools have been
+employed. The joints by which all rocks are traversed have been
+especially serviceable as dominant lines down which the rain has
+filtered, up which the springs have risen and into which the frost
+wedges have been driven. On the high bare scarps of a lofty mountain the
+inner structure of the mass is laid open, and there the system of joints
+even more than faults is seen to have determined the lines of crest, the
+vertical walls of cliff and precipice, the forms of buttress and recess,
+the position of cleft and chasm, the outline of spire and pinnacle. On
+the lower slopes, even under the tapestry of verdure which nature
+delights to hang where she can over her naked rocks, we may detect the
+same pervading influence of the joints upon the forms assumed by ravines
+and crags. Each kind of stone, too, gives rise to its own characteristic
+form of scenery. Massive crystalline rocks, such as granite, break up
+along their joints and often decay into sand or earth along their
+exposed surfaces, giving rise to rugged crags with long talus slopes at
+their base. The stratified rocks besides splitting at their joints are
+especially distinguished by parallel ledges, cornices and recesses,
+produced by the irregular decay of their component strata, so that they
+often assume curiously architectural types of scenery. But besides this
+family feature they display many minor varieties of aspect according to
+their lithological composition. A range of sandstone hills, for example,
+presents a marked contrast to one of limestone, and a line of chalk
+downs to the escarpments formed by alternating bands of harder and
+softer clays and shales.
+
+It may suffice here merely to allude to a few of the more important
+parts of the topography of the land in their relation to physiographical
+geology. A true mountain-chain, viewed from the geological side, is a
+mass of high ground which owes its prominence to a ridging-up of the
+earth's crust, and the intense plication and rupture of the rocks of
+which it is composed. But ranges of hills almost mountainous in their
+bulk may be formed by the gradual erosion of valleys out of a mass of
+original high ground, such as a high plateau or tableland. Eminences
+which have been isolated by denudation from the main mass of the
+formations of which they originally formed part are known as "outliers"
+or "hills of circumdenudation."
+
+Tablelands, as already pointed out, may be produced either by the
+upheaval of tracts of horizontal strata from the sea-floor into land; or
+by the uprise of plains of denudation, where rocks of various
+composition, structure and age have been levelled down to near or below
+the level of the sea by the co-operation of the various erosive agents.
+Most of the great tablelands of the globe are platforms of
+little-disturbed strata which have been upraised bodily to a
+considerable elevation. No sooner, however, are they placed in that
+position than they are attacked by running water, and begin to be
+hollowed out into systems of valleys. As the valleys sink, the platforms
+between them grow into narrower and more definite ridges, until
+eventually the level tableland is converted into a complicated network
+of hills and valleys, wherein, nevertheless, the key to the whole
+arrangement is furnished by a knowledge of the disposition and effects
+of the flow of water. The examples of this process brought to light in
+Colorado, Wyoming, Nevada and the other western regions by Newberry,
+King, Hayden, Powell and other explorers, are among the most striking
+monuments of geological operations in the world.
+
+Examples of ancient and much decayed tablelands formed by the denudation
+of much disturbed rocks are furnished by the Highlands of Scotland and
+of Norway. Each of these tracts of high ground consists of some of the
+oldest and most dislocated formations of Europe, which at a remote
+period were worn down into a plain, and in that condition may have lain
+long submerged under the sea and may possibly have been overspread there
+with younger formations. Having at a much later time been raised several
+thousand feet above sea-level the ancient platforms of Britain and
+Scandinavia have been since exposed to denudation, whereby each of them
+has been so deeply channeled into glens and fjords that it presents
+to-day a surface of rugged hills, either isolated or connected along the
+flanks, while only fragments of the general surface of the tableland can
+here and there be recognized amidst the general destruction.
+
+Valleys have in general been hollowed out by the greater erosive action
+of running water along the channels of drainage. Their direction has
+been probably determined in the great majority of cases by
+irregularities of the surface along which the drainage flowed on the
+first emergence of the land. Sometimes these irregularities have been
+produced by folds of the terrestrial crust, sometimes by faults,
+sometimes by the irregularities on the surface of an uplifted platform
+of deposition or of denudation. Two dominant trends may be observed
+among them. Some are longitudinal and run along the line of flexures in
+the upraised tract of land, others are transverse where the drainage has
+flowed down the slopes of the ridges into the longitudinal valleys or
+into the sea. The forms of valleys have been governed partly by the
+structure and composition of the rocks, and partly by the relative
+potency of the different denuding agents. Where the influence of rain
+and frost has been slight, and the streams, supplied from distant
+sources, have had sufficient declivity, deep, narrow, precipitous
+ravines or gorges have been excavated. The canyons of the arid region of
+the Colorado are a magnificent example of this result. Where, on the
+other hand, ordinary atmospheric action has been more rapid, the sides
+of the river channels have been attacked, and open sloping glens and
+valleys have been hollowed out. A gorge or defile is usually due to the
+action of a waterfall, which, beginning with some abrupt declivity or
+precipice in the course of the river when it first commenced to flow, or
+caused by some hard rock crossing the channel, has eaten its way
+backward.
+
+Lakes have been already referred to, and their modes of origin have been
+mentioned. As they are continually being filled up with the detritus
+washed into them from the surrounding regions they cannot be of any
+great geological antiquity, unless where by some unknown process their
+basins are from time to time widened and deepened.
+
+In the general subaerial denudation of a country, innumerable minor
+features are worked out as the structure of the rocks controls the
+operations of the eroding agents. Thus, among comparatively undisturbed
+strata, a hard bed resting upon others of a softer kind is apt to form
+along its outcrop a line of cliff or escarpment. Though a long range of
+such cliffs resembles a coast that has been worn by the sea, it may be
+entirely due to mere atmospheric waste. Again, the more resisting
+portions of a rock may be seen projecting as crags or knolls. An igneous
+mass will stand out as a bold hill from amidst the more decomposable
+strata through which it has risen. These features, often so marked on
+the lower grounds, attain their most conspicuous development among the
+higher and barer parts of the mountains, where subaerial disintegration
+is most rapid. The torrents tear out deep gullies from the sides of the
+declivities. Corries or cirques are scooped out on the one hand and
+naked precipices are left on the other. The harder bands of rock project
+as massive ribs down the slopes, shoot up into prominent _aiguilles_, or
+help to give to the summits the notched saw-like outlines they so often
+present.
+
+The materials worn from the surface of the higher are spread out over
+the lower grounds. The streams as they descend begin to drop their
+freight of sediment when, by the lessening of their declivity, their
+carrying power is diminished. The great plains of the earth's surface
+are due to this deposit of gravel, sand and loam. They are thus
+monuments at once of the destructive and reproductive processes which
+have been in progress unceasingly since the first land rose above the
+sea and the first shower of rain fell. Every pebble and particle of
+their soil, once part of the distant mountains, has travelled slowly and
+fitfully to lower levels. Again and again have these materials been
+shifted, ever moving downward and sea-ward. For centuries, perhaps, they
+have taken their share in the fertility of the plains and have
+ministered to the nurture of flower and tree, of the bird of the air,
+the beast of the field and of man himself. But their destiny is still
+the great ocean. In that bourne alone can they find undisturbed repose,
+and there, slowly accumulating in massive beds, they will remain until,
+in the course of ages, renewed upheaval shall raise them into future
+land, there once more to pass through the same cycle of change. (A. Ge.)
+
+  LITERATURE.--_Historical_: The standard work is Karl A. von Zittel's
+  _Geschichte der Geologie und Palaontologie_ (1899), of which there is
+  an abbreviated, but still valuable, English translation; D'Archiac,
+  _Histoire des progres de la geologie_, deals especially with the
+  period 1834-1850; Keferstein, _Geschichte und Literatur der
+  Geognosie_, gives a summary up to 1840; while Sir A. Geikie's
+  _Founders of Geology_ (1897; 2nd ed., 1906) deals more particularly
+  with the period 1750-1820. General treatises: Sir Charles Lyell's
+  _Principles of Geology_ is a classic. Of modern English works, Sir A.
+  Geikie's _Text Book of Geology_ (4th ed., 1903) occupies the first
+  place; the work of T.C. Chamberlin and R.D. Salisbury, _Geology; Earth
+  History_ (3 vols., 1905-1906), is especially valuable for American
+  geology. A. de Lapparent's _Traite de geologie_ (5th ed., 1906), is
+  the standard French work. H. Credner's _Elemente der Geologie_ has
+  gone through several editions in Germany. Dynamical and
+  physiographical geology are elaborately treated by E. Suess, _Das
+  Antlitz der Erde_, translated into English, with the title _The Face
+  of the Earth_. The practical study of the science is treated of by F.
+  von Richthofen, _Fuhrer fur Forschungsreisende_ (1886); G.A. Cole,
+  _Aids in Practical Geology_ (5th ed., 1906); A. Geikie, _Outlines of
+  Field Geology_ (5th ed., 1900). The practical applications of Geology
+  are discussed by J.V. Elsden, _Applied Geology_ (1898-1899). The
+  relations of Geology to scenery are dealt with by Sir A. Geikie,
+  _Scenery of Scotland_ (3rd ed., 1901); J.E. Marr, _The Scientific
+  Study of Scenery_ (1900); Lord Avebury, _The Scenery of Switzerland_
+  (1896); _The Scenery of England_ (1902); and J. Geikie, _Earth
+  Sculpture_ (1898). A detailed bibliography is given in Sir A. Geikie's
+  _Text Book of Geology_. See also the separate articles on geological
+  subjects for special references to authorities.
+
+
+FOOTNOTES:
+
+  [1] In De Luc's _Lettres physiques et morales sur les montagnes_
+    (1778), the word "cosmology" is used for our science, the author
+    stating that "geology" is more appropriate, but it "was not a word in
+    use." In a completed edition, published in 1779, the same statement
+    is made, but "geology" occurs in the text; in the same year De
+    Saussure used the word without any explanation, as if it were well
+    known.
+
+  [2] The subject of the age of the earth has also been discussed by
+    Professor J. Joly and Professor W.J. Sollas. The former geologist,
+    approaching the question from a novel point of view, has estimated
+    the total quantity of sodium in the water of the ocean and the
+    quantity of that element received annually by the ocean from the
+    denudation of the land. Dividing the one sum by the other, he arrives
+    at the result that the probable age of the earth is between 90 and
+    100 millions of years (_Trans. Roy. Dublin Soc._ ser. ii. vol. vii.,
+    1899, p. 23: _Geol. Mag._, 1900, p. 220). Professor Sollas believes
+    that this limit exceeds what is required for the evolution of
+    geological history, that the lower limit assigned by Lord Kelvin
+    falls short of what the facts demand, and that geological time will
+    probably be found to have been comprised within some indeterminate
+    period between these limits. (Address to Section C, _Brit. Assoc.
+    Report_, 1900; _Age of the Earth_, London, 1905.)
+
+
+
+
+GEOMETRICAL CONTINUITY. In a report of the Institute prefixed to Jean
+Victor Poncelet's _Traite des proprietes projectives des figures_
+(Paris, 1822), it is said that he employed "ce qu'il appelle le principe
+de continuite." The law or principle thus named by him had, he tells us,
+been tacitly assumed as axiomatic by "les plus savans geometres." It had
+in fact been enunciated as "lex continuationis," and "la loi de la
+continuite," by Gottfried Wilhelm Leibnitz (Oxf. N.E.D.), and previously
+under another name by Johann Kepler in cap. iv. 4 of his _Ad Vitellionem
+paralipomena quibus astronomiae pars optica traditur_ (Francofurti,
+1604). Of sections of the cone, he says, there are five species from the
+"recta linea" or line-pair to the circle. From the line-pair we pass
+through an infinity of hyperbolas to the parabola, and thence through an
+infinity of ellipses to the circle. Related to the sections are certain
+remarkable points which have no name. Kepler calls them foci. The circle
+has one focus at the centre, an ellipse or hyperbola two foci
+equidistant from the centre. The parabola has one focus within it, and
+another, the "caecus focus," which may be imagined to be _at infinity_
+on the axis _within or without the curve_. The line from it to any point
+of the section is parallel to the axis. To carry out the analogy we must
+speak paradoxically, and say that the line-pair likewise has foci, which
+in this case coalesce as in the circle and fall upon the lines
+themselves; for our geometrical terms should be subject to analogy.
+Kepler dearly loves analogies, his most trusty teachers, acquainted with
+all the secrets of nature, "_omnium naturae arcanorum conscios_." And
+they are to be especially regarded in geometry as, by the use of
+"however absurd expressions," classing extreme limiting forms with an
+infinity of intermediate cases, and placing the whole essence of a thing
+clearly before the eyes.
+
+Here, then, we find formulated by Kepler the doctrine of the concurrence
+of parallels at a single point at infinity and the principle of
+continuity (under the name analogy) in relation to the infinitely great.
+Such conceptions so strikingly propounded in a famous work could not
+escape the notice of contemporary mathematicians. Henry Briggs, in a
+letter to Kepler from Merton College, Oxford, dated "10 Cal. Martiis
+1625," suggests improvements in the _Ad Vitellionem paralipomena_, and
+gives the following construction: Draw a line CBADC, and let an ellipse,
+a parabola, and a hyperbola have B and A for focus and vertex. Let CC
+be the other foci of the ellipse and the hyperbola. Make AD equal to AB,
+and with centres CC and radius in each case equal to CD describe
+circles. Then any point of the ellipse is equidistant from the focus B
+and one circle, and any point of the hyperbola from the focus B and the
+other circle. Any point P of the parabola, in which the second focus is
+missing or infinitely distant, is equidistant from the focus B and the
+line through D which we call the directrix, this taking the place of
+either circle when its centre C is at infinity, and every line CP being
+then parallel to the axis. Thus Briggs, and we know not how many "savans
+geometres" who have left no record, had already taken up the new
+doctrine in geometry in its author's lifetime. Six years after Kepler's
+death in 1630 Girard Desargues, "the Monge of his age," brought out the
+first of his remarkable works founded on the same principles, a short
+tract entitled _Methode universelle de mettre en perspective les objets
+donnes reellement ou en devis_ (Paris, 1636); but "Le privilege etoit de
+1630." (Poudra, _[OE]uvres de Des._, i. 55). Kepler as a modern geometer
+is best known by his _New Stereometry of Wine Casks_ (Lincii, 1615), in
+which he replaces the circuitous Archimedean method of exhaustion by a
+direct "royal road" of infinitesimals, treating a vanishing arc as a
+straight line and regarding a curve as made up of a succession of short
+chords. Some 2000 years previously one Antipho, probably the well-known
+opponent of Socrates, has regarded a circle in like manner as the
+limiting form of a many-sided inscribed rectilinear figure. Antipho's
+notion was rejected by the men of his day as unsound, and when
+reproduced by Kepler it was again stoutly opposed as incapable of any
+sort of geometrical demonstration--not altogether without reason, for it
+rested on an assumed law of continuity rather than on palpable proof.
+
+To complete the theory of continuity, the one thing needful was the idea
+of imaginary points implied in the algebraical geometry of Rene
+Descartes, in which equations between variables representing
+co-ordinates were found often to have imaginary roots. Newton, in his
+two sections on "Inventio orbium" (_Principia_ i. 4, 5), shows in his
+brief way that he is familiar with the principles of modern geometry. In
+two propositions he uses an auxiliary line which is supposed to cut the
+conic in X and Y, but, as he remarks at the end of the second (prop.
+24), it may not cut it at all. For the sake of brevity he passes on at
+once with the observation that the required constructions are evident
+from the case in which the line cuts the trajectory. In the scholium
+appended to prop. 27, after saying that an asymptote is a tangent at
+infinity, he gives an unexplained general construction for the axes of a
+conic, which seems to imply that it has asymptotes. In all such cases,
+having equations to his loci in the background, he may have thought of
+elements of the figure as passing into the imaginary state in such
+manner as not to vitiate conclusions arrived at on the hypothesis of
+their reality.
+
+Roger Joseph Boscovich, a careful student of Newton's works, has a full
+and thorough discussion of geometrical continuity in the third and last
+volume of his _Elementa universae matheseos_ (ed. prim. Venet, 1757),
+which contains _Sectionum conicarum elementa nova quadam methodo
+concinnata et dissertationem de transformatione locorum geometricorum,
+ubi de continuitatis lege, et de quibusdam infiniti mysteriis_. His
+first principle is that all varieties of a defined locus have the same
+properties, so that what is demonstrable of one should be demonstrable
+in like manner of all, although some artifice may be required to bring
+out the underlying analogy between them. The opposite extremities of an
+infinite straight line, he says, are to be regarded as joined, as if the
+line were a circle having its centre at the infinity on either side of
+it. This leads up to the idea of a _veluti plus quam infinita extensio_,
+a line-circle containing, as we say, the line infinity. Change from the
+real to the imaginary state is contingent upon the passage of some
+element of a figure through zero or infinity and never takes place _per
+saltum_. Lines being some positive and some negative, there must be
+negative rectangles and negative squares, such as those of the exterior
+diameters of a hyperbola. Boscovich's first principle was that of
+Kepler, by whose _quantumvis absurdis locutionibus_ the boldest
+applications of it are covered, as when we say with Poncelet that all
+concentric circles in a plane touch one another in two imaginary fixed
+points at infinity. In G.K. Ch. von Staudt's _Geometrie der Lage and
+Beitrage zur G. der L._ (Nurnberg, 1847, 1856-1860) the geometry of
+position, including the extension of the field of pure geometry to the
+infinite and the imaginary, is presented as an independent science,
+"welche des Messens nicht bedarf." (See GEOMETRY: _Projective_.)
+
+Ocular illusions due to distance, such as Roger Bacon notices in the
+_Opus majus_ (i. 126, ii. 108, 497; Oxford, 1897), lead up to or
+illustrate the mathematical uses of the infinite and its reciprocal the
+infinitesimal. Specious objections can, of course, be made to the
+anomalies of the law of continuity, but they are inherent in the higher
+geometry, which has taught us so much of the "secrets of nature."
+Kepler's excursus on the "analogy" between the conic sections
+hereinbefore referred to is given at length in an article on "The
+Geometry of Kepler and Newton" in vol. xviii. of the _Transactions of
+the Cambridge Philosophical Society_ (1900). It had been generally
+overlooked, until attention was called to it by the present writer in a
+note read in 1880 (_Proc. C.P.S._ iv. 14-17), and shortly afterwards in
+_The Ancient and Modern Geometry of Conics, with Historical Notes and
+Prolegomena_ (Cambridge 1881).     (C. T.*)
+
+
+
+
+GEOMETRY, the general term for the branch of mathematics which has for
+its province the study of the properties of space. From experience, or
+possibly intuitively, we characterize existent space by certain
+fundamental qualities, termed axioms, which are insusceptible of proof;
+and these axioms, in conjunction with the mathematical entities of the
+point, straight line, curve, surface and solid, appropriately defined,
+are the premises from which the geometer draws conclusions. The
+geometrical axioms are merely conventions; on the one hand, the system
+may be based upon inductions from experience, in which case the deduced
+geometry may be regarded as a branch of physical science; or, on the
+other hand, the system may be formed by purely logical methods, in which
+case the geometry is a phase of pure mathematics. Obviously the geometry
+with which we are most familiar is that of existent space--the
+three-dimensional space of experience; this geometry may be termed
+Euclidean, after its most famous expositor. But other geometries exist,
+for it is possible to frame systems of axioms which definitely
+characterize some other kind of space, and from these axioms to deduce a
+series of non-contradictory propositions; such geometries are called
+non-Euclidean.
+
+It is convenient to discuss the subject-matter of geometry under the
+following headings:
+
+I. _Euclidean Geometry_: a discussion of the axioms of existent space
+and of the geometrical entities, followed by a synoptical account of
+Euclid's Elements.
+
+II. _Projective Geometry_: primarily Euclidean, but differing from I. in
+employing the notion of geometrical continuity (q.v.)--points and lines
+at infinity.
+
+III. _Descriptive Geometry_: the methods for representing upon planes
+figures placed in space of three dimensions.
+
+IV. _Analytical Geometry_: the representation of geometrical figures and
+their relations by algebraic equations.
+
+V. _Line Geometry_: an analytical treatment of the line regarded as the
+space element.
+
+VI. _Non-Euclidean Geometry_: a discussion of geometries other than that
+of the space of experience.
+
+VII. _Axioms of Geometry_: a critical analysis of the foundations of
+geometry.
+
+  Special subjects are treated under their own headings: e.g.
+  PROJECTION, PERSPECTIVE; CURVE, SURFACE; CIRCLE, CONIC SECTION;
+  TRIANGLE, POLYGON, POLYHEDRON; there are also articles on special
+  curves and figures, e.g. ELLIPSE, PARABOLA, HYPERBOLA; TETRAHEDRON,
+  CUBE, OCTAHEDRON, DODECAHEDRON, ICOSAHEDRON; CARDIOID, CATENARY,
+  CISSOID, CONCHOID, CYCLOID, EPICYCLOID, LIMACON, OVAL, QUADRATRIX,
+  SPIRAL, &c.
+
+_History._--The origin of geometry (Gr. [Greek: ge], earth, [Greek:
+metron], a measure) is, according to Herodotus, to be found in the
+etymology of the word. Its birthplace was Egypt, and it arose from the
+need of surveying the lands inundated by the Nile floods. In its
+infancy it therefore consisted of a few rules, very rough and
+approximate, for computing the areas of triangles and quadrilaterals;
+and, with the Egyptians, it proceeded no further, the geometrical
+entities--the point, line, surface and solid--being only discussed in so
+far as they were involved in practical affairs. The point was realized
+as a mark or position, a straight line as a stretched string or the
+tracing of a pole, a surface as an area; but these units were not
+abstracted; and for the Egyptians geometry was only an art--an auxiliary
+to surveying.[1] The first step towards its elevation to the rank of a
+science was made by Thales (q.v.) of Miletus, who transplanted the
+elementary Egyptian mensuration to Greece. Thales clearly abstracted the
+notions of points and lines, founding the geometry of the latter unit,
+and discovering _per saltum_ many propositions concerning areas, the
+circle, &c. The empirical rules of the Egyptians were corrected and
+developed by the Ionic School which he founded, especially by
+Anaximander and Anaxagoras, and in the 6th century B.C. passed into the
+care of the Pythagoreans. From this time geometry exercised a powerful
+influence on Greek thought. Pythagoras (q.v.), seeking the key of the
+universe in arithmetic and geometry, investigated logically the
+principles underlying the known propositions; and this resulted in the
+formulation of definitions, axioms and postulates which, in addition to
+founding a _science_ of geometry, permitted a crystallization,
+fractional, it is true, of the amorphous collection of material at hand.
+Pythagorean geometry was essentially a geometry of areas and solids; its
+goal was the regular solids--the tetrahedron, cube, octahedron,
+dodecahedron and icosahedron--which symbolized the five elements of
+Greek cosmology. The geometry of the circle, previously studied in Egypt
+and much more seriously by Thales, was somewhat neglected, although this
+curve was regarded as the most perfect of all plane figures and the
+sphere the most perfect of all solids. The circle, however, was taken up
+by the Sophists, who made most of their discoveries in attempts to solve
+the classical problems of squaring the circle, doubling the cube and
+trisecting an angle. These problems, besides stimulating pure geometry,
+i.e. the geometry of constructions made by the ruler and compasses,
+exercised considerable influence in other directions. The first problem
+led to the discovery of the method of _exhaustion_ for determining
+areas. Antiphon inscribed a square in a circle, and on each side an
+isosceles triangle having its vertex on the circle; on the sides of the
+octagon so obtained, isosceles triangles were again constructed, the
+process leading to inscribed polygons of 8, 16 and 32 sides; and the
+areas of these polygons, which are easily determined, are successive
+approximations to the area of the circle. Bryson of Heraclea took an
+important step when he circumscribed, in addition to inscribing,
+polygons to a circle, but he committed an error in treating the circle
+as the mean of the two polygons. The method of Antiphon, in assuming
+that by continued division a polygon can be constructed coincident with
+the circle, demanded that magnitudes are not infinitely divisible. Much
+controversy ranged about this point; Aristotle supported the doctrine of
+infinite divisibility; Zeno attempted to show its absurdity. The
+mechanical tracing of loci, a principle initiated by Archytas of
+Tarentum to solve the last two problems, was a frequent subject for
+study, and several mechanical curves were thus discovered at subsequent
+dates (cissoid, conchoid, quadratrix). Mention may be made of
+Hippocrates, who, besides developing the known methods, made a study of
+similar figures, and, as a consequence, of proportion. This step is
+important as bringing into line discontinuous number and continuous
+magnitude.
+
+A fresh stimulus was given by the succeeding Platonists, who, accepting
+in part the Pythagorean cosmology, made the study of geometry
+preliminary to that of philosophy. The many discoveries made by this
+school were facilitated in no small measure by the clarification of the
+axioms and definitions, the logical sequence of propositions which was
+adopted, and, more especially, by the formulation of the analytic
+method, i.e. of assuming the truth of a proposition and then reasoning
+to a known truth. The main strength of the Platonist geometers lies in
+stereometry or the geometry of solids. The Pythagoreans had dealt with
+the sphere and regular solids, but the pyramid, prism, cone and cylinder
+were but little known until the Platonists took them in hand. Eudoxus
+established their mensuration, proving the pyramid and cone to have
+one-third the content of a prism and cylinder on the same base and of
+the same height, and was probably the discoverer of a proof that the
+volumes of spheres are as the cubes of their radii. The discussion of
+sections of the cone and cylinder led to the discovery of the three
+curves named the parabola, ellipse and hyperbola (see CONIC SECTION); it
+is difficult to over-estimate the importance of this discovery; its
+investigation marks the crowning achievement of Greek geometry, and led
+in later years to the fundamental theorems and methods of modern
+geometry.
+
+The presentation of the subject-matter of geometry as a connected and
+logical series of propositions, prefaced by [Greek: Horoi] or
+foundations, had been attempted by many; but it is to Euclid that we owe
+a complete exposition. Little indeed in the _Elements_ is probably
+original except the arrangement; but in this Euclid surpassed such
+predecessors as Hippocrates, Leon, pupil of Neocleides, and Theudius of
+Magnesia, devising an apt logical model, although when scrutinized in
+the light of modern mathematical conceptions the proofs are riddled with
+fallacies. According to the commentator Proclus, the _Elements_ were
+written with a twofold object, first, to introduce the novice to
+geometry, and secondly, to lead him to the regular solids; conic
+sections found no place therein. What Euclid did for the line and
+circle, Apollonius did for the conic sections, but there we have a
+discoverer as well as editor. These two works, which contain the
+greatest contributions to ancient geometry, are treated in detail in
+Section I. _Euclidean Geometry_ and the articles EUCLID; CONIC SECTION;
+APPOLONIUS. Between Euclid and Apollonius there flourished the
+illustrious Archimedes, whose geometrical discoveries are mainly
+concerned with the mensuration of the circle and conic sections, and of
+the sphere, cone and cylinder, and whose greatest contribution to
+geometrical method is the elevation of the method of exhaustion to the
+dignity of an instrument of research. Apollonius was followed by
+Nicomedes, the inventor of the conchoid; Diocles, the inventor of the
+cissoid; Zenodorus, the founder of the study of isoperimetrical figures;
+Hipparchus, the founder of trigonometry; and Heron the elder, who wrote
+after the manner of the Egyptians, and primarily directed attention to
+problems of practical surveying.
+
+Of the many isolated discoveries made by the later Alexandrian
+mathematicians, those of Menelaus are of importance. He showed how to
+treat spherical triangles, establishing their properties and determining
+their congruence; his theorem on the products of the segments in which
+the sides of a triangle are cut by a line was the foundation on which
+Carnot erected his theory of transversals. These propositions, and also
+those of Hipparchus, were utilized and developed by Ptolemy (q.v.), the
+expositor of trigonometry and discoverer of many isolated propositions.
+Mention may be made of the commentator Pappus, whose _Mathematical
+Collections_ is valuable for its wealth of historical matter; of Theon,
+an editor of Euclid's _Elements_ and commentator of Ptolemy's
+_Almagest_; of Proclus, a commentator of Euclid; and of Eutocius, a
+commentator of Apollonius and Archimedes.
+
+The Romans, essentially practical and having no inclination to study
+science _qua_ science, only had a geometry which sufficed for surveying;
+and even here there were abundant inaccuracies, the empirical rules
+employed being akin to those of the Egyptians and Heron. The Hindus,
+likewise, gave more attention to computation, and their geometry was
+either of Greek origin or in the form presented in trigonometry, more
+particularly connected with arithmetic. It had no logical foundations;
+each proposition stood alone; and the results were empirical. The Arabs
+more closely followed the Greeks, a plan adopted as a sequel to the
+translation of the works of Euclid, Apollonius, Archimedes and many
+others into Arabic. Their chief contribution to geometry is exhibited in
+their solution of algebraic equations by intersecting conics, a step
+already taken by the Greeks in isolated cases, but only elevated into a
+_method_ by Omar al Hayyami, who flourished in the 11th century. During
+the middle ages little was added to Greek and Arabic geometry. Leonardo
+of Pisa wrote a _Practica geometriae_ (1220), wherein Euclidean methods
+are employed; but it was not until the 14th century that geometry,
+generally Euclid's _Elements_, became an essential item in university
+curricula. There was, however, no sign of original development, other
+branches of mathematics, mainly algebra and trigonometry, exercising a
+greater fascination until the 16th century, when the subject again came
+into favour.
+
+The extraordinary mathematical talent which came into being in the 16th
+and 17th centuries reacted on geometry and gave rise to all those
+characters which distinguish modern from ancient geometry. The first
+innovation of moment was the formulation of the principle of geometrical
+continuity by Kepler. The notion of infinity which it involved permitted
+generalizations and systematizations hitherto unthought of (see
+GEOMETRICAL CONTINUITY); and the method of indefinite division applied
+to rectification, and quadrature and cubature problems avoided the
+cumbrous method of exhaustion and provided more accurate results.
+Further progress was made by Bonaventura Cavalieri, who, in his
+_Geometria indivisibilibus continuorum_ (1620), devised a method
+intermediate between that of exhaustion and the infinitesimal calculus
+of Leibnitz and Newton. The logical basis of his system was corrected by
+Roberval and Pascal; and their discoveries, taken in conjunction with
+those of Leibnitz, Newton, and many others in the fluxional calculus,
+culminated in the branch of our subject known as differential geometry
+(see INFINITESIMAL CALCULUS; CURVE; SURFACE).
+
+A second important advance followed the recognition that conics could be
+regarded as projections of a circle, a conception which led at the hands
+of Desargues and Pascal to modern _projective geometry_ and
+_perspective_. A third, and perhaps the most important, advance attended
+the application of algebra to geometry by Descartes, who thereby founded
+_analytical geometry_. The new fields thus opened up were diligently
+explored, but the calculus exercised the greatest attraction and
+relatively little progress was made in geometry until the beginning of
+the 19th century, when a new era opened.
+
+Gaspard Monge was the first important contributor, stimulating
+analytical and differential geometry and founding _descriptive geometry_
+in a series of papers and especially in his lectures at the Ecole
+polytechnique. Projective geometry, founded by Desargues, Pascal, Monge
+and L.N.M. Carnot, was crystallized by J.V. Poncelet, the creator of the
+modern methods. In his _Traite des proprietes des figures_ (1822) the
+line and circular points at infinity, imaginaries, polar reciprocation,
+homology, cross-ratio and projection are systematically employed. In
+Germany, A.F. Mobius, J. Plucker and J. Steiner were making far-reaching
+contributions. Mobius, in his _Barycentrische Calcul_ (1827), introduced
+homogeneous co-ordinates, and also the powerful notion of geometrical
+transformation, including the special cases of collineation and duality;
+Plucker, in his _Analytisch-geometrische Entwickelungen_ (1828-1831),
+and his _System der analytischen Geometrie_ (1835), introduced the
+abridged notation, line and plane co-ordinates, and the conception of
+generalized space elements; while Steiner, besides enriching geometry in
+numerous directions, was the first to systematically generate figures by
+projective pencils. We may also notice M. Chasles, whose _Apercu
+historique_ (1837) is a classic. Synthetic geometry, characterized by
+its fruitfulness and beauty, attracted most attention, and it so
+happened that its originally weak logical foundations became replaced by
+a more substantial set of axioms. These were found in the anharmonic
+ratio, a device leading to the liberation of synthetic geometry from
+metrical relations, and in involution, which yielded rigorous
+definitions of imaginaries. These innovations were made by K.J.C. von
+Staudt. Analytical geometry was stimulated by the algebra of invariants,
+a subject much developed by A. Cayley, G. Salmon, S.H. Aronhold, L.O.
+Hesse, and more particularly by R.F.A. Clebsch.
+
+The introduction of the line as a space element, initiated by H.
+Grassmann (1844) and Cayley (1859), yielded at the hands of Plucker a
+new geometry, termed _line geometry_, a subject developed more notably
+by F. Klein, Clebsch, C.T. Reye and F.O.R. Sturm (see Section V., _Line
+Geometry_).
+
+_Non-euclidean geometries_, having primarily their origin in the
+discussion of Euclidean parallels, and treated by Wallis, Saccheri and
+Lambert, have been especially developed during the 19th century. Four
+lines of investigation may be distinguished:--the naive-synthetic,
+associated with Lobatschewski, Bolyai, Gauss; the metric differential,
+studied by Riemann, Helmholtz, Beltrami; the projective, developed by
+Cayley, Klein, Clifford; and the critical-synthetic, promoted chiefly by
+the Italian mathematicians Peano, Veronese, Burali-Forte, Levi Civitta,
+and the Germans Pasch and Hilbert.     (C. E.*)
+
+
+I. EUCLIDEAN GEOMETRY
+
+This branch of the science of geometry is so named since its methods and
+arrangement are those laid down in Euclid's _Elements_.
+
+S 1. _Axioms._--The object of geometry is to investigate the properties
+of space. The first step must consist in establishing those fundamental
+properties from which all others follow by processes of deductive
+reasoning. They are laid down in the Axioms, and these ought to form
+such a system that nothing need be added to them in order fully to
+characterize space, and that nothing may be omitted without making the
+system incomplete. They must, in fact, completely "define" space.
+
+S 2. _Definitions._--The axioms of Euclidean Geometry are obtained from
+inspection of existent space and of solids in existent space,--hence
+from experience. The same source gives us the notions of the geometrical
+entities to which the axioms relate, viz. solids, surfaces, lines or
+curves, and points. A solid is directly given by experience; we have
+only to abstract all material from it in order to gain the notion of a
+geometrical solid. This has shape, size, position, and may be moved. Its
+boundary or boundaries are called surfaces. They separate one part of
+space from another, and are said to have no thickness. Their boundaries
+are curves or lines, and these have length only. Their boundaries,
+again, are points, which have no magnitude but only position. We thus
+come in three steps from solids to points which have no magnitude; in
+each step we lose one extension. Hence we say a solid has three
+dimensions, a surface two, a line one, and a point none. Space itself,
+of which a solid forms only a part, is also said to be of three
+dimensions. The same thing is intended to be expressed by saying that a
+solid has length, breadth and thickness, a surface length and breadth, a
+line length only, and a point no extension whatsoever.
+
+Euclid gives the essence of these statements as definitions:--
+
+  Def. 1, I. _A point is that which has no parts, or which has no
+  magnitude._
+
+  Def. 2, I. _A line is length without breadth._
+
+  Def. 5, I. _A superficies is that which has only length and breadth._
+
+  Def. 1, XI. _A solid is that which has length, breadth and thickness._
+
+It is to be noted that the synthetic method is adopted by Euclid; the
+analytical derivation of the successive ideas of "surface," "line," and
+"point" from the experimental realization of a "solid" does not find a
+place in his system, although possessing more advantages.
+
+If we allow motion in geometry, we may generate these entities by moving
+a point, a line, or a surface, thus:--
+
+  The path of a moving point is a line.
+
+  The path of a moving line is, in general, a surface.
+
+  The path of a moving surface is, in general, a solid.
+
+And we may then assume that the lines, surfaces and solids, as defined
+before, can all be generated in this manner. From this generation of the
+entities it follows again that the boundaries--the first and last
+position of the moving element--of a line are points, and so on; and
+thus we come back to the considerations with which we started.
+
+Euclid points this out in his definitions,--Def. 3, I., Def. 6, I., and
+Def. 2, XI. He does not, however, show the connexion which these
+definitions have with those mentioned before. When points and lines have
+been defined, a statement like Def. 3, I., "The extremities of a line
+are points," is a proposition which either has to be proved, and then it
+is a theorem, or which has to be taken for granted, in which case it is
+an axiom. And so with Def. 6, I., and Def. 2, XI.
+
+S 3. Euclid's definitions mentioned above are attempts to describe, in a
+few words, notions which we have obtained by inspection of and
+abstraction from solids. A few more notions have to be added to these,
+principally those of the simplest line--the straight line, and of the
+simplest surface--the flat surface or plane. These notions we possess,
+but to define them accurately is difficult. Euclid's Definition 4, I.,
+"A straight line is that which lies evenly between its extreme points,"
+must be meaningless to any one who has not the notion of straightness in
+his mind. Neither does it state a property of the straight line which
+can be used in any further investigation. Such a property is given in
+Axiom 10, I. It is really this axiom, together with Postulates 2 and 3,
+which characterizes the straight line.
+
+Whilst for the straight line the verbal definition and axiom are kept
+apart, Euclid mixes them up in the case of the plane. Here the
+Definition 7, I., includes an axiom. It defines a plane as a surface
+which has the property that every straight line which joins any two
+points in it lies altogether in the surface. But if we take a straight
+line and a point in such a surface, and draw all straight lines which
+join the latter to all points in the first line, the surface will be
+fully determined. This construction is therefore sufficient as a
+definition. That every other straight line which joins any two points in
+this surface lies altogether in it is a further property, and to assume
+it gives another axiom.
+
+Thus a number of Euclid's axioms are hidden among his first definitions.
+A still greater confusion exists in the present editions of Euclid
+between the postulates and axioms so called, but this is due to later
+editors and not to Euclid himself. The latter had the last three axioms
+put together with the postulates [Greek: (aitemata)], so that these were
+meant to include all assumptions relating to space. The remaining
+assumptions, which relate to magnitudes in general, viz. the first eight
+"axioms" in modern editions, were called "common notions" [Greek:
+(koivai ennoiai)]. Of the latter a few may be said to be definitions.
+Thus the eighth might be taken as a definition of "equal," and the
+seventh of "halves." If we wish to collect the axioms used in Euclid's
+_Elements_, we have therefore to take the three postulates, the last
+three axioms as generally given, a few axioms hidden in the definitions,
+and an axiom used by Euclid in the proof of Prop. 4, I, and on a few
+other occasions, viz. that figures may be moved in space without change
+of shape or size.
+
+  S 4. _Postulates._--The assumptions actually made by Euclid may be
+  stated as follows:--
+
+  (1) Straight lines exist which have the property that any one of them
+  may be produced both ways without limit, that through any two points
+  in space such a line may be drawn, and that any two of them coincide
+  throughout their indefinite extensions as soon as two points in the
+  one coincide with two points in the other. (This gives the contents of
+  Def. 4, part of Def. 35, the first two Postulates, and Axiom 10.)
+
+  (2) Plane surfaces or planes exist having the property laid down in
+  Def. 7, that every straight line joining any two points in such a
+  surface lies altogether in it.
+
+  (3) Right angles, as defined in Def. 10, are possible, and all right
+  angles are equal; that is to say, wherever in space we take a plane,
+  and wherever in that plane we construct a right angle, all angles thus
+  constructed will be equal, so that any one of them may be made to
+  coincide with any other. (Axiom 11.)
+
+  (4) The 12th Axiom of Euclid. This we shall not state now, but only
+  introduce it when we cannot proceed any further without it.
+
+  (5) Figures maybe freely moved in space without change of shape or
+  size. This is assumed by Euclid, but not stated as an axiom.
+
+  (6) In any plane a circle may be described, having any point in that
+  plane as centre, and its distance from any other point in that plane
+  as radius. (Postulate 3.)
+
+The definitions which have not been mentioned are all "nominal
+definitions," that is to say, they fix a name for a thing described.
+Many of them overdetermine a figure.
+
+S 5. Euclid's _Elements_ (see EUCLID) are contained in thirteen books.
+Of these the first four and the sixth are devoted to "plane geometry,"
+as the investigation of figures in a plane is generally called. The 5th
+book contains the theory of proportion which is used in Book VI. The
+7th, 8th and 9th books are purely arithmetical, whilst the 10th contains
+a most ingenious treatment of geometrical irrational quantities. These
+four books will be excluded from our survey. The remaining three books
+relate to figures in space, or, as it is generally called, to "solid
+geometry." The 7th, 8th, 9th, 10th, 13th and part of the 11th and 12th
+books are now generally omitted from the school editions of the
+_Elements_. In the first four and in the 6th book it is to be understood
+that all figures are drawn in a plane.
+
+
+  BOOK I. OF EUCLID'S "ELEMENTS."
+
+  S 6. According to the third postulate it is possible to draw in any
+  plane a circle which has its centre at any given point, and its radius
+  equal to the distance of this point from any other point given in the
+  plane. This makes it possible (Prop. 1) to construct on a given line
+  AB an equilateral triangle, by drawing first a circle with A as centre
+  and AB as radius, and then a circle with B as centre and BA as radius.
+  The point where these circles intersect--that they intersect Euclid
+  quietly assumes--is the vertex of the required triangle. Euclid does
+  not suppose, however, that a circle may be drawn which has its radius
+  equal to the distance between any two points unless one of the points
+  be the centre. This implies also that we are not supposed to be able
+  to make any straight line equal to any other straight line, or to
+  carry a distance about in space. Euclid therefore next solves the
+  problem: It is required along a given straight line from a point in it
+  to set off a distance equal to the length of another straight line
+  given anywhere in the plane. This is done in two steps. It is shown in
+  Prop. 2 how a straight line may be drawn from a given point equal in
+  length to another given straight line not drawn from that point. And
+  then the problem itself is solved in Prop. 3, by drawing first through
+  the given point some straight line of the required length, and then
+  about the same point as centre a circle having this length as radius.
+  This circle will cut off from the given straight line a length equal
+  to the required one. Nowadays, instead of going through this long
+  process, we take a pair of compasses and set off the given length by
+  its aid. This assumes that we may move a length about without changing
+  it. But Euclid has not assumed it, and this proceeding would be fully
+  justified by his desire not to take for granted more than was
+  necessary, if he were not obliged at his very next step actually to
+  make this assumption, though without stating it.
+
+  S 7. We now come (in Prop. 4) to the first theorem. It is the
+  fundamental theorem of Euclid's whole system, there being only a very
+  few propositions (like Props. 13, 14, 15, I.), except those in the 5th
+  book and the first half of the 11th, which do not depend upon it. It
+  is stated very accurately, though somewhat clumsily, as follows:--
+
+  _If two triangles have two sides of the one equal to two sides of the
+  other, each to each, and have also the angles contained by those sides
+  equal to one another, they shall also have their bases or third sides
+  equal; and the two triangles shall be equal; and their other angles
+  shall be equal, each to each, namely, those to which the equal sides
+  are opposite._
+
+  That is to say, the triangles are "identically" equal, and one may be
+  considered as a copy of the other. The proof is very simple. The first
+  triangle is taken up and placed on the second, so that the parts of
+  the triangles which are known to be equal fall upon each other. It is
+  then easily seen that also the remaining parts of one coincide with
+  those of the other, and that they are therefore equal. This process of
+  applying one figure to another Euclid scarcely uses again, though many
+  proofs would be simplified by doing so. The process introduces motion
+  into geometry, and includes, as already stated, the axiom that figures
+  may be moved without change of shape or size.
+
+  If the last proposition be applied to an isosceles triangle, which has
+  two sides equal, we obtain the theorem (Prop. 5), _if two sides of a
+  triangle are equal, then the angles opposite these sides are equal_.
+
+  Euclid's proof is somewhat complicated, and a stumbling-block to many
+  schoolboys. The proof becomes much simpler if we consider the
+  isosceles triangle ABC (AB = AC) twice over, once as a triangle BAC,
+  and once as a triangle CAB; and now remember that AB, AC in the first
+  are equal respectively to AC, AB in the second, and the angles
+  included by these sides are equal. Hence the triangles are equal, and
+  the angles in the one are equal to those in the other, viz. those
+  which are opposite equal sides, i.e. angle ABC in the first equals
+  angle ACB in the second, as they are opposite the equal sides AC and
+  AB in the two triangles.
+
+  There follows the converse theorem (Prop. 6). _If two angles in a
+  triangle are equal, then the sides opposite them are equal_,--i.e. the
+  triangle is isosceles. The proof given consists in what is called a
+  _reductio ad absurdum_, a kind of proof often used by Euclid, and
+  principally in proving the converse of a previous theorem. It assumes
+  that the theorem to be proved is wrong, and then shows that this
+  assumption leads to an absurdity, i.e. to a conclusion which is in
+  contradiction to a proposition proved before--that therefore the
+  assumption made cannot be true, and hence that the theorem is true. It
+  is often stated that Euclid invented this kind of proof, but the
+  method is most likely much older.
+
+  S 8. It is next proved that _two triangles which have the three sides
+  of the one equal respectively to those of the other are identically
+  equal, hence that the angles of the one are equal respectively to
+  those of the other, those being equal which are opposite equal sides_.
+  This is Prop. 8, Prop. 7 containing only a first step towards its
+  proof.
+
+  These theorems allow now of the solution of a number of problems,
+  viz.:--
+
+  _To bisect a given angle_ (Prop. 9).
+
+  _To bisect a given finite straight line_ (Prop. 10).
+
+  _To draw a straight line perpendicularly to a given straight line
+  through a given point in it_ (Prop. 11), _and also through a given
+  point not in it_ (Prop. 12).
+
+  The solutions all depend upon properties of isosceles triangles.
+
+  S 9. The next three theorems relate to angles only, and might have
+  been proved before Prop. 4, or even at the very beginning. The first
+  (Prop. 13) says, _The angles which one straight line makes with
+  another straight line on one side of it either are two right angles or
+  are together equal to two right angles_. This theorem would have been
+  unnecessary if Euclid had admitted the notion of an angle such that
+  its two limits are in the same straight line, and had besides defined
+  the sum of two angles.
+
+  Its converse (Prop. 14) is of great use, inasmuch as it enables us in
+  many cases to prove that two straight lines drawn from the same point
+  are one the continuation of the other. So also is
+
+  Prop. 15. _If two straight lines cut one another, the vertical or
+  opposite angles shall be equal._
+
+  S 10. Euclid returns now to properties of triangles. Of great
+  importance for the next steps (though afterwards superseded by a more
+  complete theorem) is
+
+  Prop. 16. _If one side of a triangle be produced, the exterior angle
+  shall be greater than either of the interior opposite angles._
+
+  Prop. 17. _Any two angles of a triangle are together less than two
+  right angles, is an immediate consequence of it._ By the aid of these
+  two, the following fundamental properties of triangles are easily
+  proved:--
+
+  Prop. 18. _The greater side of every triangle has the greater angle
+  opposite to it_;
+
+  Its converse, Prop. 19. _The greater angle of every triangle is
+  subtended by the greater side, or has the greater side opposite to
+  it_;
+
+  Prop. 20. _Any two sides of a triangle are together greater than the
+  third side_;
+
+  And also Prop. 21. _If from the ends of the side of a triangle there
+  be drawn two straight lines to a point within the triangle, these
+  shall be less than the other two sides of the triangle, but shall
+  contain a greater angle._
+
+  S 11. Having solved two problems (Props. 22, 23), he returns to two
+  triangles which have two sides of the one equal respectively to two
+  sides of the other. It is known (Prop. 4) that if the included angles
+  are equal then the third sides are equal; and conversely (Prop. 8), if
+  the third sides are equal, then the angles included by the first sides
+  are equal. From this it follows that if the included angles are not
+  equal, the third sides are not equal; and conversely, that if the
+  third sides are not equal, the included angles are not equal. Euclid
+  now completes this knowledge by proving, that "_if the included angles
+  are not equal, then the third side in that triangle is the greater
+  which contains the greater angle_"; and conversely, that "_if the
+  third sides are unequal, that triangle contains the greater angle
+  which contains the greater side_." These are Prop. 24 and Prop. 25.
+
+  S 12. The next theorem (Prop. 26) says that _if two triangles have one
+  side and two angles of the one equal respectively to one side and two
+  angles of the other, viz. in both triangles either the angles adjacent
+  to the equal side, or one angle adjacent and one angle opposite it,
+  then the two triangles are identically equal_.
+
+  This theorem belongs to a group with Prop. 4 and Prop. 8. Its first
+  case might have been given immediately after Prop. 4, but the second
+  case requires Prop. 16 for its proof.
+
+  S 13. We come now to the investigation of parallel straight lines,
+  i.e. of straight lines which lie in the same plane, and cannot be made
+  to meet however far they be produced either way. The investigation
+  which starts from Prop. 16, will become clearer if a few names be
+  explained which are not all used by Euclid. If two straight lines be
+  cut by a third, the latter is now generally called a "transversal" of
+  the figure. It forms at the two points where it cuts the given lines
+  four angles with each. Those of the angles which lie between the given
+  lines are called interior angles, and of these, again, any two which
+  lie on opposite sides of the transversal but one at each of the two
+  points are called "alternate angles."
+
+  We may now state Prop. 16 thus:--_If two straight lines which meet are
+  cut by a transversal, their alternate angles are unequal_. For the
+  lines will form a triangle, and one of the alternate angles will be an
+  exterior angle to the triangle, the other interior and opposite to it.
+
+  From this follows at once the theorem contained in Prop. 27. _If two
+  straight lines which are cut by a transversal make alternate angles
+  equal, the lines cannot meet, however far they be produced, hence they
+  are parallel._ This proves the existence of parallel lines.
+
+  Prop. 28 states the same fact in different forms. _If a straight line,
+  falling on two other straight lines, make the exterior angle equal to
+  the interior and opposite angle on the same side of the line, or make_
+  _the interior angles on the same side together equal to two right
+  angles, the two straight lines shall be parallel to one another_.
+
+  Hence we know that, "if two straight lines which are cut by a
+  transversal meet, their alternate angles are not equal"; and hence
+  that, "if alternate angles are equal, then the lines are parallel."
+
+  The question now arises, Are the propositions converse to these true
+  or not? That is to say, "If alternate angles are unequal, do the lines
+  meet?" And "if the lines are parallel, are alternate angles
+  necessarily equal?"
+
+  The answer to either of these two questions implies the answer to the
+  other. But it has been found impossible to prove that the negation or
+  the affirmation of either is true.
+
+  The difficulty which thus arises is overcome by Euclid assuming that
+  the first question has to be answered in the affirmative. This gives
+  his last axiom (12), which we quote in his own words.
+
+  Axiom 12.--_If a straight line meet two straight lines, so as to make
+  the two interior angles on the same side of it taken together less
+  than two right angles, these straight lines, being continually
+  produced, shall at length meet on that side on which are the angles
+  which are less than two right angles._
+
+  The answer to the second of the above questions follows from this, and
+  gives the theorem Prop. 29:--_If a straight line fall on two parallel
+  straight lines, it makes the alternate angles equal to one another,
+  and the exterior angle equal to the interior and opposite angle on the
+  same side, and also the two interior angles on the same side together
+  equal to two right angles_.
+
+  S 14. With this a new part of elementary geometry begins. The earlier
+  propositions are independent of this axiom, and would be true even if
+  a wrong assumption had been made in it. They all relate to figures in
+  a plane. But a plane is only one among an infinite number of
+  conceivable surfaces. We may draw figures on any one of them and study
+  their properties. We may, for instance, take a sphere instead of the
+  plane, and obtain "spherical" in the place of "plane" geometry. If on
+  one of these surfaces lines and figures could be drawn, answering to
+  all the definitions of our plane figures, and if the axioms with the
+  exception of the last all hold, then all propositions up to the 28th
+  will be true for these figures. This is the case in spherical geometry
+  if we substitute "shortest line" or "great circle" for "straight
+  line," "small circle" for "circle," and if, besides, we limit all
+  figures to a part of the sphere which is less than a hemisphere, so
+  that two points on it cannot be opposite ends of a diameter, and
+  therefore determine always one and only one great circle.
+
+  For spherical triangles, therefore, all the important propositions 4,
+  8, 26; 5 and 6; and 18, 19 and 20 will hold good.
+
+  This remark will be sufficient to show the impossibility of proving
+  Euclid's last axiom, which would mean proving that this axiom is a
+  consequence of the others, and hence that the theory of parallels
+  would hold on a spherical surface, where the other axioms do hold,
+  whilst parallels do not even exist.
+
+  It follows that the axiom in question states an inherent difference
+  between the plane and other surfaces, and that the plane is only fully
+  characterized when this axiom is added to the other assumptions.
+
+  S 15. The introduction of the new axiom and of parallel lines leads to
+  a new class of propositions.
+
+  After proving (Prop. 30) that "_two lines which are each parallel to a
+  third are parallel to each other_," we obtain the new properties of
+  triangles contained in Prop. 32. Of these the second part is the most
+  important, viz. the theorem, _The three interior angles of every
+  triangle are together equal to two right angles_.
+
+  As easy deductions not given by Euclid but added by Simson follow the
+  propositions about the angles in polygons, they are given in English
+  editions as corollaries to Prop. 32.
+
+  These theorems do not hold for spherical figures. The sum of the
+  interior angles of a spherical triangle is always greater than two
+  right angles, and increases with the area.
+
+  S 16. The theory of parallels as such may be said to be finished with
+  Props. 33 and 34, which state properties of the parallelogram, i.e. of
+  a quadrilateral formed by two pairs of parallels. They are--
+
+  Prop. 33. _The straight lines which join the extremities of two equal
+  and parallel straight lines towards the same parts are themselves
+  equal and parallel_; and
+
+  Prop. 34. _The opposite sides and angles of a parallelogram are equal
+  to one another, and the diameter (diagonal) bisects the parallelogram,
+  that is, divides it into two equal parts._
+
+  S 17. The rest of the first book relates to areas of figures.
+
+  The theory is made to depend upon the theorems--
+
+  Prop. 35. _Parallelograms on the same base and between the same
+  parallels are equal to one another_; and
+
+  Prop. 36. _Parallelograms on equal bases and between the same
+  parallels are equal to one another_.
+
+  As each parallelogram is bisected by a diagonal, the last theorems
+  hold also if the word parallelogram be replaced by "triangle," as is
+  done in Props. 37 and 38.
+
+  It is to be remarked that Euclid proves these propositions only in the
+  case when the parallelograms or triangles have their bases in the same
+  straight line.
+
+  The theorems converse to the last form the contents of the next three
+  propositions, viz.: Props, 40 and 41.--_Equal triangles, on the same
+  or on equal bases, in the same straight line, and on the same side of
+  it, are between the same parallels_.
+
+  That the two cases here stated are given by Euclid in two separate
+  propositions proved separately is characteristic of his method.
+
+  S 18. To compare areas of other figures, Euclid shows first, in Prop.
+  42, how _to draw a parallelogram which is equal in area to a given
+  triangle, and has one of its angles equal to a given angle_. If the
+  given angle is right, then the problem is solved _to draw a
+  "rectangle" equal in area to a given triangle_.
+
+  Next this parallelogram is transformed into another parallelogram,
+  _which has one of its sides equal to a given straight line_, whilst
+  its angles remain unaltered. This may be done by aid of the theorem in
+
+  Prop. 43. _The complements of the parallelograms which are about the
+  diameter of any parallelogram are equal to one another._
+
+  Thus the problem (Prop. 44) is solved to _construct a parallelogram on
+  a given line, which is equal in area to a given triangle, and which
+  has one angle equal to a given angle_ (generally a right angle).
+
+  As every polygon can be divided into a number of triangles, we can now
+  construct a parallelogram having a given angle, say a right angle, and
+  being equal in area to a given polygon. For each of the triangles into
+  which the polygon has been divided, a parallelogram may be
+  constructed, having one side equal to a given straight line and one
+  angle equal to a given angle. If these parallelograms be placed side
+  by side, they may be added together to form a single parallelogram,
+  having still one side of the given length. This is done in Prop. 45.
+
+  Herewith a means is found to compare areas of different polygons. We
+  need only construct two rectangles equal in area to the given
+  polygons, and having each one side of given length. By comparing the
+  unequal sides we are enabled to judge whether the areas are equal, or
+  which is the greater. Euclid does not state this consequence, but the
+  problem is taken up again at the end of the second book, where it is
+  shown how to construct a square equal in area to a given polygon.
+
+  Prop. 46 is: _To describe a square on a given straight line_.
+
+  S 19. The first book concludes with one of the most important theorems
+  in the whole of geometry, and one which has been celebrated since the
+  earliest times. It is stated, but on doubtful authority, that
+  Pythagoras discovered it, and it has been called by his name. If we
+  call that side in a right-angled triangle which is opposite the right
+  angle the hypotenuse, we may state it as follows:--
+
+  Theorem of Pythagoras (Prop. 47).--_In every right-angled triangle the
+  square on the hypotenuse is equal to the sum of the squares of the
+  other sides._
+
+  And conversely--
+
+  Prop. 48. _If the square described on one of the sides of a triangle
+  be equal to the squares described on the other sides, then the angle
+  contained by these two sides is a right angle._
+
+  On this theorem (Prop. 47) almost all geometrical measurement depends,
+  which cannot be directly obtained.
+
+
+  BOOK II.
+
+  S 20. The propositions in the second book are very different in
+  character from those in the first; they all relate to areas of
+  rectangles and squares. Their true significance is best seen by
+  stating them in an algebraic form. This is often done by expressing
+  the lengths of lines by aid of numbers, which tell how many times a
+  chosen unit is contained in the lines. If there is a unit to be found
+  which is contained an exact number of times in each side of a
+  rectangle, it is easily seen, and generally shown in the teaching of
+  arithmetic, that the rectangle contains a number of unit squares equal
+  to the product of the numbers which measure the sides, a unit square
+  being the square on the unit line. If, however, no such unit can be
+  found, this process requires that connexion between lines and numbers
+  which is only established by aid of ratios of lines, and which is
+  therefore at this stage altogether inadmissible. But there exists
+  another way of connecting these propositions with algebra, based on
+  modern notions which seem destined greatly to change and to simplify
+  mathematics. We shall introduce here as much of it as is required for
+  our present purpose.
+
+  At the beginning of the second book we find a definition according to
+  which "a rectangle is said to be 'contained' by the two sides which
+  contain one of its right angles"; in the text this phraseology is
+  extended by speaking of rectangles contained by any two straight
+  lines, meaning the rectangle which has two adjacent sides equal to the
+  two straight lines.
+
+  We shall denote a finite straight line by a single small letter, a, b,
+  c, ... x, and the area of the rectangle contained by two lines a and b
+  by ab, and this we shall call the product of the two lines a and b. It
+  will be understood that this definition has nothing to do with the
+  definition of a product of numbers.
+
+  We define as follows:--
+
+  The _sum_ of two straight lines a and b means a straight line c which
+  may be divided in two parts equal respectively to a and b. This sum is
+  denoted by a + b.
+
+  The _difference_ of two lines a and b (in symbols, a-b) means a line c
+  which when added to b gives a; that is,
+
+    a - b = c if b + c = a.
+
+  The _product_ of two lines a and b (in symbols, ab) means the area of
+  the rectangle contained by the lines a and b. For aa, which means the
+  square on the line a, we write a^2.
+
+  S 21. The first ten of the fourteen propositions of the second book
+  may then be written in the form of formulae as follows:--
+
+    Prop. 1. a(b + c + d + ... ) = ab + ac + ad + ...
+
+      "   2. ab + ac = a^2 if b + c = a.
+
+      "   3. a(a + b) = a^2 + ab.
+
+      "   4. (a + b)^2 = a^2 + 2ab + b^2.
+
+      "   5. (a + b)(a - b) + b^2 = a^2.
+
+      "   6. (a + b)(a - b) + b^2 = a^2.
+
+      "   7. a^2 + (a - b)^2 = 2a(a - b) + b^2.
+
+      "   8. 4(a + b)a + b^2 = (2a + b)^2.
+
+      "   9. (a + b)^2 + (a - b)^2 = 2a^2 + 2b^2.
+
+      "  10. (a + b)^2 + (a - b)^2 = 2a^2 + 2b^2.
+
+  It will be seen that 5 and 6, and also 9 and 10, are identical. In
+  Euclid's statement they do not look the same, the figures being
+  arranged differently.
+
+  If the letters a, b, c, ... denoted numbers, it follows from algebra
+  that each of these formulae is true. But this does not prove them in
+  our case, where the letters denote lines, and their products areas
+  without any reference to numbers. To prove them we have to discover
+  the laws which rule the operations introduced, viz. addition and
+  multiplication of segments. This we shall do now; and we shall find
+  that these laws are the same with those which hold in algebraical
+  addition and multiplication.
+
+  S 22. In a sum of numbers we may change the order in which the numbers
+  are added, and we may also add the numbers together in groups and then
+  add these groups. But this also holds for the sum of segments and for
+  the sum of rectangles, as a little consideration shows. That the sum
+  of rectangles has always a meaning follows from the Props. 43-45 in
+  the first book. These laws about addition are reducible to the two--
+
+    a + b = b + a            (1),
+
+    a + (b + c) = a + b + c  (2);
+
+  or, when expressed for rectangles,
+
+    ab + ed = ed + ab              (3),
+
+    ab + (cd + ef) = ab + cd + ef  (4).
+
+  The brackets mean that the terms in the bracket have been added
+  together before they are added to another term. The more general cases
+  for more terms may be deduced from the above.
+
+  For the product of two numbers we have the law that it remains
+  unaltered if the factors be interchanged. This also holds for our
+  geometrical product. For if ab denotes the area of the rectangle which
+  has a as base and b as altitude, then ba will denote the area of the
+  rectangle which has b as base and a as altitude. But in a rectangle we
+  may take either of the two lines which contain it as base, and then
+  the other will be the altitude. This gives
+
+    ab = ba       (5).
+
+  In order further to multiply a sum by a number, we have in algebra the
+  rule:--Multiply each term of the sum, and add the products thus
+  obtained. That this holds for our geometrical products is shown by
+  Euclid in his first proposition of the second book, where he proves
+  that the area of a rectangle whose base is the sum of a number of
+  segments is equal to the sum of rectangles which have these segments
+  separately as bases. In symbols this gives, in the simplest case,
+
+     a(b + c) = ab + ac   \
+                           >  (6).
+  and (b + c)a = ba + ca  /
+
+  To these laws, which have been investigated by Sir William Hamilton
+  and by Hermann Grassmann, the former has given special names. He calls
+  the laws expressed in
+
+    (1) and (3) the commutative law for addition;
+
+            (5)          "       "   "  multiplication;
+
+    (2) and (4) the associative laws for addition;
+
+            (6) the distributive law.
+
+  S 23. Having proved that these six laws hold, we can at once prove
+  every one of the above propositions in their algebraical form.
+
+  The first is proved geometrically, it being one of the fundamental
+  laws. The next two propositions are only special cases of the first.
+  Of the others we shall prove one, viz. the fourth:--
+
+         (a + b)^2 = (a + b)(a + b) = (a + b)a + (a + b)b   by (6).
+
+  But                     (a + b)a = aa + ba       by (6),
+                                   = aa + ab       by (5);
+
+  and                     (a + b)b = ab + bb       by (6).
+
+  Therefore     (a + b)^2 = aa + ab + (ab + bb) \
+                         = aa + (ab + ab) + bb   >  by (4).
+                         = aa + 2ab + bb        /
+
+  This gives the theorem in question.
+
+  In the same manner every one of the first ten propositions is proved.
+
+  It will be seen that the operations performed are exactly the same as
+  if the letters denoted numbers.
+
+  Props. 5 and 6 may also be written thus--
+
+    (a + b)(a - b) = a^2 - b^2.
+
+  Prop. 7, which is an easy consequence of Prop. 4, may be transformed.
+  If we denote by c the line a + b, so that
+
+    c = a + b, a = c - b,
+
+  we get
+
+    c^2 + (c - b)^2 = 2c(c - b) + b^2
+                    = 2c^2 - 2bc + b^2.
+
+  Subtracting c^2 from both sides, and writing a for c, we get
+
+    (a - b)^2 = a^2 - 2ab + b^2.
+
+  In Euclid's _Elements_ this form of the theorem does not appear, all
+  propositions being so stated that the notion of subtraction does not
+  enter into them.
+
+  S 24. The remaining two theorems (Props. 12 and 13) connect the square
+  on one side of a triangle with the sum of the squares on the other
+  sides, in case that the angle between the latter is acute or obtuse.
+  They are important theorems in trigonometry, where it is possible to
+  include them in a single theorem.
+
+  S 25. There are in the second book two problems, Props. 11 and 14.
+
+  If written in the above symbolic language, the former requires to find
+  a line x such that a(a - x) = x^2. Prop. 11 contains, therefore, the
+  solution of a quadratic equation, which we may write x^2 + ax = a^2.
+  The solution is required later on in the construction of a regular
+  decagon.
+
+  More important is the problem in the last proposition (Prop. 14). It
+  requires the construction of a square equal in area to a given
+  rectangle, hence a solution of the equation
+
+    x^2 = ab.
+
+  In Book I., 42-45, it has been shown how a rectangle may be
+  constructed equal in area to a given figure bounded by straight lines.
+  By aid of the new proposition we may therefore now determine a line
+  such that the square on that line is equal in area to any given
+  rectilinear figure, or we can _square_ any such figure.
+
+  As of two squares that is the greater which has the greater side, it
+  follows that now the comparison of two areas has been reduced to the
+  comparison of two lines.
+
+  The problem of reducing other areas to squares is frequently met with
+  among Greek mathematicians. We need only mention the problem of
+  squaring the circle (see CIRCLE).
+
+  In the present day the comparison of areas is performed in a simpler
+  way by reducing all areas to rectangles having a common base. Their
+  altitudes give then a measure of their areas.
+
+  The construction of a rectangle having the base u, and being equal in
+  area to a given rectangle, depends upon Prop. 43, I. This therefore
+  gives a solution of the equation
+
+    ab = ux,
+
+  where x denotes the unknown altitude.
+
+
+  BOOK III.
+
+  S 26. The third book of the _Elements_ relates exclusively to
+  properties of the circle. A circle and its circumference have been
+  defined in Book I., Def. 15. We restate it here in slightly different
+  words:--
+
+  _Definition_.--The circumference of a circle is a plane curve such
+  that all points in it have the same distance from a fixed point in the
+  plane. This point is called the "centre" of the circle.
+
+  Of the new definitions, of which eleven are given at the beginning of
+  the third book, a few only require special mention. The first, which
+  says that circles with equal radii are equal, is in part a theorem,
+  but easily proved by applying the one circle to the other. Or it may
+  be considered proved by aid of Prop. 24, equal circles not being used
+  till after this theorem.
+
+  In the second definition is explained what is meant by a line which
+  "touches" a circle. Such a line is now generally called a tangent to
+  the circle. The introduction of this name allows us to state many of
+  Euclid's propositions in a much shorter form.
+
+  For the same reason we shall call a straight line joining two points
+  on the circumference of a circle a "chord."
+
+  Definitions 4 and 5 may be replaced with a slight generalization by
+  the following:--
+
+  _Definition_.--By the distance of a point from a line is meant the
+  length of the perpendicular drawn from the point to the line.
+
+  S 27. From the definition of a circle it follows that every circle has
+  a centre. Prop. 1 requires to find it when the circle is given, i.e.
+  when its circumference is drawn.
+
+  To solve this problem a chord is drawn (that is, any two points in the
+  circumference are joined), and through the point where this is
+  bisected a perpendicular to it is erected. Euclid then proves, first,
+  that no point off this perpendicular can be the centre, hence that the
+  centre must lie in this line; and, secondly, that of the points on the
+  perpendicular one only can be the centre, viz. the one which bisects
+  the parts of the perpendicular bounded by the circle. In the second
+  part Euclid silently assumes that the perpendicular there used does
+  cut the circumference in two, and only in two points. The proof
+  therefore is incomplete. The proof of the first part, however, is
+  exact. By drawing two non-parallel chords, and the perpendiculars
+  which bisect them, the centre will be found as the point where these
+  perpendiculars intersect.
+
+  S 28. In Prop. 2 it is proved that a chord of a circle lies altogether
+  within the circle.
+
+  What we have called the first part of Euclid's solution of Prop. 1 may
+  be stated as a theorem:--
+
+  _Every straight line which bisects a chord, and is at right angles to
+  it, passes through the centre of the circle._
+
+  The converse to this gives Prop. 3, which may be stated thus:--
+
+  _If a straight line through the centre of a circle bisect a chord,
+  then it is perpendicular to the chord, and if it be perpendicular to
+  the chord it bisects it._
+
+  An easy consequence of this is the following theorem, which is
+  essentially the same as Prop. 4:--
+
+  _Two chords of a circle, of which neither passes through the centre,
+  cannot bisect each other._
+
+  These last three theorems are fundamental for the theory of the
+  circle. It is to be remarked that Euclid never proves that a straight
+  line cannot have more than two points in common with a circumference.
+
+  S 29. The next two propositions (5 and 6) might be replaced by a
+  single and a simpler theorem, viz:--
+
+  _Two circles which have a common centre, and whose circumferences have
+  one point in common, coincide._
+
+  Or, more in agreement with Euclid's form:--
+
+  _Two different circles, whose circumferences have a point in common,
+  cannot have the same centre._
+
+  That Euclid treats of two cases is characteristic of Greek
+  mathematics.
+
+  The next two propositions (7 and 8) again belong together. They may be
+  combined thus:--
+
+  _If from a point in a plane of a circle, which is not the centre,
+  straight lines be drawn to the different points of the circumference,
+  then of all these lines one is the shortest, and one the longest, and
+  these lie both in that straight line which joins the given point to
+  the centre. Of all the remaining lines each is equal to one and only
+  one other, and these equal lines lie on opposite sides of the shortest
+  or longest, and make equal angles with them._
+
+  Euclid distinguishes the two cases where the given point lies within
+  or without the circle, omitting the case where it lies in the
+  circumference.
+
+  From the last proposition it follows that if from a point more than
+  two equal straight lines can be drawn to the circumference, this point
+  must be the centre. This is Prop. 9.
+
+  As a consequence of this we get
+
+  _If the circumferences of the two circles have three points in common
+  they coincide._
+
+  For in this case the two circles have a common centre, because from
+  the centre of the one three equal lines can be drawn to points on the
+  circumference of the other. But two circles which have a common
+  centre, and whose circumferences have a point in common, coincide.
+  (Compare above statement of Props. 5 and 6.)
+
+  This theorem may also be stated thus:--
+
+  _Through three points only one circumference may be drawn; or, Three
+  points determine a circle._
+
+  Euclid does not give the theorem in this form. He proves, however,
+  _that the two circles cannot cut another in more than two points_
+  (Prop. 10), and _that two circles cannot touch one another in more
+  points than one_ (Prop. 13).
+
+  S 30. Propositions 11 and 12 assert that _if two circles touch, then
+  the point of contact lies on the line joining their centres_. This
+  gives two propositions, because the circles may touch either
+  internally or externally.
+
+  S 31. Propositions 14 and 15 relate to the length of chords. The first
+  says _that equal chords are equidistant from the centre, and that
+  chords which are equidistant from the centre are equal_;
+
+  Whilst Prop. 15 compares unequal chords, viz. _Of all chords the
+  diameter is the greatest, and of other chords that is the greater
+  which is nearer to the centre_; and conversely, _the greater chord is
+  nearer to the centre_.
+
+  S 32. In Prop. 16 the tangent to a circle is for the first time
+  introduced. The proposition is meant to show that the straight line at
+  the end point of the diameter and at right angles to it is a tangent.
+  The proposition itself does not state this. It runs thus:--
+
+  Prop. 16. _The straight line drawn at right angles to the diameter of
+  a circle, from the extremity of it, falls without the circle; and no
+  straight line can be drawn from the extremity, between that straight
+  line and the circumference, so as not to cut the circle._
+
+  _Corollary_.--The straight line at right angles to a diameter drawn
+  through the end point of it touches the circle.
+
+  The statement of the proposition and its whole treatment show the
+  difficulties which the tangents presented to Euclid.
+
+  Prop. 17 solves the problem _through a given point, either in the
+  circumference or without it, to draw a tangent to a given circle_.
+
+  Closely connected with Prop. 16 are Props. 18 and 19, which state
+  (Prop. 18), _that the line joining the centre of a circle to the point
+  of contact of a tangent is perpendicular to the tangent_; and
+  conversely (Prop. 19), _that the straight line through the point of
+  contact of, and perpendicular to, a tangent to a circle passes through
+  the centre of the circle_.
+
+  S 33. The rest of the book relates to angles connected with a circle,
+  viz. angles which have the vertex either at the centre or on the
+  circumference, and which are called respectively angles at the centre
+  and angles at the circumference. Between these two kinds of angles
+  exists the important relation expressed as follows:--
+
+  Prop. 20. _The angle at the centre of a circle is double of the angle
+  at the circumference on the same base, that is, on the same arc._
+
+  This is of great importance for its consequences, of which the two
+  following are the principal:--
+
+  Prop. 21. _The angles in the same segment of a circle are equal to one
+  another_;
+
+  Prop. 22. _The opposite angles of any quadrilateral figure inscribed
+  in a circle are together equal to two right angles._
+
+  Further consequences are:--
+
+  Prop. 23. _On the same straight line, and on the same side of it,
+  there cannot be two similar segments of circles, not coinciding with
+  one another_;
+
+  Prop. 24. _Similar segments of circles on equal straight lines are
+  equal to one another._
+
+  The problem Prop. 25. _A segment of a circle being given to describe
+  the circle of which it is a segment_, may be solved much more easily
+  by aid of the construction described in relation to Prop. 1, III., in
+  S 27.
+
+  S 34. There follow four theorems connecting the angles at the centre,
+  the arcs into which they divide the circumference, and the chords
+  subtending these arcs. They are expressed for angles, arcs and chords
+  in equal circles, but they hold also for angles, arcs and chords in
+  the same circle.
+
+  The theorems are:--
+
+  Prop. 26. _In equal circles equal angles stand on equal arcs, whether
+  they be at the centres or circumferences_;
+
+  Prop. 27. (converse to Prop. 26). _In equal circles the angles which
+  stand on equal arcs are equal to one another, whether they be at the
+  centres or the circumferences_;
+
+  Prop. 28. _In equal circles equal straight lines_ (equal chords) _cut
+  off equal arcs, the greater equal to the greater, and the less equal
+  to the less_;
+
+  Prop. 29 (converse to Prop. 28). _In equal circles equal arcs are
+  subtended by equal straight lines._
+
+  S 35. Other important consequences of Props. 20-22 are:--
+
+  Prop. 31. _In a circle the angle in a semicircle is a right angle; but
+  the angle in a segment greater than a semicircle is less than a right
+  angle; and the angle in a segment less than a semicircle is greater
+  than a right angle_;
+
+  Prop. 32. _If a straight line touch a circle, and from the point of
+  contact a straight line be drawn cutting the circle, the angles which
+  this line makes with the line touching the circle shall be equal to
+  the angles which are in the alternate segments of the circle._
+
+  S 36. Propositions 30, 33, 34, contain problems which are solved by
+  aid of the propositions preceding them:--
+
+  Prop. 30. _To bisect a given arc, that is, to divide it into two equal
+  parts_;
+
+  Prop. 33. _On a given straight line to describe a segment of a circle
+  containing an angle equal to a given rectilineal angle_;
+
+  Prop. 34. _From a given circle to cut off a segment containing an
+  angle equal to a given rectilineal angle_.
+
+  S 37. If we draw chords through a point A within a circle, they will
+  each be divided by A into two segments. Between these segments the law
+  holds that the rectangle contained by them has the same area on
+  whatever chord through A the segments are taken. The value of this
+  rectangle changes, of course, with the position of A.
+
+  A similar theorem holds if the point A be taken without the circle. On
+  every straight line through A, which cuts the circle in two points B
+  and C, we have two segments AB and AC, and the rectangles contained by
+  them are again equal to one another, and equal to the square on a
+  tangent drawn from A to the circle.
+
+  The first of these theorems gives Prop. 35, and the second Prop. 36,
+  with its corollary, whilst Prop. 37, the last of Book III., gives the
+  converse to Prop. 36. The first two theorems may be combined in one:--
+
+  _If through a point A in the plane of a circle a straight line be
+  drawn cutting the circle in B and C, then the rectangle AB.AC has a
+  constant value so long as the point A be fixed; and if from A a
+  tangent AD can be drawn to the circle, touching at D, then the above
+  rectangle equals the square on AD._
+
+  Prop. 37 may be stated thus:--
+
+  _If from a point A without a circle a line be drawn cutting the circle
+  in B and C, and another line to a point D on the circle, and AB.AC =
+  AD^2, then the line AD touches the circle at D._
+
+  It is not difficult to prove also the converse to the general
+  proposition as above stated. This proposition and its converse may be
+  expressed as follows:--
+
+  _If four points ABCD be taken on the circumference of a circle, and if
+  the lines AB, CD, produced if necessary, meet at E, then_
+
+    EA.EB = EC.ED;
+
+  _and conversely, if this relation holds then the four points lie on a
+  circle, that is, the circle drawn through three of them passes through
+  the fourth._
+
+  That a circle may always be drawn through three points, provided that
+  they do not lie in a straight line, is proved only later on in Book
+  IV.
+
+
+  BOOK IV.
+
+  S 38. The fourth book contains only problems, all relating to the
+  construction of triangles and polygons inscribed in and circumscribed
+  about circles, and of circles inscribed in or circumscribed about
+  triangles and polygons. They are nearly all given for their own sake,
+  and not for future use in the construction of figures, as are most of
+  those in the former books. In seven definitions at the beginning of
+  the book it is explained what is understood by figures inscribed in or
+  described about other figures, with special reference to the case
+  where one figure is a circle. Instead, however, of saying that one
+  figure is described about another, it is now generally said that the
+  one figure is circumscribed about the other. We may then state the
+  definitions 3 or 4 thus:--
+
+  _Definition._--A polygon is said to be inscribed in a circle, and the
+  circle is said to be circumscribed about the polygon, if the vertices
+  of the polygon lie in the circumference of the circle.
+
+  And definitions 5 and 6 thus:--
+
+  _Definition._--A polygon is said to be circumscribed about a circle,
+  and a circle is said to be inscribed in a polygon, if the sides of the
+  polygon are tangents to the circle.
+
+  S 39. The first problem is merely constructive. It requires to draw in
+  a given circle a chord equal to a given straight line, which is not
+  greater than the diameter of the circle. The problem is not a
+  determinate one, inasmuch as the chord may be drawn from any point in
+  the circumference. This may be said of almost all problems in this
+  book, especially of the next two. They are:--
+
+  Prop. 2. _In a given circle to inscribe a triangle equiangular to a
+  given triangle;_
+
+  Prop. 3. _About a given circle to circumscribe a triangle equiangular
+  to a given triangle._
+
+  S 40. Of somewhat greater interest are the next problems, where the
+  triangles are given and the circles to be found.
+
+  Prop. 4. _To inscribe a circle in a given triangle._
+
+  The result is that the problem has always a solution, viz. the centre
+  of the circle is the point where the bisectors of two of the interior
+  angles of the triangle meet. The solution shows, though Euclid does
+  not state this, that the problem has but one solution; and also,
+
+  _The three bisectors of the interior angles of any triangle meet in a
+  point, and this is the centre of the circle inscribed in the
+  triangle._
+
+  The solutions of most of the other problems contain also theorems. Of
+  these we shall state those which are of special interest; Euclid does
+  not state any one of them.
+
+  S 41. Prop. 5. _To circumscribe a circle about a given triangle._
+
+  The one solution which always exists contains the following:--
+
+  _The three straight lines which bisect the sides of a triangle at
+  right angles meet in a point, and this point is the centre of the
+  circle circumscribed about the triangle._
+
+  Euclid adds in a corollary the following property:--
+
+  The centre of the circle circumscribed about a triangle lies within,
+  on a side of, or without the triangle, according as the triangle is
+  acute-angled, right-angled or obtuse-angled.
+
+  S 42. Whilst it is always possible to draw a circle which is inscribed
+  in or circumscribed about a given triangle, this is not the case with
+  quadrilaterals or polygons of more sides. Of those for which this is
+  possible the regular polygons, i.e. polygons which have all their
+  sides and angles equal, are the most interesting. In each of them a
+  circle may be inscribed, and another may be circumscribed about it.
+
+  Euclid does not use the word regular, but he describes the polygons in
+  question as _equiangular_ and _equilateral_. We shall use the name
+  regular polygon. The regular triangle is equilateral, the regular
+  quadrilateral is the square.
+
+  Euclid considers the regular polygons of 4, 5, 6 and 15 sides. For
+  each of the first three he solves the problems--(1) to inscribe such a
+  polygon in a given circle; (2) to circumscribe it about a given
+  circle; (3) to inscribe a circle in, and (4) to circumscribe a circle
+  about, such a polygon.
+
+  For the regular triangle the problems are not repeated, because more
+  general problems have been solved.
+
+  Props. 6, 7, 8 and 9 solve these problems for the square.
+
+  The general problem of inscribing in a given circle a regular polygon
+  of n sides depends upon the problem of dividing the circumference of a
+  circle into n equal parts, or what comes to the same thing, of drawing
+  from the centre of the circle n radii such that the angles between
+  consecutive radii are equal, that is, to divide the space about the
+  centre into n equal angles. Thus, if it is required to inscribe a
+  square in a circle, we have to draw four lines from the centre, making
+  the four angles equal. This is done by drawing two diameters at right
+  angles to one another. The ends of these diameters are the vertices of
+  the required square. If, on the other hand, tangents be drawn at these
+  ends, we obtain a square circumscribed about the circle.
+
+  S 43. To construct a _regular pentagon_, we find it convenient first
+  to construct a _regular decagon_. This requires to divide the space
+  about the centre into ten equal angles. Each will be 1/10th of a right
+  angle, or 1/5th of two right angles. If we suppose the decagon
+  constructed, and if we join the centre to the end of one side, we get
+  an isosceles triangle, where the angle at the centre equals 1/5th of
+  two right angles; hence each of the angles at the base will be 2/5ths
+  of two right angles, as all three angles together equal two right
+  angles. Thus we have to construct an isosceles triangle, having the
+  angle at the vertex equal to half an angle at the base. This is solved
+  in Prop. 10, by aid of the problem in Prop. 11 of the second book. If
+  we make the sides of this triangle equal to the radius of the given
+  circle, then the base will be the side of the regular decagon
+  inscribed in the circle. This side being known the decagon can be
+  constructed, and if the vertices are joined alternately, leaving out
+  half their number, we obtain the regular pentagon. (Prop. 11.)
+
+  Euclid does not proceed thus. He wants the pentagon before the
+  decagon. This, however, does not change the real nature of his
+  solution, nor does his solution become simpler by not mentioning the
+  decagon.
+
+  Once the regular pentagon is inscribed, it is easy to circumscribe
+  another by drawing tangents at the vertices of the inscribed pentagon.
+  This is shown in Prop. 12.
+
+  Props. 13 and 14 teach how a circle may be inscribed in or
+  circumscribed about any given regular pentagon.
+
+  S 44. The _regular hexagon_ is more easily constructed, as shown in
+  Prop. 15. The result is that the side of the regular hexagon inscribed
+  in a circle is equal to the radius of the circle.
+
+  For this polygon the other three problems mentioned are not solved.
+
+  S 45. The book closes with Prop. 16. To inscribe a regular quindecagon
+  in a given circle. If we inscribe a regular pentagon and a regular
+  hexagon in the circle, having one vertex in common, then the arc from
+  the common vertex to the next vertex of the pentagon is 1/5th of the
+  circumference, and to the next vertex of the hexagon is 1/6th of the
+  circumference. The difference between these arcs is, therefore, 1/5 -
+  1/6 = 1/30th of the circumference. The latter may, therefore, be
+  divided into thirty, and hence also in fifteen equal parts, and the
+  regular quindecagon be described.
+
+  S 46. We conclude with a few theorems about regular polygons which are
+  not given by Euclid.
+
+  _The straight lines perpendicular to and bisecting the sides of any
+  regular polygon meet in a point. The straight lines bisecting the
+  angles in the regular polygon meet in the same point. This point is
+  the centre of the circles circumscribed about and inscribed in the
+  regular polygon._
+
+  We can bisect any given arc (Prop. 30, III.). Hence we can divide a
+  circumference into 2n equal parts as soon as it has been divided into
+  n equal parts, or as soon as a regular polygon of n sides has been
+  constructed. Hence--
+
+  _If a regular polygon of n sides has been constructed, then a regular
+  polygon of 2n sides, of 4n, of 8n sides, &c., may also be
+  constructed._ Euclid shows how to construct regular polygons of 3, 4,
+  5 and 15 sides. It follows that we can construct regular polygons of
+
+     3,  6, 12,  24  sides
+     4,  8, 16,  32    "
+     5, 10, 20,  40    "
+    15, 30, 60, 120    "
+
+  The construction of any new regular polygon not included in one of
+  these series will give rise to a new series. Till the beginning of the
+  19th century nothing was added to the knowledge of regular polygons as
+  given by Euclid. Then Gauss, in his celebrated _Arithmetic_, proved
+  that every regular polygon of 2^n + 1 sides may be constructed if this
+  number 2^n + 1 be prime, and that no others except those with 2^m(2^n
+  + 1) sides can be constructed by elementary methods. This shows that
+  regular polygons of 7, 9, 13 sides cannot thus be constructed, but
+  that a regular polygon of 17 sides is possible; for 17 = 2^4 + 1. The
+  next polygon is one of 257 sides. The construction becomes already
+  rather complicated for 17 sides.
+
+
+  BOOK V.
+
+  S 47. The fifth book of the _Elements_ is not exclusively geometrical.
+  It contains the theory of ratios and proportion of quantities in
+  general. The treatment, as here given, is admirable, and in every
+  respect superior to the algebraical method by which Euclid's theory is
+  now generally replaced. We shall treat the subject in order to show
+  why the usual algebraical treatment of proportion is not really sound.
+  We begin by quoting those definitions at the beginning of Book V.
+  which are most important. These definitions have given rise to much
+  discussion.
+
+  The only definitions which are essential for the fifth book are Defs.
+  1, 2, 4, 5, 6 and 7. Of the remainder 3, 8 and 9 are more than
+  useless, and probably not Euclid's, but additions of later editors, of
+  whom Theon of Alexandria was the most prominent. Defs. 10 and 11
+  belong rather to the sixth book, whilst all the others are merely
+  nominal. The really important ones are 4, 5, 6 and 7.
+
+  S 48. To define a magnitude is not attempted by Euclid. The first two
+  definitions state what is meant by a "part," that is, a submultiple or
+  measure, and by a "multiple" of a given magnitude. The meaning of Def.
+  4 is that two given quantities can have a ratio to one another only in
+  case that they are comparable as to their magnitude, that is, if they
+  are of the same kind.
+
+  Def. 3, which is probably due to Theon, professes to define a ratio,
+  but is as meaningless as it is uncalled for, for all that is wanted is
+  given in Defs. 5 and 7.
+
+  In Def. 5 it is explained what is meant by saying that two magnitudes
+  have the same ratio to one another as two other magnitudes, and in
+  Def. 7 what we have to understand by a greater or a less ratio. The
+  6th definition is only nominal, explaining the meaning of the word
+  _proportional_.
+
+  Euclid represents magnitudes by lines, and often denotes them either
+  by single letters or, like lines, by two letters. We shall use only
+  single letters for the purpose. If a and b denote two magnitudes of
+  the same kind, their ratio will be denoted by a : b; if c and d are
+  two other magnitudes of the same kind, but possibly of a different
+  kind from a and b, then if c and d have the same ratio to one another
+  as a and b, this will be expressed by writing--
+
+    a : b :: c : d.
+
+  Further, if m is a (whole) number, ma shall denote the multiple of a
+  which is obtained by taking it m times.
+
+  S 49. The whole theory of ratios is based on Def. 5.
+
+  Def. 5. _The first of four magnitudes is said to have the same ratio
+  to the second that the third has to the fourth when, any equimultiples
+  whatever of the first and the third being taken, and any equimultiples
+  whatever of the second and the fourth, if the multiple of the first be
+  less than that of the second, the multiple of the third is also less
+  than that of the fourth; and if the multiple of the first is equal to
+  that of the second, the multiple of the third is also equal to that of
+  the fourth; and if the multiple of the first is greater than that of
+  the second, the multiple of the third is also greater than that of the
+  fourth._
+
+  It will be well to show at once in an example how this definition can
+  be used, by proving the first part of the first proposition in the
+  sixth book. _Triangles of the same altitude are to one another as
+  their bases_, or if a and b are the bases, and [alpha] and [beta] the
+  areas, of two triangles which have the same altitude, then a : b ::
+  [alpha] : [beta].
+
+  To prove this, we have, according to Definition 5, to show--
+
+    if ma > nb, then m[alpha] > n[beta],
+    if ma = nb, then m[alpha] = n[beta],
+    if ma < nb, then m[alpha] < n[beta].
+
+  That this is true is in our case easily seen. We may suppose that the
+  triangles have a common vertex, and their bases in the same line. We
+  set off the base a along the line containing the bases m times; we
+  then join the different parts of division to the vertex, and get m
+  triangles all equal to [alpha]. The triangle on ma as base equals,
+  therefore, m[alpha]. If we proceed in the same manner with the base b,
+  setting it off n times, we find that the area of the triangle on the
+  base nb equals n[beta], the vertex of all triangles being the same.
+  But if two triangles have the same altitude, then their areas are
+  equal if the bases are equal; hence m[alpha] = n[beta] if ma = nb, and
+  if their bases are unequal, then that has the greater area which is on
+  the greater base; in other words, m[alpha] is greater than, equal to,
+  or less than n[beta], according as ma is greater than, equal to, or
+  less than nb, which was to be proved.
+
+  S 50. It will be seen that even in this example it does not become
+  evident what a ratio really is. It is still an open question whether
+  ratios are magnitudes which we can compare. We do not know whether the
+  ratio of two lines is a magnitude of the same kind as the ratio of two
+  areas. Though we might say that Def. 5 defines _equal _ratios, still
+  we do not know whether they are equal in the sense of the axiom, that
+  two things which are equal to a third are equal to one another. That
+  this is the case requires a proof, and until this proof is given we
+  shall use the :: instead of the sign = , which, however, we shall
+  afterwards introduce.
+
+  As soon as it has been established that all ratios are like
+  magnitudes, it becomes easy to show that, in some cases at least, they
+  are numbers. This step was never made by Greek mathematicians. They
+  distinguished always most carefully between continuous magnitudes and
+  the discrete series of numbers. In modern times it has become the
+  custom to ignore this difference.
+
+  If, in determining the ratio of two lines, a common measure can be
+  found, which is contained m times in the first, and n times in the
+  second, then the ratio of the two lines equals the ratio of the two
+  numbers m : n. This is shown by Euclid in Prop. 5, X. But the ratio of
+  two numbers is, as a rule, a fraction, and the Greeks did not, as we
+  do, consider fractions as numbers. Far less had they any notion of
+  introducing irrational numbers, which are neither whole nor
+  fractional, as we are obliged to do if we wish to say that all ratios
+  are numbers. The incommensurable numbers which are thus introduced as
+  ratios of incommensurable quantities are nowadays as familiar to us as
+  fractions; but a proof is generally omitted that we may apply to them
+  the rules which have been established for rational numbers only.
+  Euclid's treatment of ratios avoids this difficulty. His definitions
+  hold for commensurable as well as for incommensurable quantities. Even
+  the notion of incommensurable quantities is avoided in Book V. But he
+  proves that the more elementary rules of algebra hold for ratios. We
+  shall state all his propositions in that algebraical form to which we
+  are now accustomed. This may, of course, be done without changing the
+  character of Euclid's method.
+
+  S. 51. Using the notation explained above we express the first
+  propositions as follows:--
+
+  Prop. 1. If   a = ma', b = mb', c = mc',
+  then          a + b + c = m(a' + b' + c').
+
+  Prop. 2. If   a = mb, and c = md,
+                e = nb, and f = nd,
+
+  then a + e is the same multiple of b as c + f is of d, viz.:--
+
+    a + e = (m + n)b, and c + f = (m + n)d.
+
+  Prop. 3. If a = mb, c = md, then is na the same multiple of b that nc
+  is of d, viz. na = nmb, nc = nmd.
+
+  Prop. 4. If   a : b :: c : d,
+  then          ma : nb :: mc : nd.
+
+  Prop. 5. If   a = mb, and c = md,
+  then          a - c = m(b - d).
+
+  Prop. 6. If   a = mb, c = md,
+
+  then are a - nb and c - nd either equal to, or equimultiples of, b and
+  d, viz. a - nb = (m - n)b and c - nd = (m - n)d, where m - n may be
+  unity.
+
+  All these propositions relate to _equimultiples_. Now follow
+  propositions about ratios which are compared as to their magnitude.
+
+  S 52. Prop. 7. If a = b, then a : c :: b : c and c : a :: c : b.
+
+  The proof is simply this. As a = b we know that ma = mb; therefore
+
+    if   ma > nc, then mb > nc,
+    if   ma = nc, then mb = nc,
+    if   ma < nc, then mb < nc,
+
+  therefore the first proportion holds by Definition 5.
+
+  Prop. 8. If a > b, then a : c > b : c,
+  and                     c : a < c : b.
+
+  The proof depends on Definition 7.
+
+  Prop. 9 (converse to Prop. 7). If
+             a : c :: b : c,
+  or if      c : a :: c : b, then a = b.
+
+  Prop. 10 (converse to Prop. 8). If
+             a : c > b : c, then a > b,
+  and if     c : a < c : b, then a < b.
+
+  Prop. 11. If  a : b :: c : d,
+  and           a : b :: e : f,
+  then          c : d :: e : f.
+
+  In words, _if too ratios are equal to a third, they are equal to one
+  another_. After these propositions have been proved, we have a right
+  to consider a ratio as a _magnitude_, for only now can we consider a
+  ratio as something for which the axiom about magnitudes holds: things
+  which are equal to a third are equal to one another.
+
+  We shall indicate this by writing in future the sign = instead of ::.
+  The remaining propositions, which explain themselves, may then be
+  stated as follows:
+
+  S 53. Prop. 12. If  a : b = c : d = e : f,
+  then                a + c + e : b + d + f = a : b.
+
+  Prop. 13. If    a : b = c : d and c : d > e : f,
+  then            a : b > e : f.
+
+  Prop. 14. If    a : b = c : d, and a > c, then b > d.
+
+  Prop. 15. Magnitudes have the same ratio to one another that their
+  equimultiples have--
+
+  ma : mb = a : b.
+
+  Prop. 16. If a, b, c, d are magnitudes of the same kind, and if
+                  a : b = c : d,
+  then            a : c = b : d.
+
+  Prop. 17. If    a + b : b = c + d : d,
+  then            a : b = c : d.
+
+  Prop. 18 (converse to 17). If
+                  a : b = c : d
+  then            a + b : b = c + d : d.
+
+  Prop. 19. If a, b, c, d are quantities of the same kind, and if
+                  a : b = c : d,
+  then            a - c : b - d = a : b.
+
+  S 54. Prop. 20. _If there be three magnitudes, and another three,
+  which have the same ratio, taken two and two, then if the first be
+  greater than the third, the fourth shall be greater than the sixth:
+  and if equal, equal; and if less, less._
+
+  If we understand by
+
+    a : b : c : d : e : ... = a' : b' : c' : d' : e' : ...
+
+  that the ratio of any two consecutive magnitudes on the first side
+  equals that of the corresponding magnitudes on the second side, we may
+  write this theorem in symbols, thus:--
+
+  If a, b, c be quantities of one, and d, e, f magnitudes of the same or
+  any other kind, such that
+
+           a : b : c = d : e : f,
+  and if   a > c, then d > f,
+  but if   a = c, then d = f,
+  and if   a < c, then d < f.
+
+  Prop. 21. If  a : b = e : f and b : c = d : e,
+  or if         a : b : c = 1/f : 1/e : 1/d,
+  and if        a > c, then d > f,
+  but if        a = c, then d = f,
+  and if        a < c, then d < f.
+
+  By aid of these two propositions the following two are proved.
+
+  S 55. Prop. 22. _If there be any number of magnitudes, and as many
+  others, which have the same ratio, taken two and two in order, the
+  first shall have to the last of the first magnitudes the same ratio
+  which the first of the others has to the last._
+
+  We may state it more generally, thus:
+
+  If   a : b : c : d : e: ... = a' : b' : c' : d' : e' : ... ,
+
+  then not only have two consecutive, but any two magnitudes on the
+  first side, the same ratio as the corresponding magnitudes on the
+  other. For instance--
+
+    a : c = a' : c'; b : e = b' : e', &c.
+
+  Prop. 23 we state only in symbols, viz.:--
+
+  If  a : b : c : d : e : ... = 1/a' : 1/b' : 1/c' : 1/d' : 1/e' ...,
+
+  then  a : c = c' : a',
+        b : e = e' : b',
+
+  and so on.
+
+  Prop. 24 comes to this: If a : b = c : d and e : b = f : d, then
+
+    a + e : b = c + f : d.
+
+  Some of the proportions which are considered in the above propositions
+  have special names. These we have omitted, as being of no use, since
+  algebra has enabled us to bring the different operations contained in
+  the propositions under a common point of view.
+
+  S 56. The last proposition in the fifth book is of a different
+  character.
+
+  Prop. 25. _If four magnitudes of the same kind be proportional, the
+  greatest and least of them together shall be greater than the other
+  two together._ In symbols--
+
+  If a, b, c, d be magnitudes of the same kind, and if a : b = c : d,
+  and if a is the greatest, hence d the least, then a + d > b + c.
+
+  S 57. We return once again to the question. What is a ratio? We have
+  seen that we may treat ratios as magnitudes, and that all ratios are
+  magnitudes of the same kind, for we may compare any two as to their
+  magnitude. It will presently be shown that ratios of lines may be
+  considered as _quotients_ of lines, so that a ratio appears as answer
+  to the question, How often is one line contained in another? But the
+  answer to this question is given by a number, at least in some cases,
+  and in all cases if we admit incommensurable numbers. Considered from
+  this point of view, we may say the fifth book of the _Elements_ shows
+  that some of the simpler algebraical operations hold for
+  incommensurable numbers. In the ordinary algebraical treatment of
+  numbers this proof is altogether omitted, or given by a process of
+  limits which does not seem to be natural to the subject.
+
+
+  BOOK VI.
+
+  S 58. The sixth book contains the theory of similar figures. After a
+  few definitions explaining terms, the first proposition gives the
+  first application of the theory of proportion.
+
+  Prop. 1. _Triangles and parallelograms of the same altitude are to one
+  another as their bases._
+
+  The proof has already been considered in S 49.
+
+  From this follows easily the important theorem
+
+  Prop. 2. _If a straight line be drawn parallel to one of the sides of
+  a triangle it shall cut the other sides, or those sides produced,
+  proportionally; and if the sides or the sides produced be cut
+  proportionally, the straight line which joins the points of section
+  shall be parallel to the remaining side of the triangle._
+
+  S 59. The next proposition, together with one added by Simson as Prop.
+  A, may be expressed more conveniently if we introduce a modern
+  phraseology, viz. if in a line AB we assume a point C between A and B,
+  we shall say that C divides AB internally in the ratio AC : CB; but if
+  C be taken in the line AB produced, we shall say that AB is divided
+  externally in the ratio AC : CB.
+
+  The two propositions then come to this:
+
+  Prop. 3. _The bisector of an angle in a triangle divides the opposite
+  side internally in a ratio equal to the ratio of the two sides
+  including that angle;_ and conversely, _if a line through the vertex
+  of a triangle divide the base internally in the ratio of the two other
+  sides, then that line bisects the angle at the vertex_.
+
+  Simson's Prop. A. _The line which bisects an exterior angle of a
+  triangle divides the opposite side externally in the ratio of the
+  other sides;_ and conversely, _if a line through the vertex of a
+  triangle divide the base externally in the ratio of the sides, then it
+  bisects an exterior angle at the vertex of the triangle_.
+
+  If we combine both we have--
+
+  _The two lines which bisect the interior and exterior angles at one
+  vertex of a triangle divide the opposite side internally and
+  externally in the same ratio, viz. in the ratio of the other two
+  sides._
+
+  S 60. The next four propositions contain the theory of similar
+  triangles, of which four cases are considered. They may be stated
+  together.
+
+  _Two triangles are similar_,--
+
+  1. (Prop. 4). _If the triangles are equiangular:_
+
+  2. (Prop. 5). _If the sides of the one are proportional to those of
+  the other_;
+
+  3. (Prop. 6). _If two sides in one are proportional to two sides in
+  the other, and if the angles contained by these sides are equal_;
+
+  4. (Prop. 7). _If two sides in one are proportional to two sides in
+  the other, if the angles opposite homologous sides are equal, and if
+  the angles opposite the other homologous sides are both acute, both
+  right or both obtuse; homologous sides being in each case those which
+  are opposite equal angles_.
+
+  An important application of these theorems is at once made to a
+  right-angled triangle, viz.:--
+
+  Prop. 8. _In a right-angled triangle, if a perpendicular be drawn from
+  the right angle to the base, the triangles on each side of it are
+  similar to the whole triangle, and to one another_.
+
+  _Corollary._--From this it is manifest that the perpendicular drawn
+  from the right angle of a right-angled triangle to the base is a mean
+  proportional between the segments of the base, and also that each of
+  the sides is a mean proportional between the base and the segment of
+  the base adjacent to that side.
+
+  S 61. There follow four propositions containing problems, in language
+  slightly different from Euclid's, viz.:--
+
+  Prop. 9. _To divide a straight line into a given number of equal
+  parts_.
+
+  Prop. 10. _To divide a straight line in a given ratio_.
+
+  Prop. 11. _To find a third proportional to two given straight lines_.
+
+  Prop. 12. _To find a fourth proportional to three given straight
+  lines_.
+
+  Prop. 13. _To find a mean proportional between two given straight
+  lines_.
+
+  The last three may be written as equations with one unknown
+  quantity--viz. if we call the given straight lines a, b, c, and the
+  required line x, we have to find a line x so that
+
+  Prop. 11.  a : b = b : x;
+
+  Prop. 12.  a : b = c : x;
+
+  Prop. 13.  a : x = x : b.
+
+  We shall see presently how these may be written without the signs of
+  ratios.
+
+  S 62. Euclid considers next proportions connected with parallelograms
+  and triangles which are equal in area.
+
+  Prop. 14. _Equal parallelograms which have one angle of the one equal
+  to one angle of the other have their sides about the equal angles
+  reciprocally proportional; and parallelograms which have one angle of
+  the one equal to one angle of the other, and their sides about the
+  equal angles reciprocally proportional, are equal to one another_.
+
+  Prop. 15. _Equal triangles which have one angle of the one equal to
+  one angle of the other, have their sides about the equal angles
+  reciprocally proportional; and triangles which have one angle of the
+  one equal to one angle of the other, and their sides about the equal
+  angles reciprocally proportional, are equal to one another_.
+
+  [Illustration]
+
+  The latter proposition is really the same as the former, for if, as in
+  the accompanying diagram, in the figure belonging to the former the
+  two equal parallelograms AB and BC be bisected by the lines DF and EG,
+  and if EF be drawn, we get the figure belonging to the latter.
+
+  It is worth noticing that the lines FE and DG are parallel. We may
+  state therefore the theorem--
+
+  _If two triangles are equal in area, and have one angle in the one
+  vertically opposite to one angle in the other, then the two straight
+  lines which join the remaining two vertices of the one to those of the
+  other triangle are parallel_.
+
+  S 63. A most important theorem is
+
+  _Prop. 16. If four straight lines be proportionals, the rectangle
+  contained by the extremes is equal to the rectangle contained by the
+  means; and if the rectangle contained by the extremes be equal to the
+  rectangle contained by the means, the four straight lines are
+  proportionals_.
+
+  In symbols, if a, b, c, d are the four lines, and
+  if                  a : b = c : d,
+  then                ad = bc;
+  and conversely, if  ad = bc,
+  then                a : b = c : d,
+
+  where ad and bc denote (as in S 20), the areas of the rectangles
+  contained by a and d and by b and c respectively.
+
+  This allows us to transform every proportion between four lines into
+  an equation between two products.
+
+  It shows further that the operation of forming a product of two lines,
+  and the operation of forming their ratio are each the inverse of the
+  other.
+
+  If we now define a quotient a/b of two lines as the _number_ which
+  multiplied into b gives a, so that
+
+    a
+    -- b = a,
+    b
+
+  we see that from the equality of two quotients
+
+    a    c
+    -- = --
+    b    d
+
+  follows, if we multiply both sides by bd,
+
+    a        c
+    -- b.d = -- d.b,
+    b        d
+
+    ad = cb.
+
+  But from this it follows, according to the last theorem, that
+
+    a : b = c : d.
+
+  Hence we conclude that the quotient a/b and the ratio a : b are
+  different forms of the same magnitude, only with this important
+  difference that the quotient a/b would have a meaning only if a and b
+  have a common measure, until we introduce incommensurable numbers,
+  while the ratio a : b has always a meaning, and thus gives rise to the
+  introduction of incommensurable numbers.
+
+  Thus it is really the theory of ratios in the fifth book which enables
+  us to extend the geometrical calculus given before in connexion with
+  Book II. It will also be seen that if we write the ratios in Book V.
+  as quotients, or rather as fractions, then most of the theorems state
+  properties of quotients or of fractions.
+
+  S 64. Prop. 17. _If three straight lines are proportional the
+  rectangle contained by the extremes is equal to the square on the
+  mean;_ and conversely, is only a special case of 16. After the
+  problem, Prop. 18, _On a given straight line to describe a rectilineal
+  figure similar and similarly situated to a given rectilineal figure_,
+  there follows another fundamental theorem:
+
+  Prop. 19. _Similar triangles are to one another in the duplicate ratio
+  of their homologous sides._ In other words, the areas of similar
+  triangles are to one another as the squares on homologous sides. This
+  is generalized in:
+
+  Prop. 20. _Similar polygons may be divided into the same number of
+  similar triangles, having the same ratio to one another that the
+  polygons have; and the polygons are to one another in the duplicate
+  ratio of their homologous sides._
+
+  S 65. Prop. 21. _Rectilineal figures which are similar to the same
+  rectilineal figure are also similar to each other_, is an immediate
+  consequence of the definition of similar figures. As similar figures
+  may be said to be equal in "shape" but not in "size," we may state it
+  also thus:
+
+  "Figures which are equal in shape to a third are equal in shape to
+  each other."
+
+  Prop. 22. _If four straight lines be proportionals, the similar
+  rectilineal figures similarly described on them shall also be
+  proportionals; and if the similar rectilineal figures similarly
+  described on four straight lines be proportionals, those straight
+  lines shall be proportionals._
+
+  This is essentially the same as the following:--
+
+  _If_    a : b = c : d,
+  _then_  a^2 : b^2 = c^2 : d^2.
+
+  S 66. Now follows a proposition which has been much discussed with
+  regard to Euclid's exact meaning in saying that a ratio is
+  _compounded_ of two other ratios, viz.:
+
+  Prop. 23. _Parallelograms which are equiangular to one another, have
+  to one another the ratio which is compounded of the ratios of their
+  sides._
+
+  The proof of the proposition makes its meaning clear. In symbols the
+  ratio a : c is compounded of the two ratios a : b and b : c, and if a
+  : b = a' : b', b : c = b" : c", then a : c is compounded of a' : b'
+  and b" : c".
+
+  If we consider the ratios as numbers, we may say that the one ratio is
+  the product of those of which it is compounded, or in symbols,
+
+    a    a    b    a'   b"     a    a'     b    b"
+    -- = -- . -- = -- . --, if -- = -- and -- = --.
+    c    b    c    b'   c"     b    b'     c    c"
+
+  The theorem in Prop. 23 is the foundation of all mensuration of areas.
+  From it we see at once that two rectangles have the ratio of their
+  areas compounded of the ratios of their sides.
+
+  If A is the area of a rectangle contained by a and b, and B that of a
+  rectangle contained by c and d, so that A = ab, B = cd, then A : B =
+  ab : cd, and this is, the theorem says, compounded of the ratios a : c
+  and b : d. In forms of quotients,
+
+    a    b    ab
+    -- . -- = --.
+    c    d    cd
+
+  This shows how to multiply quotients in our geometrical calculus.
+
+  Further, _Two triangles have the ratios of their areas compounded of
+  the ratios of their bases and their altitude._ For a triangle is equal
+  in area to half a parallelogram which has the same base and the same
+  altitude.
+
+  S 67. To bring these theorems to the form in which they are usually
+  given, we assume a straight line u as our unit of length (generally an
+  inch, a foot, a mile, &c.), and determine the number [alpha] which
+  expresses how often u is contained in a line a, so that [alpha]
+  denotes the ratio a : u whether commensurable or not, and that a =
+  [alpha]u. We call this number [alpha] the numerical value of a. If in
+  the same manner [beta] be the numerical value of a line b we have
+
+    a : b = [alpha] : [beta];
+
+  in words: _The ratio of two lines (and of two like quantities in
+  general) is equal to that of their numerical values._
+
+  This is easily proved by observing that a = [alpha]u, b = [beta]u,
+  therefore a : b = [alpha]u : [beta]u, and this may without difficulty
+  be shown to equal [alpha] : [beta].
+
+  If now a, b be base and altitude of one, a', b' those of another
+  parallelogram, [alpha], [beta] and [alpha]', [beta]' their numerical
+  values respectively, and A, A' their areas, then
+
+    A    a    b    [alpha]    [beta]    [alpha][beta]
+    -- = -- . -- = -------- . ------ = ---------------.
+    A'   a'   b'   [alpha]'   [beta]'  [alpha]'[beta]'
+
+  In words: _The areas of two parallelograms are to each other as the
+  products of the numerical values of their bases and altitudes._
+
+  If especially the second parallelogram is the unit square, i.e. a
+  square on the unit of length, then [alpha]' = [beta]' = 1, A' = u^2,
+  and we have
+
+    A
+    -- = [alpha][beta] or A = [alpha][beta] . u^2.
+    A'
+
+  This gives the theorem: The number of unit squares contained in a
+  parallelogram equals the product of the numerical values of base and
+  altitude, and similarly the number of unit squares contained in a
+  triangle equals half the product of the numerical values of base and
+  altitude.
+
+  This is often stated by saying that the area of a parallelogram is
+  equal to the product of the base and the altitude, meaning by this
+  product the product of the numerical values, and not the product as
+  defined above in S 20.
+
+  S 68. Propositions 24 and 26 relate to parallelograms about diagonals,
+  such as are considered in Book I., 43. They are--
+
+  Prop. 24. _Parallelograms about the diameter of any parallelogram are
+  similar to the whole parallelogram and to one another_; and its
+  converse (Prop. 26), _If two similar parallelograms have a common
+  angle, and be similarly situated, they are about the same diameter._
+
+  Between these is inserted a problem.
+
+  Prop. 25. _To describe a rectilineal figure which shall be similar to
+  one given rectilinear figure, and equal to another given rectilineal
+  figure_.
+
+  S 69. Prop. 27 contains a theorem relating to the theory of maxima and
+  minima. We may state it thus:
+
+  Prop. 27. _If a parallelogram be divided into two by a straight line
+  cutting the base, and if on half the base another parallelogram be
+  constructed similar to one of those parts, then this third
+  parallelogram is greater than the other part._
+
+  Of far greater interest than this general theorem is a special case of
+  it, where the parallelograms are changed into rectangles, and where
+  one of the parts into which the parallelogram is divided is made a
+  square; for then the theorem changes into one which is easily
+  recognized to be identical with the following:--
+
+  _Of all rectangles which have the same perimeter the square has the
+  greatest area._
+
+  This may also be stated thus:--
+
+  _Of all rectangles which have the same area the square has the least
+  perimeter._
+
+  S 70. The next three propositions contain problems which may be said
+  to be solutions of quadratic equations. The first two are, like the
+  last, involved in somewhat obscure language. We transcribe them as
+  follows:
+
+  _Problem_.--To describe on a given base a parallelogram, and to divide
+  it either internally (Prop. 28) or externally (Prop. 29) from a point
+  on the base into two parallelograms, of which the one has a given size
+  (is equal in area to a given figure), whilst the other has a given
+  shape (is similar to a given parallelogram).
+
+  If we express this again in symbols, calling the given base a, the one
+  part x, and the altitude y, we have to determine x and y in the first
+  case from the equations
+
+    (a - x)y = k^2,
+
+    x    p
+    -- = --,
+    y    q
+
+  k^2 being the given size of the first, and p and q the base and
+  altitude of the parallelogram which determine the shape of the second
+  of the required parallelograms.
+
+  If we substitute the value of y, we get
+
+               pk^2
+    (a - x)x = ----,
+                q
+
+  or,
+
+    ax - x^2 = b^2,
+
+  where a and b are known quantities, taking b^2 = pk^2/q.
+
+  The second case (Prop. 29) gives rise, in the same manner, to the
+  quadratic
+
+    ax + x^2 = b^2.
+
+  The next problem--
+
+  Prop. 30. _To cut a given straight line in extreme and mean ratio_,
+  leads to the equation
+
+    ax + x^2 = a^2.
+
+  This is, therefore, only a special case of the last, and is, besides,
+  an old acquaintance, being essentially the same problem as that
+  proposed in II. 11.
+
+  Prop. 30 may therefore be solved in two ways, either by aid of Prop.
+  29 or by aid of II. 11. Euclid gives both solutions.
+
+  S 71. Prop. 31 (Theorem). _In any right-angled triangle, any
+  rectilineal figure described on the side subtending the right angle is
+  equal to the similar and similarly-described figures on the sides
+  containing the right angle_,--is a pretty generalization of the
+  theorem of Pythagoras (I. 47).
+
+  Leaving out the next proposition, which is of little interest, we come
+  to the last in this book.
+
+  Prop. 33. _In equal circles angles, whether at the centres or the
+  circumferences, have the same ratio which the arcs on which they stand
+  have to one another; so also have the sectors_.
+
+  Of this, the part relating to angles at the centre is of special
+  importance; it enables us to measure angles by arcs.
+
+  With this closes that part of the _Elements_ which is devoted to the
+  study of figures in a plane.
+
+
+  BOOK XI.
+
+  S 72. In this book figures are considered which are not confined to a
+  plane, viz. first relations between lines and planes in space, and
+  afterwards properties of solids.
+
+  Of new definitions we mention those which relate to the
+  perpendicularity and the inclination of lines and planes.
+
+  Def. 3. _A straight line is perpendicular, or at right angles, to a
+  plane when it makes right angles with every straight line meeting it
+  in that plane_.
+
+  The definition of perpendicular planes (Def. 4) offers no difficulty.
+  Euclid defines the inclination of lines to planes and of planes to
+  planes (Defs. 5 and 6) by aid of plane angles, included by straight
+  lines, with which we have been made familiar in the first books.
+
+  The other important definitions are those of parallel planes, which
+  never meet (Def. 8), and of solid angles formed by three or more
+  planes meeting in a point (Def. 9).
+
+  To these we add the definition of a line parallel to a plane as a line
+  which does not meet the plane.
+
+  S 73. Before we investigate the contents of Book XI., it will be well
+  to recapitulate shortly what we know of planes and lines from the
+  definitions and axioms of the first book. There a plane has been
+  defined as a surface which has the property that every straight line
+  which joins two points in it lies altogether in it. This is equivalent
+  to saying that a straight line which has two points in a plane has all
+  points in the plane. Hence, a straight line which does not lie in the
+  plane cannot have more than one point in common with the plane. This
+  is virtually the same as Euclid's Prop. 1, viz.:--
+
+  Prop. 1. _One part of a straight line cannot be in a plane and another
+  part without it_.
+
+  It also follows, as was pointed out in S 3, in discussing the
+  definitions of Book I., that a plane is determined already by one
+  straight line and a point without it, viz. if all lines be drawn
+  through the point, and cutting the line, they will form a plane.
+
+  This may be stated thus:--
+
+  _A plane is determined_--
+
+  1st, _By a straight line and a point which does not lie on it;_
+
+  2nd, _By three points which do not lie in a straight line_; for if two
+  of these points be joined by a straight line we have case 1;
+
+  3rd, _By two intersecting straight lines_; for the point of
+  intersection and two other points, one in each line, give case 2;
+
+  4th, _By two parallel lines_ (Def. 35, I.).
+
+  The third case of this theorem is Euclid's
+
+  Prop. 2. _Two straight lines which cut one another are in one plane,
+  and three straight lines which meet one another are in one plane_.
+
+  And the fourth is Euclid's
+
+  Prop. 7. _If two straight lines be parallel, the straight line drawn
+  from any point in one to any point in the other is in the same plane
+  with the parallels_. From the definition of a plane further follows
+
+  Prop. 3. _If two planes cut one another, their common section is a
+  straight line_.
+
+  S 74. Whilst these propositions are virtually contained in the
+  definition of a plane, the next gives us a new and fundamental
+  property of space, showing at the same time that it is possible to
+  have a straight line perpendicular to a plane, according to Def. 3. It
+  states--
+
+  Prop. 4. _If a straight line is perpendicular to two straight lines in
+  a plane which it meets, then it is perpendicular to all lines in the
+  plane which it meets, and hence it is perpendicular to the plane_.
+
+  Def. 3 may be stated thus: If a straight line is perpendicular to a
+  plane, then it is perpendicular to every line in the plane which it
+  meets. The converse to this would be
+
+  _All straight lines which meet a given straight line in the same
+  point, and are perpendicular to it, lie in a plane which is
+  perpendicular to that line_.
+
+  This Euclid states thus:
+
+  Prop. 5. _If three straight lines meet all at one point, and a
+  straight line stands at right angles to each of them at that point,
+  the three straight lines shall be in one and the same plane_.
+
+  S 75. There follow theorems relating to the theory of parallel lines
+  in space, viz.:--
+
+  Prop. 6. _Any two lines which are perpendicular to the same plane are
+  parallel to each other;_ and conversely
+
+  Prop. 8. _If of two parallel straight lines one is perpendicular to a
+  plane, the other is so also._
+
+  Prop. 7. _If two straight lines are parallel, the straight line which
+  joins any point in one to any point in the other is in the same plane
+  as the parallels._ (See above, S 73.)
+
+  Prop. 9. _Two straight lines which are each of them parallel to the
+  same straight line, and not in the same plane with it, are parallel to
+  one another;_ where the words, "and not in the same plane with it,"
+  may be omitted, for they exclude the case of three parallels in a
+  plane, which has been proved before; and
+
+  Prop. 10. _If two angles in different planes have the two limits of
+  the one parallel to those of the other, then the angles are equal._
+  That their planes are parallel is shown later on in Prop. 15.
+
+  This theorem is not necessarily true, for the angles in question may
+  be supplementary; but then the one angle will be equal to that which
+  is adjacent and supplementary to the other, and this latter angle will
+  also have its limits parallel to those of the first.
+
+  From this theorem it follows that if we take any two straight lines in
+  space which do not meet, and if we draw through any point P in space
+  two lines parallel to them, then the angle included by these lines
+  will always be the same, whatever the position of the point P may be.
+  This angle has in modern times been called the angle between the given
+  lines:--
+
+  _By the angles between two not intersecting lines we understand the
+  angles which two intersecting lines include that are parallel
+  respectively to the two given lines._
+
+  S 76. It is now possible to solve the following two problems:--
+
+  _To draw a straight line perpendicular to a given plane from a given
+  point which lies_
+
+  1. _Not in the plane_ (Prop. 11).
+
+  2. _In the plane_ (Prop. 12).
+
+  The second case is easily reduced to the first--viz. if by aid of the
+  first we have drawn any perpendicular to the plane from some point
+  without it, we need only draw through the given point in the plane a
+  line parallel to it, in order to have the required perpendicular
+  given. The solution of the first part is of interest in itself. It
+  depends upon a construction which may be expressed as a theorem.
+
+  _If from a point A without a plane a perpendicular AB be drawn to the
+  plane, and if from the foot B of this perpendicular another
+  perpendicular BC be drawn to any straight line in the plane, then the
+  straight line joining A to the foot C of this second perpendicular
+  will also be perpendicular to the line in the plane._
+
+  The theory of perpendiculars to a plane is concluded by the theorem--
+
+  Prop. 13. _Through any point in space, whether in or without a plane,
+  only one straight line can be drawn perpendicular to the plane._
+
+  S 77. The next four propositions treat of parallel planes. It is shown
+  _that planes which have a common perpendicular are parallel_ (Prop.
+  14); _that two planes are parallel if two intersecting straight lines
+  in the one are parallel respectively to two straight lines in the
+  other plane_ (Prop. 15); _that parallel planes are cut by any plane in
+  parallel straight lines_ (Prop. 16); and lastly, _that any two
+  straight lines are cut proportionally by a series of parallel planes_
+  (Prop. 17).
+
+  This theory is made more complete by adding the following theorems,
+  which are easy deductions from the last: _Two parallel planes have
+  common perpendiculars_ (converse to 14); and _Two planes which are
+  parallel to a third plane are parallel to each other._
+
+  It will be noted that Prop. 15 at once allows of the solution of the
+  problem: "Through a given point to draw a plane parallel to a given
+  plane." And it is also easily proved that this problem allows always
+  of one, and only of one, solution.
+
+  S 78. We come now to planes which are perpendicular to one another.
+  Two theorems relate to them.
+
+  Prop. 18. _If a straight line be at right angles to a plane, every
+  plane which passes through it shall be at right angles to that plane._
+
+  Prop. 19. _If two planes which cut one another be each of them
+  perpendicular to a third plane, their common section shall be
+  perpendicular to the same plane._
+
+  S 79. If three planes pass through a common point, and if they bound
+  each other, a solid angle of three faces, or a _trihedral_ angle, is
+  formed, and similarly by more planes a solid angle of more faces, or a
+  _polyhedral_ angle. These have many properties which are quite
+  analogous to those of triangles and polygons in a plane. Euclid states
+  some, viz.:--
+
+  Prop. 20. _If a solid angle be contained by three plane angles, any
+  two of them are together greater than the third._
+
+  But the next--
+
+  Prop. 21. _Every solid angle is contained by plane angles, which are
+  together less than four right angles_--has no analogous theorem in the
+  plane.
+
+  We may mention, however, that the theorems about triangles contained
+  in the propositions of Book I., which do not depend upon the theory of
+  parallels (that is all up to Prop. 27), have their corresponding
+  theorems about trihedral angles. The latter are formed, if for "side
+  of a triangle" we write "plane angle" or "face" of trihedral angle,
+  and for "angle of triangle" we substitute "angle between two faces"
+  where the planes containing the solid angle are called its _faces_. We
+  get, for instance, from I. 4, the theorem, _If two trihedral angles
+  have the angles of two faces in the one equal to the angles of two
+  faces in the other, and have likewise the angles included by these
+  faces equal, then the angles in the remaining faces are equal, and the
+  angles between the other faces are equal each to each, viz. those
+  which are opposite equal faces._ The solid angles themselves are not
+  necessarily equal, for they may be only symmetrical like the right
+  hand and the left.
+
+  The connexion indicated between triangles and trihedral angles will
+  also be recognized in
+
+  Prop. 22. _If every two of three plane angles be greater than the
+  third, and if the straight lines which contain them be all equal, a
+  triangle may be made of the straight lines that join the extremities
+  of those equal straight lines._
+
+  And Prop. 23 solves the problem, _To construct a trihedral angle
+  having the angles of its faces equal to three given plane angles, any
+  two of them being greater than the third._ It is, of course, analogous
+  to the problem of constructing a triangle having its sides of given
+  length.
+
+  Two other theorems of this kind are added by Simson in his edition of
+  Euclid's _Elements_.
+
+  S 80. These are the principal properties of lines and planes in space,
+  but before we go on to their applications it will be well to define
+  the word _distance_. In geometry distance means always "shortest
+  distance"; viz. the distance of a point from a straight line, or from
+  a plane, is the length of the perpendicular from the point to the line
+  or plane. The distance between two non-intersecting lines is the
+  length of their common perpendicular, there being but one. The
+  distance between two parallel lines or between two parallel planes is
+  the length of the common perpendicular between the lines or the
+  planes.
+
+  S 81. _Parallelepipeds_.--The rest of the book is devoted to the study
+  of the parallelepiped. In Prop. 24 the possibility of such a solid is
+  proved, viz.:--
+
+  Prop. 24. _If a solid be contained by six planes two and two of which
+  are parallel, the opposite planes are similar and equal
+  parallelograms._
+
+  Euclid calls this solid henceforth a parallelepiped, though he never
+  defines the word. Either face of it may be taken as _base_, and its
+  distance from the opposite face as _altitude_.
+
+  Prop. 25. _If a solid parallelepiped be cut by a plane parallel to two
+  of its opposite planes, it divides the whole into two solids, the base
+  of one of which shall be to the base of the other as the one solid is
+  to the other_.
+
+  This theorem corresponds to the theorem (VI. 1) that parallelograms
+  between the same parallels are to one another as their bases. A
+  similar analogy is to be observed among a number of the remaining
+  propositions.
+
+  S 82. After solving a few problems we come to
+
+  Prop. 28. _If a solid parallelepiped be cut by a plane passing through
+  the diagonals of two of the opposite planes, it shall be cut in two
+  equal parts._
+
+  In the proof of this, as of several other propositions, Euclid
+  neglects the difference between solids which are symmetrical like the
+  right hand and the left.
+
+  Prop. 31. _Solid parallelepipeds, which are upon equal bases, and of
+  the same altitude, are equal to one another._
+
+  Props. 29 and 30 contain special cases of this theorem leading up to
+  the proof of the general theorem.
+
+  As consequences of this fundamental theorem we get
+
+  Prop. 32. _Solid parallelepipeds, which have the same altitude, are to
+  one another as their bases;_ and
+
+  Prop. 33. _Similar solid parallelepipeds are to one another in the
+  triplicate ratio of their homologous sides._
+
+  If we consider, as in S 67, the ratios of lines as numbers, we may
+  also say--
+
+  _The ratio of the volumes of similar parallelepipeds is equal to the
+  ratio of the third powers of homologous sides._
+
+  Parallelepipeds which are not similar but equal are compared by aid of
+  the theorem
+
+  Prop. 34. _The bases and altitudes of equal solid parallelepipeds are
+  reciprocally proportional; and if the bases and altitudes be
+  reciprocally proportional, the solid parallelepipeds are equal._
+
+  S 83. Of the following propositions the 37th and 40th are of special
+  interest.
+
+  Prop. 37. _If four straight lines be proportionals, the similar solid
+  parallelepipeds, similarly described from them, shall also be
+  proportionals; and if the similar parallelepipeds similarly described
+  from four straight lines be proportionals, the straight lines shall be
+  proportionals._
+
+  In symbols it says--
+
+    If a : b = c : d, then a^3 : b^3 = c^3 : d^3.
+
+  Prop. 40 teaches how to compare the volumes of triangular prisms with
+  those of parallelepipeds, by proving _that a triangular prism is equal
+  in volume to a parallelepiped, which has its altitude and its base
+  equal to the altitude and the base of the triangular prism._
+
+  S 84. From these propositions follow all results relating to the
+  mensuration of volumes. We shall state these as we did in the case of
+  areas. The starting-point is the "rectangular" parallelepiped, which
+  has every edge perpendicular to the planes it meets, and which takes
+  the place of the rectangle in the plane. If this has all its edges
+  equal we obtain the "cube."
+
+  If we take a certain line u as unit length, then the square on u is
+  the unit of area, and the cube on u the unit of volume, that is to
+  say, if we wish to measure a volume we have to determine how many unit
+  cubes it contains.
+
+  A rectangular parallelepiped has, as a rule, the three edges unequal,
+  which meet at a point. Every other edge is equal to one of them. If a,
+  b, c be the three edges meeting at a point, then we may take the
+  rectangle contained by two of them, say by b and c, as base and the
+  third as altitude. Let V be its volume, V' that of another rectangular
+  parallelepiped which has the edges a', b, c, hence the same base as
+  the first. It follows then easily, from Prop. 25 or 32, that V : V' =
+  a : a'; or in words,
+
+  _Rectangular parallelepipeds on equal bases are proportional to their
+  altitudes._
+
+  If we have two rectangular parallelepipeds, of which the first has the
+  volume V and the edges a, b, c, and the second, the volume V' and the
+  edges a', b', c', we may compare them by aid of two new ones which
+  have respectively the edges a', b, c and a', b', c, and the volumes V1
+  and V2. We then have
+
+    V : V1 = a : a'; V1 : V2 = b : b', V2 : V' = c : c'.
+
+  Compounding these, we have
+
+    V : V' = (a : a')(b : b')(c : c'),
+
+  or
+
+    V    a    b    c
+    -- = -- . -- . --.
+    V'   a'   b'   c'
+
+  Hence, as a special case, making V' equal to the unit cube U on u we
+  get
+
+    V    a    b    c
+    -- = -- . -- . -- = [alpha].[beta].[gamma],
+    U    u    u    u
+
+  where [alpha], [beta], [gamma] are the numerical values of a, b, c;
+  that is, _The number of unit cubes in a rectangular parallelepiped_ is
+  equal to the product of the numerical values of its three edges. This
+  is generally expressed by saying the volume of a rectangular
+  parallelepiped is measured by the product of its sides, or by the
+  product of its base into its altitude, which in this case is the same.
+
+  Prop. 31 allows us to extend this to any parallelepipeds, and Props.
+  28 or 40, to triangular prisms.
+
+  _The volume of any parallelepiped, or of any triangular prism, is
+  measured by the product of base and altitude._
+
+  The consideration that any polygonal prism may be divided into a
+  number of triangular prisms, which have the same altitude and the sum
+  of their bases equal to the base of the polygonal prism, shows further
+  that the same holds for any prism whatever.
+
+
+  BOOK XII.
+
+  S 85. In the last part of Book XI. we have learnt how to compare the
+  volumes of parallelepipeds and of prisms. In order to determine the
+  volume of any solid bounded by plane faces we must determine the
+  volume of pyramids, for every such solid may be decomposed into a
+  number of pyramids.
+
+  As every pyramid may again be decomposed into triangular pyramids, it
+  becomes only necessary to determine their volume. This is done by the
+
+  _Theorem._--Every triangular pyramid is equal in volume to one third
+  of a triangular prism having the same base and the same altitude as
+  the pyramid.
+
+  This is an immediate consequence of Euclid's
+
+  Prop. 7. _Every prism having a triangular base may be divided into
+  three pyramids that have triangular bases, and are equal to one
+  another._
+
+  The proof of this theorem is difficult, because the three triangular
+  pyramids into which the prism is divided are by no means equal in
+  shape, and cannot be made to coincide. It has first to be proved that
+  two triangular pyramids have equal volumes, if they have equal bases
+  and equal altitudes. This Euclid does in the following manner. He
+  first shows (Prop. 3) that a triangular pyramid may be divided into
+  four parts, of which two are equal triangular pyramids similar to the
+  whole pyramid, whilst the other two are equal triangular prisms, and
+  further, that these two prisms together are greater than the two
+  pyramids, hence more than half the given pyramid. He next shows (Prop.
+  4) that if two triangular pyramids are given, having equal bases and
+  equal altitudes, and if each be divided as above, then the two
+  triangular prisms in the one are equal to those in the other, and each
+  of the remaining pyramids in the one has its base and altitude equal
+  to the base and altitude of the remaining pyramids in the other. Hence
+  to these pyramids the same process is again applicable. We are thus
+  enabled to cut out of the two given pyramids equal parts, each greater
+  than half the original pyramid. Of the remainder we can again cut out
+  equal parts greater than half these remainders, and so on as far as we
+  like. This process may be continued till the last remainder is smaller
+  than any assignable quantity, however small. It follows, so we should
+  conclude at present, that the two volumes must be equal, for they
+  cannot differ by any assignable quantity.
+
+  To Greek mathematicians this conclusion offers far greater
+  difficulties. They prove elaborately, by a _reductio ad absurdum_,
+  that the volumes cannot be unequal. This proof must be read in the
+  _Elements._ We must, however, state that we have in the above not
+  proved Euclid's Prop. 5, but only a special case of it. Euclid does
+  not suppose that the bases of the two pyramids to be compared are
+  equal, and hence he proves that the volumes are as the bases. The
+  reasoning of the proof becomes clearer in the special case, from which
+  the general one may be easily deduced.
+
+  S 86. Prop. 6 extends the result to pyramids with polygonal bases.
+  From these results follow again the rules at present given for the
+  mensuration of solids, viz. a pyramid is the third part of a
+  triangular prism having the same base and the same altitude. But a
+  triangular prism is equal in volume to a parallelepiped which has the
+  same base and altitude. Hence if B is the base and h the altitude, we
+  have
+
+    Volume of prism   = Bh,
+    Volume of pyramid = 1/3Bh,
+
+  statements which have to be taken in the sense that B means the number
+  of square units in the base, h the number of units of length in the
+  altitude, or that B and h denote the numerical values of base and
+  altitude.
+
+  S 87. A method similar to that used in proving Prop. 5 leads to the
+  following results relating to solids bounded by simple curved
+  surfaces:--
+
+  Prop. 10. _Every cone is the third part of a cylinder which has the
+  same base, and is of an equal altitude with it._
+
+  Prop. 11. _Cones or cylinders of the same altitude are to one another
+  as their bases._
+
+  Prop. 12. _Similar cones or cylinders have to one another the
+  triplicate ratio of that which the diameters of their bases have._
+
+  Prop. 13. _If a cylinder be cut by a plane parallel to its opposite
+  planes or bases, it divides the cylinder into two cylinders, one of
+  which is to the other as the axis of the first to the axis of the
+  other;_ which may also be stated thus:--
+
+  _Cylinders on the same base are proportional to their altitudes._
+
+  Prop. 14. _Cones or cylinders upon equal bases are to one another as
+  their altitudes._
+
+  Prop. 15. _The bases and altitudes of equal cones or cylinders are
+  reciprocally proportional, and if the bases and altitudes be
+  reciprocally proportional, the cones or cylinders are equal to one
+  another._
+
+  These theorems again lead to formulae in mensuration, if we compare a
+  cylinder with a prism having its base and altitude equal to the base
+  and altitude of the cylinder. This may be done by the method of
+  exhaustion. We get, then, the result that their bases are equal, and
+  have, if B denotes the numerical value of the base, and h that of the
+  altitude,
+
+    Volume of cylinder = Bh,
+    Volume of cone     = 1/3Bh.
+
+  S 88. The remaining propositions relate to circles and spheres. Of the
+  sphere only one property is proved, viz.:--
+
+  Prop. 18. _Spheres have to one another the triplicate ratio of that
+  which their diameters have._ The mensuration of the sphere, like that
+  of the circle, the cylinder and the cone, had not been settled in the
+  time of Euclid. It was done by Archimedes.
+
+
+  BOOK XIII.
+
+  S 89. The 13th and last book of Euclid's _Elements_ is devoted to the
+  regular solids (see POLYHEDRON). It is shown that there are five of
+  them, viz.:--
+
+  1. The regular _tetrahedron_, with 4 triangular faces and 4 vertices;
+
+  2. The _cube_, with 8 vertices and 6 square faces;
+
+  3. The _octahedron_, with 6 vertices and 8 triangular faces;
+
+  4. The _dodecahedron_, with 12 pentagonal faces, 3 at each of the
+  20 vertices;
+
+  5. The _icosahedron_, with 20 triangular faces, 5 at each of the
+  12 vertices.
+
+  It is shown how to inscribe these solids in a given sphere, and how to
+  determine the lengths of their edges.
+
+  S 90. The 13th book, and therefore the _Elements_, conclude with the
+  scholium, "that no other regular solid exists besides the five ones
+  enumerated."
+
+  The proof is very simple. Each face is a regular polygon, hence the
+  angles of the faces at any vertex must be angles in equal regular
+  polygons, must be together less than four right angles (XI. 21), and
+  must be three or more in number. Each angle in a regular triangle
+  equals two-thirds of one right angle. Hence it is possible to form a
+  solid angle with three, four or five regular triangles or faces. These
+  give the solid angles of the tetrahedron, the octahedron and the
+  icosahedron. The angle in a square (the regular quadrilateral) equals
+  one right angle. Hence three will form a solid angle, that of the
+  cube, and four will not. The angle in the regular pentagon equals 6/5
+  of a right angle. Hence three of them equal 18/5 (i.e. less than 4)
+  right angles, and form the solid angle of the dodecahedron. Three
+  regular polygons of six or more sides cannot form a solid angle.
+  Therefore no other regular solids are possible.     (O. H.)
+
+
+II. PROJECTIVE GEOMETRY
+
+It is difficult, at the outset, to characterize projective geometry as
+compared with Euclidean. But a few examples will at least indicate the
+practical differences between the two.
+
+In Euclid's _Elements_ almost all propositions refer to the _magnitude_
+of lines, angles, areas or volumes, and therefore to measurement. The
+statement that an angle is right, or that two straight lines are
+parallel, refers to measurement. On the other hand, the fact that a
+straight line does or does not cut a circle is independent of
+measurement, it being dependent only upon the mutual "position" of the
+line and the circle. This difference becomes clearer if we project any
+figure from one plane to another (see PROJECTION). By this the length of
+lines, the magnitude of angles and areas, is altered, so that the
+projection, or shadow, of a square on a plane will not be a square; it
+will, however, be some quadrilateral. Again, the projection of a circle
+will not be a circle, but some other curve more or less resembling a
+circle. But one property may be stated at once--no straight line can cut
+the projection of a circle in more than two points, because no straight
+line can cut a circle in more than two points. There are, then, some
+properties of figures which do not alter by projection, whilst others
+do. To the latter belong nearly all properties relating to measurement,
+at least in the form in which they are generally given. The others are
+said to be projective properties, and their investigation forms the
+subject of projective geometry.
+
+Different as are the kinds of properties investigated in the old and the
+new sciences, the methods followed differ in a still greater degree. In
+Euclid each proposition stands by itself; its connexion with others is
+never indicated; the leading ideas contained in its proof are not
+stated; general principles do not exist. In the modern methods, on the
+other hand, the greatest importance is attached to the leading thoughts
+which pervade the whole; and general principles, which bring whole
+groups of theorems under one aspect, are given rather than separate
+propositions. The whole tendency is towards generalization. A straight
+line is considered as given in its entirety, extending both ways to
+infinity, while Euclid never admits anything but finite quantities. The
+treatment of the infinite is in fact another fundamental difference
+between the two methods: Euclid avoids it; in modern geometry it is
+systematically introduced.
+
+Of the different modern methods of geometry, we shall treat principally
+of the methods of projection and correspondence which have proved to be
+the most powerful. These have become independent of Euclidean Geometry,
+especially through the _Geometrie der Lage_ of V. Staudt and the
+_Ausdehnungslehre_ of Grassmann.
+
+For the sake of brevity we shall presuppose a knowledge of Euclid's
+_Elements_, although we shall use only a few of his propositions.
+
+  S 1. _Geometrical Elements._ We consider space as filled with points,
+  lines and planes, and these we call the elements out of which our
+  figures are to be formed, calling any combination of these elements a
+  "figure."
+
+  By a line we mean a straight line in its entirety, extending both ways
+  to infinity; and by a plane, a plane surface, extending in all
+  directions to infinity.
+
+  We accept the three-dimensional space of experience--the space assumed
+  by Euclid--which has for its properties (among others):--
+
+  Through any two points in space one and only one line may be drawn;
+
+  Through any three points which are not in a line, one and only one
+  plane may be placed;
+
+  The intersection of two planes is a line;
+
+  A line which has two points in common with a plane lies in the plane,
+  hence the intersection of a line and a plane is a single point; and
+
+  Three planes which do not meet in a line have one single point in
+  common.
+
+  These results may be stated differently in the following form:--
+
+  I. A plane is determined--           A point is determined--
+       1. By three points which do         1. By three planes which do
+           not lie in a line;                  not pass through a line;
+       2. By two intersecting lines;       2. By two intersecting lines;
+       3. By a line and a point            3. By a plane and a line
+           which does not lie in it.           which does not lie in it.
+  II. A line is determined--
+       1. By two points;                   2. By two planes.
+
+  It will be observed that not only are planes determined by points, but
+  also points by planes; that therefore the planes may be considered as
+  elements, like points; and also that in any one of the above
+  statements we may interchange the words point and plane, and we obtain
+  again a correct statement, provided that these statements themselves
+  are true. As they stand, we ought, in several cases, to add "if they
+  are not parallel," or some such words, parallel lines and planes being
+  evidently left altogether out of consideration. To correct this we
+  have to reconsider the theory of parallels.
+
+  [Illustration: FIG. 1.]
+
+  S 2. _Parallels. Point at Infinity._--Let us take in a plane a line p
+  (fig. 1), a point S not in this line, and a line q drawn through S.
+  Then this line q will meet the line p in a point A. If we turn the
+  line q about S towards q', its point of intersection with p will move
+  along p towards B, passing, on continued turning, to a greater and
+  greater distance, until it is moved out of our reach. If we turn q
+  still farther, its continuation will meet p, but now at the other side
+  of A. The point of intersection has disappeared to the right and
+  reappeared to the left. There is one intermediate position where q is
+  parallel to p--that is where it does not cut p. In every other
+  position it cuts p in some finite point. If, on the other hand, we
+  move the point A to an infinite distance in p, then the line q which
+  passes through A will be a line which does not cut p at any finite
+  point. Thus we are led to say: _Every_ line through S which joins it
+  to any point at an infinite distance in p is parallel to p. But by
+  Euclid's 12th axiom there is but one line parallel to p through S. The
+  difficulty in which we are thus involved is due to the fact that we
+  try to reason about infinity as if we, with our finite capabilities,
+  could comprehend the infinite. To overcome this difficulty, we may say
+  that all points at infinity in a line _appear_ to us as one, and may
+  be replaced by a single "ideal" point.
+
+  We may therefore now give the following definitions and axiom:--
+
+  _Definition._--Lines which meet at infinity are called parallel.
+
+  _Axiom._--All points at an infinite distance in a line may be
+  considered as one single point.
+
+  _Definition._--This ideal point is called the _point at infinity_ in
+  the line.
+
+  The axiom is equivalent to Euclid's Axiom 12, for it follows from
+  either that through any point only one line may be drawn parallel to a
+  given line.
+
+  This point at infinity in a line is reached whether we move a point in
+  the one or in the opposite direction of a line to infinity. A line
+  thus appears closed by this point, and we speak as if we could move a
+  point along the line from one position A to another B in two ways,
+  either through the point at infinity or through finite points only.
+
+  It must never be forgotten that this point at infinity is ideal; in
+  fact, the whole notion of "infinity" is only a mathematical
+  conception, and owes its introduction (as a method of research) to the
+  working generalizations which it permits.
+
+  S 3. _Line and Plane at Infinity._--Having arrived at the notion of
+  replacing all points at infinity in a line by one ideal point, there
+  is no difficulty in replacing all points at infinity in a plane by one
+  ideal line.
+
+  To make this clear, let us suppose that a line p, which cuts two fixed
+  lines a and b in the points A and B, moves parallel to itself to a
+  greater and greater distance. It will at last cut both a and b at
+  their points at infinity, so that a line which joins the two points at
+  infinity in two intersecting lines lies altogether at infinity. Every
+  other line in the plane will meet it therefore at infinity, and thus
+  it contains all points at infinity in the plane.
+
+  _All points at infinity in a plane lie in a line, which is called the_
+  line at infinity _in the plane._
+
+  It follows that parallel planes must be considered as planes having a
+  common line at infinity, for any other plane cuts them in parallel
+  lines which have a point at infinity in common.
+
+  If we next take two intersecting planes, then the point at infinity in
+  their line of intersection lies in both planes, so that their lines at
+  infinity meet. Hence every line at infinity meets every other line at
+  infinity, and they are therefore all in one plane.
+
+  _All points at infinity in space may be considered as lying in one
+  ideal plane, which is called the_ plane at infinity.
+
+  S 4. _Parallelism._--We have now the following definitions:--
+
+  Parallel lines are lines which meet at infinity;
+
+  Parallel planes are planes which meet at infinity;
+
+  A line is parallel to a plane if it meets it at infinity.
+
+  Theorems like this--Lines (or planes) which are parallel to a third
+  are parallel to each other--follow at once.
+
+  This view of parallels leads therefore to no contradiction of Euclid's
+  _Elements._
+
+  As immediate consequences we get the propositions:--
+
+  Every line meets a plane in one point, or it lies in it;
+
+  Every plane meets every other plane in a line;
+
+  Any two lines in the same plane meet.
+
+  S 5. _Aggregates of Geometrical Elements._--We have called points,
+  lines and planes the elements of geometrical figures. We also say that
+  an element of one kind contains one of the other if it lies in it or
+  passes through it.
+
+  All the elements of one kind which are contained in one or two
+  elements of a different kind form aggregates which have to be
+  enumerated. They are the following:--
+
+  I. Of one dimension.
+
+     1. The _row_, or range, _of points_ formed by all points in a line,
+          which is called its base.
+
+     2. The _flat pencil_ formed by all the lines through a point in a
+          plane. Its base is the point in the plane.
+
+     3. The _axial pencil_ formed by all planes through a line which is
+          called its base or axis.
+
+  II. Of two dimensions.
+
+     1. The field of points and lines--that is, a plane with all its
+          points and all its lines.
+
+     2. The pencil of lines and planes--that is, a point in space with
+          all lines and all planes through it.
+
+  III. Of three dimensions.
+
+     The space of points--that is, all points in space.
+
+     The space of planes--that is, all planes in space.
+
+  IV. Of four dimensions.
+
+     The space of lines, or all lines in space.
+
+  S 6. _Meaning of "Dimensions."_--The word dimension in the above needs
+  explanation. If in a plane we take a row p and a pencil with centre Q,
+  then through every point in p one line in the pencil will pass, and
+  every ray in Q will cut p in one point, so that we are entitled to say
+  a row contains as many points as a flat pencil lines, and, we may add,
+  as an axial pencil planes, because an axial pencil is cut by a plane
+  in a flat pencil.
+
+  The number of elements in the row, in the flat pencil, and in the
+  axial pencil is, of course, infinite and indefinite too, but the same
+  in all. This number may be denoted by [infinity]. Then a plane
+  contains [infinity]^2 points and as many lines. To see this, take a
+  flat pencil in a plane. It contains [infinity] lines, and each line
+  contains [infinity] points, whilst each point in the plane lies on one
+  of these lines. Similarly, in a plane each line cuts a fixed line in a
+  point. But this line is cut at each point by [infinity] lines and
+  contains [infinity] points; hence there are [infinity]^2 lines in a
+  plane.
+
+  A pencil in space contains as many lines as a plane contains points
+  and as many planes as a plane contains lines, for any plane cuts the
+  pencil in a field of points and lines. Hence a pencil contains
+  [infinity]^2 lines and [infinity]^2 planes. _The field and the pencil
+  are of two dimensions._
+
+  To count the number of points in space we observe that each point lies
+  on some line in a pencil. But the pencil contains [infinity]^2 lines,
+  and each line [infinity] points; hence space contains [infinity]^3
+  points. Each plane cuts any fixed plane in a line. But a plane
+  contains [infinity]^2 lines, and through each pass [infinity] planes;
+  therefore space contains [infinity]^3 planes.
+
+  Hence space contains as many planes as points, but it contains an
+  infinite number of times more lines than points or planes. To count
+  them, notice that every line cuts a fixed plane in one point. But
+  [infinity]^2 lines pass through each point, and there are [infinity]^2
+  points in the plane. Hence there are [infinity]^4 lines in space. _The
+  space of points and planes is of three dimensions, but the space of
+  lines is of four dimensions._
+
+  A field of points or lines contains an infinite number of rows and
+  flat pencils; a pencil contains an infinite number of flat pencils and
+  of axial pencils; space contains a triple infinite number of pencils
+  and of fields, [infinity]^4 rows and axial pencils and [infinity]^5
+  flat pencils--or, in other words, each point is a centre of
+  [infinity]^2 flat pencils.
+
+  S 7. The above enumeration allows a classification of figures. Figures
+  in a row consist of groups of points only, and figures in the flat or
+  axial pencil consist of groups of lines or planes. In the plane we may
+  draw polygons; and in the pencil or in the point, solid angles, and so
+  on.
+
+  We may also distinguish the different measurements We have--
+
+    In the row, length of segment;
+    In the flat pencil, angles;
+    In the axial pencil, dihedral angles between two planes;
+    In the plane, areas;
+    In the pencil, solid angles;
+    In the space of points or planes, volumes.
+
+
+  SEGMENTS OF A LINE
+
+  S 8. Any two points A and B in space determine on the line through
+  them a finite part, which may be considered as being described by a
+  point moving from A to B. This we shall denote by AB, and distinguish
+  it from BA, which is supposed as being described by a point moving
+  from B to A, and hence in a direction or in a "sense" opposite to AB.
+  Such a finite line, which has a definite sense, we shall call a
+  "segment," so that AB and BA denote different segments, which are said
+  to be equal in length but of opposite sense. The one sense is often
+  called positive and the other negative.
+
+  In introducing the word "sense" for direction in a line, we have the
+  word direction reserved for direction of the line itself, so that
+  different lines have different directions, unless they be parallel,
+  whilst in each line we have a positive and negative sense.
+
+  We may also say, with Clifford, that AB denotes the "step" of going
+  from A to B.
+
+  [Illustration: FIG. 2.]
+
+  S 9. If we have three points A, B, C in a line (fig. 2), the step AB
+  will bring us from A to B, and the step BC from B to C. Hence both
+  steps are equivalent to the one step AC. This is expressed by saying
+  that AC is the "sum" of AB and BC; in symbols--
+
+    AB + BC = AC,
+
+  where account is to be taken of the sense.
+
+  This equation is true whatever be the position of the three points on
+  the line. As a special case we have
+
+    AB + BA = 0, (1)
+
+  and similarly
+
+    AB + BC + CA = 0, (2)
+
+  which again is true for any three points in a line.
+
+  We further write
+
+    AB = -BA.
+
+  where - denotes negative sense.
+
+  We can then, just as in algebra, change subtraction of segments into
+  addition by changing the sense, so that AB - CB is the same as AB +
+  (-CB) or AB + BC. A figure will at once show the truth of this. The
+  sense is, in fact, in every respect equivalent to the "sign" of a
+  number in algebra.
+
+  S 10. Of the many formulae which exist between points in a line we
+  shall have to use only one more, which connects the segments between
+  any four points A, B, C, D in a line. We have
+
+    BC = BD + DC, CA = CD + DA, AB = AD + DB;
+
+  or multiplying these by AD, BD, CD respectively, we get
+
+    BC.AD = BD.AD + DC.AD = BD.AD - CD.AD
+
+    CA.BD = CD.BD + DA.BD = CD.BD - AD.BD
+
+    AB.CD = AD.CD + DB.CD = AD.CD - BD.CD.
+
+  It will be seen that the sum of the right-hand sides vanishes, hence
+  that
+
+    BC.AD + CA.BD + AB.CD = 0 (3)
+
+  for any four points on a line.
+
+  [Illustration: FIG. 3.]
+
+  S 11. If C is any point in the line AB, then we say that C divides the
+  segment AB in the ratio AC/CB, account being taken of the sense of the
+  two segments AC and CB. If C lies between A and B the ratio is
+  positive, as AC and CB have the same sense. But if C lies without the
+  segment AB, i.e. if C divides AB externally, then the ratio is
+  negative. To see how the value of this ratio changes with C, we will
+  move C along the whole line (fig. 3), whilst A and B remain fixed. If
+  C lies at the point A, then AC = 0, hence the ratio AC : CB vanishes.
+  As C moves towards B, AC increases and CB decreases, so that our ratio
+  increases. At the middle point M of AB it assumes the value +1, and
+  then increases till it reaches an infinitely large value, when C
+  arrives at B. On passing beyond B the ratio becomes negative. If C is
+  at P we have AC = AP = AB + BP, hence
+
+    AC   AB   BP     AB
+    -- = -- + -- = - -- - 1.
+    CB   PB   PB     BP
+
+  In the last expression the ratio AB : BP is positive, has its greatest
+  value [infinity] when C coincides with B, and vanishes when BC becomes
+  infinite. Hence, as C moves from B to the right to the point at
+  infinity, the ratio AC : CB varies from -[infinity] to -1.
+
+  If, on the other hand, C is to the left of A, say at Q, we have AC =
+  AQ = AB + BQ = AB - QB, hence AC/CB = AB/QB - 1.
+
+  Here AB < QB, hence the ratio AB : QB is positive and always less than
+  one, so that the whole is negative and < 1. If C is at the point at
+  infinity it is -1, and then increases as C moves to the right, till
+  for C at A we get the ratio = 0. Hence--
+
+  "As C moves along the line from an infinite distance to the left to an
+  infinite distance at the right, the ratio always increases; it starts
+  with the value -1, reaches 0 at A, +1 at M, [infinity] at B, now
+  changes sign to -[infinity], and increases till at an infinite
+  distance it reaches again the value -1. _It assumes therefore all
+  possible values from -[infinity] to +[infinity], and each value only
+  once, so that not only does every position of C determine a definite
+  value of the ratio AC : CB, but also, conversely, to every positive or
+  negative value of this ratio belongs one single point in the line AB._
+
+  [Relations between segments of lines are interesting as showing an
+  application of algebra to geometry. The genesis of such relations
+  from algebraic identities is very simple. For example, if a, b, c, x
+  be any four quantities, then
+
+              a                       b
+    --------------------- + --------------------- +
+    (a - b)(a - c)(x - a)   (b - c)(b - a)(x - b)
+
+                c                       x
+      --------------------- = ---------------------;
+      (c - a)(c - b)(x - c)   (x - a)(x - b)(x - c)
+
+  this may be proved, cumbrously, by multiplying up, or, simply, by
+  decomposing the right-hand member of the identity into partial
+  fractions. Now take a line ABCDX, and let AB = a, AC = b, AD = c, AX =
+  x. Then obviously (a - b) = AB - AC = -BC, paying regard to signs; (a
+  - c) = AB - AD = DB, and so on. Substituting these values in the
+  identity we obtain the following relation connecting the segments
+  formed by five points on a line:--
+
+       AB         AC         AD         AX
+    -------- + -------- + -------- = --------.
+    BC.BD.BX   CD.CB.CX   DB.DC.DX   BX.CX.DX
+
+  Conversely, if a metrical relation be given, its validity may be
+  tested by reducing to an algebraic equation, which is an identity if
+  the relation be true. For example, if ABCDX be five collinear points,
+  prove
+
+    AD.AX   BD.BX   CD.CX
+    ----- + ----- + ----- = 1.
+    AB.AC   BC.BA   CA.CB
+
+  Clearing of fractions by multiplying throughout by AB.BC.CA, we have
+  to prove
+
+    -AD.AX.BC - BD.BX.CA - CD.CX.AB = AB.BC.CA.
+
+  Take A as origin and let AB = a, AC = b, AD = c, AX = x. Substituting
+  for the segments in terms of a, b, c, x, we obtain on simplification
+
+    a^2b - ab^2 = -ab^2 + a^2b, an obvious identity.
+
+  An alternative method of testing a relation is illustrated in the
+  following example:-- If A, B, C, D, E, F be six collinear points, then
+
+      AE.AF      BE.BF      CE.CF      DE.DF
+    -------- + -------- + -------- + -------- = 0.
+    AB.AC.AD   BC.BD.BA   CD.CA.CB   DA.DB.DC
+
+  Clearing of fractions by multiplying throughout by AB.BC.CD.DA, and
+  reducing to a common origin O (calling OA = a, OB = b, &c.), an
+  equation containing the second and lower powers of OA (= a), &c., is
+  obtained. Calling OA = x, it is found that x = b, x = c, x = d are
+  solutions. Hence the quadratic has three roots; consequently it is an
+  identity.
+
+  The relations connecting five points which we have instanced above may
+  be readily deduced from the six-point relation; the first by taking D
+  at infinity, and the second by taking F at infinity, and then making
+  the obvious permutations of the points.]
+
+
+  PROJECTION AND CROSS-RATIOS
+
+  S 12. If we join a point A to a point S, then the point where the line
+  SA cuts a fixed plane [pi] is called the projection of A on the plane
+  [pi] from S as centre of projection. If we have two planes [pi] and
+  [pi]' and a point S, we may project every point A in [pi] to the other
+  plane. If A' is the projection of A, then A is also the projection of
+  A', so that the relations are reciprocal. To every figure in [pi] we
+  get as its projection a corresponding figure in [pi]'.
+
+  We shall determine such properties of figures as remain true for the
+  projection, and which are called projective properties. For this
+  purpose it will be sufficient to consider at first only constructions
+  in one plane.
+
+  [Illustration: FIG. 4.]
+
+  [Illustration: FIG. 5.]
+
+  Let us suppose we have given in a plane two lines p and p' and a
+  centre S (fig. 4); we may then project the points in p from S to p'.
+  Let A', B' ... be the projections of A, B ..., the point at infinity
+  in p which we shall denote by I will be projected into a finite point
+  I' in p', viz. into the point where the parallel to p through S cuts
+  p'. Similarly one point J in p will be projected into the point J' at
+  infinity in p'. This point J is of course the point where the parallel
+  to p' through S cuts p. We thus see that every point in p is projected
+  into a single point in p'.
+
+  Fig. 5 shows that a segment AB will be projected into a segment A'B'
+  which is not equal to it, at least not as a rule; and also that the
+  ratio AC : CB is not equal to the ratio A'C' : C'B' formed by the
+  projections. These ratios will become equal only if p and p' are
+  parallel, for in this case the triangle SAB is similar to the triangle
+  SA'B'. Between three points in a line and their projections there
+  exists therefore in general no relation. But between four points a
+  relation does exist.
+
+  S 13. Let A, B, C, D be four points in p, A', B', C, D' their
+  projections in p', then the ratio of the two ratios AC : CB and AD :
+  DB into which C and D divide the segment AB is equal to the
+  corresponding expression between A', B', C', D'. In symbols we have
+
+    AC   AD   A'C'   A'D'
+    -- : -- = ---- : ----.
+    CB   DB   C'B'   D'B'
+
+  This is easily proved by aid of similar triangles.
+
+  [Illustration: FIG. 6.]
+
+  Through the points A and B on p draw parallels to p', which cut the
+  projecting rays in C2, D2, B2 and A1, C1, D1, as indicated in fig. 6.
+  The two triangles ACC2 and BCC1 will be similar, as will also be the
+  triangles ADD2 and BDD1.
+
+  The proof is left to the reader.
+
+  This result is of fundamental importance.
+
+  The expression AC/CB : AD/DB has been called by Chasles the
+  "anharmonic ratio of the four points A, B, C, D." Professor Clifford
+  proposed the shorter name of "cross-ratio." We shall adopt the latter.
+  We have then the
+
+  FUNDAMENTAL THEOREM.--_The cross-ratio of four points in a line is
+  equal to the cross-ratio of their projections on any other line which
+  lies in the same plane with it._
+
+  S 14. Before we draw conclusions from this result, we must investigate
+  the meaning of a cross-ratio somewhat more fully.
+
+  If four points A, B, C, D are given, and we wish to form their
+  cross-ratio, we have first to divide them into two groups of two, the
+  points in each group being taken in a definite order. Thus, let A, B
+  be the first, C, D the second pair, A and C being the first points in
+  each pair. The cross-ratio is then the ratio AC : CB divided by AD :
+  DB. This will be denoted by (AB, CD), so that
+
+               AC   AD
+    (AB, CD) = -- : --.
+               CB   DB
+
+  This is easily remembered. In order to write it out, make first the
+  two lines for the fractions, and put above and below these the letters
+  A and B in their places, thus, A*/B : A*/B; and then fill up,
+  crosswise, the first by C and the other by D.
+
+  S 15. If we take the points in a different order, the value of the
+  cross-ratio will change. We can do this in twenty-four different ways
+  by forming all permutations of the letters. But of these twenty-four
+  cross-ratios groups of four are equal, so that there are really only
+  six different ones, and these six are reciprocals in pairs.
+
+  We have the following rules:--
+
+  I. If in a cross-ratio the two groups be interchanged, its value
+  remains unaltered, i.e.
+
+    (AB, CD) = (CD, AB) = (BA, DC) = (DC, BA).
+
+  II. If in a cross-ratio the two points belonging to one of the two
+  groups be interchanged, the cross-ratio changes into its reciprocal,
+  i.e.
+
+    (AB, CD) = 1/(AB, DC) = 1/(BA, CD) = 1/(CD, BA) = 1/(DC, AB).
+
+  From I. and II. we see that eight cross-ratios are associated with
+  (AB, CD).
+
+  III. If in a cross-ratio the two middle letters be interchanged, the
+  cross-ratio [alpha] changes into its complement 1 - [alpha], i.e. (AB,
+  CD) = 1 - (AC, BD).
+
+  [S 16. If [lambda] = (AB, CD), [mu] = (AC, DB), [nu] = (AD, BC), then
+  [lambda], [mu], [nu] and their reciprocals 1/[lambda], 1/[mu], 1/[nu]
+  are the values of the total number of twenty-four cross-ratios.
+  Moreover, [lambda], [mu], [nu] are connected by the relations
+
+    [lambda] + 1/[mu] = [mu] + 1/[nu] = [nu] + 1/[lambda] = -[lambda][mu][nu] = 1;
+
+  this proposition may be proved by substituting for [lambda], [mu],
+  [nu] and reducing to a common origin. There are therefore four
+  equations between three unknowns; hence if one cross-ratio be given,
+  the remaining twenty-three are determinate. Moreover, two of the
+  quantities [lambda], [mu], [nu] are positive, and the remaining one
+  negative.
+
+  The following scheme shows the twenty-four cross-ratios expressed in
+  terms of [lambda], [mu], [nu].]
+
+    +---------+-----------------------+---------------+---------------+
+    |(AB, CD) |                       |               |               |
+    |(BA, DC) |       [lambda]        |    1 - [mu]   |  1/(1 - [nu]) |
+    |(CD, AB) |                       |               |               |
+    |(DC, BA) |                       |               |               |
+    +---------+-----------------------+---------------+---------------+
+    |(AC, DB) |                       |               |               |
+    |(BD, CA) |   1/(1 - [lambda])    |     1/[mu]    |([nu] - 1)/[nu]|
+    |(CA, BD) |                       |               |               |
+    |(DB, AC) |                       |               |               |
+    +---------+-----------------------+---------------+---------------+
+    |(AB, DC) |                       |               |               |
+    |(BA, CD) |      1/[lambda]       |  1/(1 - [mu]) |   1 - [nu]    |
+    |(CD, BA) |                       |               |               |
+    |(DC, AB) |                       |               |               |
+    +---------+-----------------------+---------------+---------------+
+    |(AD, BC) |                       |               |               |
+    |(BC, AD) |([lambda] - 1)/[lambda]|[mu]/([mu] - 1)|     [nu]      |
+    |(CB, DA) |                       |               |               |
+    |(DA, CB) |                       |               |               |
+    +---------+-----------------------+---------------+---------------+
+    |(AC, BD) |                       |               |               |
+    |(BD, AC) |     1 - [lambda]      |     [mu]      |[nu]/([nu] - 1)|
+    |(CA, DB) |                       |               |               |
+    |(DB, CA) |                       |               |               |
+    +---------+-----------------------+---------------+---------------+
+    |(AD, CB) |                       |               |               |
+    |(BC, DA) |[lambda]/([lambda] - 1)|([mu] - 1)/[mu]|    1/[nu]     |
+    |(CB, AD) |                       |               |               |
+    |(DA, BC) |                       |               |               |
+    +---------+-----------------------+---------------+---------------+
+
+  S 17. If one of the points of which a cross-ratio is formed is the
+  point at infinity in the line, the cross-ratio changes into a simple
+  ratio. It is convenient to let the point at infinity occupy the last
+  place in the symbolic expression for the cross-ratio. Thus if I is a
+  point at infinity, we have (AB, CI) = -AC/CB, because AI : IB = -1.
+
+  Every common ratio of three points in a line may thus be expressed as
+  a cross-ratio, by adding the point at infinity to the group of points.
+
+
+  HARMONIC RANGES
+
+  S 18. If the points have special positions, the cross-ratios may have
+  such a value that, of the six different ones, two and two become
+  equal. If the first two shall be equal, we get [lambda] = 1/[lambda],
+  or [lambda]^2 = 1, [lambda] = [+-]1.
+
+  If we take [lambda] = +1, we have (AB, CD) = 1, or AC/CB = AD/DB; that
+  is, the points C and D coincide, provided that A and B are different.
+
+  If we take [lambda] = -1, so that (AB, CD) = -1, we have AC/CB =
+  -AD/DB. _Hence C and D divide AB internally and externally in the same
+  ratio._
+
+  The four points are in this case said to be _harmonic points_, and _C
+  and D are said to be harmonic conjugates with regard to A and B._
+
+  But we have also (CD, AB) = -1, so that A and B are harmonic
+  conjugates with regard to C and D.
+
+  The principal property of harmonic points is that their cross-ratio
+  remains unaltered if we interchange the two points belonging to one
+  pair, viz.
+
+    (AB, CD) = (AB, DC) = (BA, CD).
+
+  For four harmonic points the six cross-ratios become equal two and
+  two:
+
+                                       [lambda]
+    [lambda] = -1, 1 - [lambda] = 2, ------------ = 1/2,
+                                     [lambda] - 1
+
+           1                1              [lambda] - 1
+      = -------- = -1, ------------ = 1/2, ------------ = 2.
+        [lambda]       1 - [lambda]          [lambda]
+
+  Hence if we get four points whose cross-ratio is 2 or 1/2, then they
+  are harmonic, but not arranged so that conjugates are paired. If this
+  is the case the cross-ratio = -1.
+
+  S 19. If we equate any two of the above six values of the
+  cross-ratios, we get either [lambda] = 1, 0, [infinity], or [lambda] =
+  -1, 2, 1/2, or else [lambda] becomes a root of the equation [lambda]^2
+  - [lambda] + 1 = 0, that is, an imaginary cube root of -1. In this
+  case the six values become three and three equal, so that only two
+  different values remain. This case, though important in the theory of
+  cubic curves, is for our purposes of no interest, whilst harmonic
+  points are all-important.
+
+  S 20. From the definition of harmonic points, and by aid of S 11, the
+  following properties are easily deduced.
+
+  If C and D are harmonic conjugates with regard to A and B, then one of
+  them lies in, the other without AB; it is impossible to move from A to
+  B without passing either through C or through D; the one blocks the
+  finite way, the other the way through infinity. This is expressed by
+  saying A and B are "separated" by C and D.
+
+  For every position of C there will be one and only one point D which
+  is its harmonic conjugate with regard to any point pair A, B.
+
+  If A and B are different points, and if C coincides with A or B, D
+  does. But if A and B coincide, one of the points C or D, lying between
+  them, coincides with them, and the other may be anywhere in the line.
+  It follows that, "_if of four harmonic conjugates two coincide, then a
+  third coincides with them, and the fourth may be any point in the
+  line_."
+
+  If C is the middle point between A and B, then D is the point at
+  infinity; for AC : CB = +1, hence AD : DB must be equal to -1. _The
+  harmonic conjugate of the point at infinity in a line with regard to
+  two points A, B is the middle point of AB._
+
+  This important property gives a first example how metric properties
+  are connected with projective ones.
+
+  [S 21. _Harmonic properties of the complete quadrilateral and
+  quadrangle._
+
+  [Illustration: FIG. 7.]
+
+  [Illustration: FIG. 8.]
+
+  A figure formed by four lines in a plane is called a _complete
+  quadrilateral_, or, shorter, a _four-side_. The four sides meet in six
+  points, named the "vertices," which may be joined by three lines
+  (other than the sides), named the "diagonals" or "harmonic lines." The
+  diagonals enclose the "harmonic triangle of the quadrilateral." In
+  fig. 7, A'B'C', B'AC, C'AB, CBA' are the sides, A, A', B, B', C, C'
+  the vertices, AA', BB', CC' the harmonic lines, and
+  [alpha][beta][gamma] the harmonic triangle of the quadrilateral. A
+  figure formed by four coplanar points is named a _complete
+  quadrangle_, or, shorter, a _four-point_. The four points may be
+  joined by six lines, named the "sides," which intersect in three other
+  points, termed the "diagonal or harmonic points." The harmonic points
+  are the vertices of the "harmonic triangle of the complete
+  quadrangle." In fig. 8, AA', BB' are the points, AA', BB', A'B', B'A,
+  AB, BA' are the sides, L, M, N are the diagonal points, and LMN is the
+  harmonic triangle of the quadrangle.
+
+  The harmonic property of the complete quadrilateral is: Any diagonal
+  or harmonic line is harmonically divided by the other two; and of a
+  complete quadrangle: The angle at any harmonic point is divided
+  harmonically by the joins to the other harmonic points. To prove the
+  first theorem, we have to prove (AA', [beta][gamma]), (BB',
+  [gamma][alpha]), (CC', [beta][alpha]) are harmonic. Consider the
+  cross-ratio (CC', [alpha][beta]). Then projecting from A on BB' we
+  have A(CC', [alpha][beta]) = A(B'B, [alpha][gamma]). Projecting from
+  A' on BB', A'(CC', [alpha][beta]) = A'(BB', [alpha][gamma]). Hence
+  (B'B, [alpha][gamma]) = (BB', [alpha][gamma]), i.e. the cross-ratio
+  (BB', [alpha][gamma]) equals that of its reciprocal; hence the range
+  is harmonic.
+
+  The second theorem states that the pencils L(BA, NM), M(B'A, LN),
+  N(BA, LM) are harmonic. Deferring the subject of harmonic pencils to
+  the next section, it will suffice to state here that any transversal
+  intersects an harmonic pencil in an harmonic range. Consider the
+  pencil L(BA, NM), then it is sufficient to prove (BA', NM') is
+  harmonic. This follows from the previous theorem by considering A'B as
+  a diagonal of the quadrilateral ALB'M.]
+
+  This property of the complete quadrilateral allows the solution of the
+  problem:
+
+  _To construct the harmonic conjugate D to a point C with regard to two
+  given points A and B._
+
+  Through A draw any two lines, and through C one cutting the former two
+  in G and H. Join these points to B, cutting the former two lines in E
+  and F. The point D where EF cuts AB will be the harmonic conjugate
+  required.
+
+  This remarkable construction requires nothing but the drawing of
+  lines, and is therefore independent of measurement. In a similar
+  manner the harmonic conjugate of the line VA for two lines VC, VD is
+  constructed with the aid of the property of the complete quadrangle.
+
+  S 22. _Harmonic Pencils._--The theory of cross-ratios may be extended
+  from points in a row to lines in a flat pencil and to planes in an
+  axial pencil. We have seen (S 13) that if the lines which join four
+  points A, B, C, D to any point S be cut by any other line in A', B',
+  C', D', then (AB, CD) = (A'B', C'D'). In other words, four lines in a
+  flat pencil are cut by every other line in four points whose
+  cross-ratio is constant.
+
+  _Definition._--By the cross-ratio of four rays in a flat pencil is
+  meant the cross-ratio of the four points in which the rays are cut by
+  any line. If a, b, c, d be the lines, then this cross-ratio is denoted
+  by (ab, cd).
+
+  _Definition._--By the cross-ratio of four planes in an axial pencil is
+  understood the cross-ratio of the four points in which any line cuts
+  the planes, or, what is the same thing, the cross-ratio of the four
+  rays in which any plane cuts the four planes.
+
+  In order that this definition may have a meaning, it has to be proved
+  that all lines cut the pencil in points which have the same
+  cross-ratio. This is seen at once for two intersecting lines, as their
+  plane cuts the axial pencil in a flat pencil, which is itself cut by
+  the two lines. The cross-ratio of the four points on one line is
+  therefore equal to that on the other, and equal to that of the four
+  rays in the flat pencil.
+
+  If two non-intersecting lines p and q cut the four planes in A, B, C,
+  D and A', B', C', D', draw a line r to meet both p and q, and let this
+  line cut the planes in A", B", C", D". Then (AB, CD) = (A'B', C'D'),
+  for each is equal to (A"B", C"D").
+
+  S 23. We may now also extend the notion of harmonic elements, viz.
+
+  _Definition._--Four rays in a flat pencil and four planes in an axial
+  pencil are said to be harmonic if their cross-ratio equals -1, that
+  is, if they are cut by a line in four harmonic points.
+
+  If we understand by a "median line" of a triangle a line which joins a
+  vertex to the middle point of the opposite side, and by a "median
+  line" of a parallelogram a line joining middle points of opposite
+  sides, we get as special cases of the last theorem:
+
+  _The diagonals and median lines of a parallelogram form an harmonic
+  pencil_; and
+
+  _At a vertex of any triangle, the two sides, the median line, and the
+  line parallel to the base form an harmonic pencil._
+
+  Taking the parallelogram a rectangle, or the triangle isosceles, we
+  get:
+
+  _Any two lines and the bisections of their angles form an harmonic
+  pencil._ Or:
+
+  _In an harmonic pencil, if two conjugate rays are perpendicular, then
+  the other two are equally inclined to them_; and, conversely, _if one
+  ray bisects the angle between conjugate rays, it is perpendicular to
+  its conjugate_.
+
+  This connects perpendicularity and bisection of angles with projective
+  properties.
+
+  S 24. We add a few theorems and problems which are easily proved or
+  solved by aid of harmonics.
+
+  An harmonic pencil is cut by a line parallel to one of its rays in
+  three equidistant points.
+
+  Through a given point to draw a line such that the segment determined
+  on it by a given angle is bisected at that point.
+
+  Having given two parallel lines, to bisect on either any given segment
+  without using a pair of compasses.
+
+  Having given in a line a segment and its middle point, to draw through
+  any given point in the plane a line parallel to the given line.
+
+  To draw a line which joins a given point to the intersection of two
+  given lines which meet off the drawing paper (by aid of S 21).
+
+
+  CORRESPONDENCE. HOMOGRAPHIC AND PERSPECTIVE RANGES
+
+  S 25. Two rows, p and p', which are one the projection of the other
+  (as in fig. 5), stand in a definite relation to each other,
+  characterized by the following properties.
+
+  1. _To each point in either corresponds one point in the other_; that
+  is, those points are said to correspond which are projections of one
+  another.
+
+  2. _The cross-ratio of any four points in one equals that of the
+  corresponding points in the other._
+
+  3. _The lines joining corresponding points all pass through the same
+  point._
+
+  If we suppose corresponding points marked, and the rows brought into
+  any other position, then the lines joining corresponding points will
+  no longer meet in a common point, and hence the third of the above
+  properties will not hold any longer; but we have still a
+  correspondence between the points in the two rows possessing the first
+  two properties. Such a correspondence has been called a _one-one
+  correspondence_, whilst the two rows between which such correspondence
+  has been established are said to be _projective_ or _homographic_. Two
+  rows which are each the projection of the other are therefore
+  _projective_. We shall presently see, also, that any two projective
+  rows may always be placed in such a position that one appears as the
+  projection of the other. If they are in such a position the rows are
+  said to be in _perspective position_, or simply to be in
+  _perspective_.
+
+  S 26. The notion of a one-one correspondence between rows may be
+  extended to flat and axial pencils, viz. a flat pencil will be said to
+  be projective to a flat pencil if to each ray in the first corresponds
+  one ray in the second, and if the cross-ratio of four rays in one
+  equals that of the corresponding rays in the second.
+
+  Similarly an axial pencil may be projective to an axial pencil. But a
+  flat pencil may also be projective to an axial pencil, or either
+  pencil may be projective to a row. The definition is the same in each
+  case: there is a one-one correspondence between the elements, and four
+  elements have the same cross-ratio as the corresponding ones.
+
+  S 27. There is also in each case a special position which is called
+  _perspective_, viz.
+
+  1. Two projective rows are perspective if they lie in the same plane,
+  and if the one row is a projection of the other.
+
+  2. Two projective flat pencils are perspective--(1) if they lie in the
+  same plane, and have a row as a common section; (2) if they lie in the
+  same pencil (in space), and are both sections of the same axial
+  pencil; (3) if they are in space and have a row as common section, or
+  are both sections of the same axial pencil, one of the conditions
+  involving the other.
+
+  3. Two projective axial pencils, if their axes meet, and if they have
+  a flat pencil as a common section.
+
+  4. A row and a projective flat pencil, if the row is a section of the
+  pencil, each point lying in its corresponding line.
+
+  5. A row and a projective axial pencil, if the row is a section of the
+  pencil, each point lying in its corresponding line.
+
+  6. A flat and a projective axial pencil, if the former is a section of
+  the other, each ray lying in its corresponding plane.
+
+  That in each case the correspondence established by the position
+  indicated is such as has been called projective follows at once from
+  the definition. It is not so evident that the perspective position may
+  always be obtained. We shall show in S 30 this for the first three
+  cases. First, however, we shall give a few theorems which relate to
+  the general correspondence, not to the perspective position.
+
+  S 28. _Two rows or pencils, flat or axial, which are projective to a
+  third are projective to each other_; this follows at once from the
+  definitions.
+
+  S 29. _If two rows, or two pencils, either flat or axial, or a row and
+  a pencil, be projective, we may assume to any three elements in the
+  one the three corresponding elements in the other, and then the
+  correspondence is uniquely determined._
+
+  For if in two projective rows we assume that the points A, B, C in the
+  first correspond to the given points A', B', C' in the second, then to
+  any fourth point D in the first will correspond a point D' in the
+  second, so that
+
+    (AB, CD) = (A'B', C'D').
+
+  But there is only one point, D', which makes the cross-ratio (A'B',
+  C'D') equal to the given number (AB, CD).
+
+  The same reasoning holds in the other cases.
+
+  S 30. If two rows are perspective, then the lines joining
+  corresponding points all meet in a point, the centre of projection;
+  and the point in which the two bases of the rows intersect as a point
+  in the first row coincides with its corresponding point in the second.
+
+  This follows from the definition. The converse also holds, viz.
+
+  _If two projective rows have such a position that one point in the one
+  coincides with its corresponding point in the other, then they are
+  perspective, that is, the lines joining corresponding points all pass
+  through a common point, and form a flat pencil._
+
+  For let A, B, C, D ... be points in the one, and A', B', C', D' ...
+  the corresponding points in the other row, and let A be made to
+  coincide with its corresponding point A'. Let S be the point where the
+  lines BB' and CC' meet, and let us join S to the point D in the first
+  row. This line will cut the second row in a point D", so that A, B, C,
+  D are projected from S into the points A, B', C', D". The cross-ratio
+  (AB, CD) is therefore equal to (AB', C'D"), and by hypothesis it is
+  equal to (A'B', C'D'). Hence (A'B', C'D") = (A'B', C'D'), that is, D"
+  is the same point as D'.
+
+  S 31. If two projected flat pencils in the same plane are in
+  perspective, then the intersections of corresponding lines form a row,
+  and the line joining the two centres as a line in the first pencil
+  corresponds to the same line as a line in the second. And conversely,
+
+  _If two projective pencils in the same plane, but with different
+  centres, have one line in the one coincident with its corresponding
+  line in the other, then the two pencils are perspective, that is, the
+  intersection of corresponding lines lie in a line._
+
+  The proof is the same as in S 30.
+
+  S 32. If two projective flat pencils in the same point (pencil in
+  space), but not in the same plane, are perspective, then the planes
+  joining corresponding rays all pass through a line (they form an axial
+  pencil), and the line common to the two pencils (in which their planes
+  intersect) corresponds to itself. And conversely:--
+
+  If two flat pencils which have a common centre, but do not lie in a
+  common plane, are placed so that one ray in the one coincides with its
+  corresponding ray in the other, then they are perspective, that is,
+  the planes joining corresponding lines all pass through a line.
+
+  S 33. If two projective axial pencils are perspective, then the
+  intersection of corresponding planes lie in a plane, and the plane
+  common to the two pencils (in which the two axes lie) corresponds to
+  itself. And conversely:--
+
+  If two projective axial pencils are placed in such a position that a
+  plane in the one coincides with its corresponding plane, then the two
+  pencils are perspective, that is, corresponding planes meet in lines
+  which lie in a plane.
+
+  The proof again is the same as in S 30.
+
+  S 34. These theorems relating to perspective position become illusory
+  if the projective rows of pencils have a common base. We then have:--
+
+  In two projective rows on the same line--and also in two projective
+  and concentric flat pencils in the same plane, or in two projective
+  axial pencils with a common axis--every element in the one coincides
+  with its corresponding element in the other as soon as three elements
+  in the one coincide with their corresponding elements in the other.
+
+  _Proof_ (in case of two rows).--Between four elements A, B, C, D and
+  their corresponding elements A', B', C', D' exists the relation (ABCD)
+  = (A'B'C'D'). If now A', B', C' coincide respectively with A, B, C, we
+  get (AB, CD) = (AB, CD'), hence D and D' coincide.
+
+  The last theorem may also be stated thus:--
+
+  In two projective rows or pencils, which have a common base but are
+  not identical, not more than two elements in the one can coincide with
+  their corresponding elements in the other.
+
+  Thus two projective rows on the same line cannot have more than two
+  pairs of coincident points unless every point coincides with its
+  corresponding point.
+
+  It is easy to construct two projective rows on the same line, which
+  have two pairs of corresponding points coincident. Let the points A,
+  B, C as points belonging to the one row correspond to A, B, and C' as
+  points in the second. Then A and B coincide with their corresponding
+  points, but C does not. It is, however, not necessary that two such
+  rows have twice a point coincident with its corresponding point; it is
+  possible that this happens only once or not at all. Of this we shall
+  see examples later.
+
+  [Illustration: FIG. 9.]
+
+  S 35. If two projective rows or pencils are in perspective position,
+  we know at once which element in one corresponds to any given element
+  in the other. If p and q (fig. 9) are two projective rows, so that K
+  corresponds to itself, and if we know that to A and B in p correspond
+  A' and B' in q, then the point S, where AA' meets BB', is the centre
+  of projection, and hence, in order to find the point C' corresponding
+  to C, we have only to join C to S; the point C', where this line cuts
+  q, is the point required.
+
+  [Illustration: FIG. 10.]
+
+  If two flat pencils, S1 and S2, in a plane are perspective (fig. 10),
+  we need only to know two pairs, a, a' and b, b', of corresponding rays
+  in order to find the axis s of projection. This being known, a ray c'
+  in S2, corresponding to a given ray c in S1, is found by joining S2 to
+  the point where c cuts the axis s.
+
+  A similar construction holds in the other cases of perspective
+  figures.
+
+  On this depends the solution of the following general problem.
+
+  S 36. Three pairs of corresponding elements in two projective rows or
+  pencils being given, to determine for any element in one the
+  corresponding element in the other.
+
+  We solve this in the two cases of two projective rows and of two
+  projective flat pencils in a plane.
+
+  _Problem_ I.--Let A, B, C be          _Problem_ II.--Let a, b, c be
+  three points in a row s, A', B',      three rays in a pencil S, a',
+  C' the corresponding points in a      b', c' the corresponding rays in
+  projective row s', both being in      a projective pencil S', both
+  a plane; it is required to find       being in the same plane; it is
+  for any point D in s the              required to find for any ray d
+  corresponding point D' in s'.         in S the corresponding ray d' in
+                                        S'.
+
+  The solution is made to depend on the construction of an auxiliary row
+  or pencil which is perspective to both the given ones. This is found
+  as follows:--
+
+  [Illustration: FIG. 11.]
+
+  _Solution of Problem_ I.--On the line joining two corresponding
+  points, say AA' (fig. 11), take any two points, S and S', as centres
+  of auxiliary pencils. Join the intersection B1 of SB and S'B' to the
+  intersection C1 of SC and S'C' by the line s1. Then a row on s1 will
+  be perspective to s with S as centre of projection, and to s' with S'
+  as centre. To find now the point D' on s' corresponding to a point D
+  on s we have only to determine the point D1, where the line SD cuts
+  s1, and to draw S'D1; the point where this line cuts s' will be the
+  required point D'.
+
+  _Proof._--The rows s and s' are both perspective to the row s1, hence
+  they are projective to one another. To A, B, C, D on s correspond A1,
+  B1, C1, D1 on s1, and to these correspond A', B', C', D' on s'; so
+  that D and D' are corresponding points as required.
+
+  [Illustration: FIG. 12.]
+
+  _Solution of Problem_ II.--Through the intersection A of two
+  corresponding rays a and a' (fig. 12), take two lines, s and s', as
+  bases of auxiliary rows. Let S1 be the point where the line b1, which
+  joins B and B', cuts the line c1, which joins C and C'. Then a pencil
+  S1 will be perspective to S with s as axis of projection. To find the
+  ray d' in S' corresponding to a given ray d in S, cut d by s at D;
+  project this point from S1 to D' on s' and join D' to S'. This will be
+  the required ray.
+
+  _Proof._--That the pencil S1 is perspective to S and also to S'
+  follows from construction. To the lines a1, b1, c1, d1 in S1
+  correspond the lines a, b, c, d in S and the lines a', b', c', d' in
+  S', so that d and d' are corresponding rays.
+
+  In the first solution the two centres, S, S', are _any_ two points on
+  a line joining any two corresponding points, so that the solution of
+  the problem allows of a great many different constructions. _But
+  whatever construction be used, the point D', corresponding to D, must
+  be always the same_, according to the theorem in S 29. This gives rise
+  to a number of theorems, into which, however, we shall not enter. The
+  same remarks hold for the second problem.
+
+  S 37. _Homological Triangles._--As a further application of the
+  theorems about perspective rows and pencils we shall prove the
+  following important theorem.
+
+  _Theorem._--If ABC and A'B'C' (fig. 13) be two triangles, such that
+  the lines AA', BB', CC' meet in a point S, then the intersections of
+  BC and B'C', of CA and C'A', and of AB and A'B' will lie in a line.
+  Such triangles are said to be homological, or in perspective. The
+  triangles are "co-axial" in virtue of the property that the meets of
+  corresponding sides are collinear and copolar, since the lines joining
+  corresponding vertices are concurrent.
+
+  _Proof._--Let a, b, c denote the lines AA', BB', CC', which meet at S.
+  Then these may be taken as bases of projective rows, so that A, A', S
+  on a correspond to B, B', S on b, and to C, C', S on c. As the point S
+  is common to all, any two of these rows will be perspective.
+
+    If S1 be the centre of projection of rows b and c,
+       S2      "          "          "        c and a,
+       S3      "          "          "        a and b,
+
+  and if the line S1S2 cuts a in A1, and b in B1, and c in C1, then A1,
+  B1 will be corresponding points in a and b, both corresponding to C1
+  in c. But a and b are perspective, therefore the line A1B1, that is
+  S1S2, joining corresponding points must pass through the centre of
+  projection S3 of a and b. In other words, S1, S2, S3 lie in a line.
+  This is Desargues' celebrated theorem if we state it thus:--
+
+  [Illustration: FIG. 13.]
+
+  _Theorem of Desargues._--If each of two triangles has one vertex on
+  each of three concurrent lines, then the intersections of
+  corresponding sides lie in a line, those sides being called
+  corresponding which are opposite to vertices on the same line.
+
+  The converse theorem holds also, viz.
+
+  _Theorem._--If the sides of one triangle meet those of another in
+  three points which lie in a line, then the vertices lie on three lines
+  which meet in a point.
+
+  The proof is almost the same as before.
+
+  S 38. _Metrical Relations between Projective Rows._--Every row
+  contains one point which is distinguished from all others, viz. the
+  point at infinity. In two projective rows, to the point I at infinity
+  in one corresponds a point I' in the other, and to the point J' at
+  infinity in the second corresponds a point J in the first. The points
+  I' and J are in general finite. If now A and B are any two points in
+  the one, A', B' the corresponding points in the other row, then
+
+    (AB, JI) = (A'B', J'I'),
+
+  or
+
+    AJ/JB : AI/IB = A'J'/J'B' : A'I'/I'B'.
+
+  But, by S 17,
+
+    AI/IB = A'J'/J'B' = -1;
+
+  therefore the last equation changes into
+
+    AJ.A'I' = BJ.B'I',
+
+  that is to say--
+
+  _Theorem._--The product of the distances of any two corresponding
+  points in two projective rows from the points which correspond to the
+  points at infinity in the other is constant, viz. AJ.A'I' = k.
+  Steiner has called this number k the _Power of the correspondence_.
+
+  [The relation AJ . A'I' = k shows that if J, I' be given then the
+  point A' corresponding to a specified point A is readily found; hence
+  A, A' generate homographic ranges of which I and J' correspond to the
+  points at infinity on the ranges. If we take any two origins O, O', on
+  the ranges and reduce the expression AJ . A'I' = k to its algebraic
+  equivalent, we derive an equation of the form [alpha]xx' + [beta]x +
+  [gamma]x' + [delta] = 0. Conversely, if a relation of this nature
+  holds, then points corresponding to solutions in x, x' form
+  homographic ranges.]
+
+  S 39. _Similar Rows._--If the points at infinity in two projective
+  rows correspond so that I' and J are at infinity, this result loses
+  its meaning. But if A, B, C be any three points in one, A', B', C' the
+  corresponding ones on the other row, we have
+
+    (AB, CI) = (A'B', C'I'),
+
+  which reduces to
+
+    AC/CB = A'C'/C'B' or AC/A'C' = BC/B'C',
+
+  that is, corresponding segments are proportional. Conversely, if
+  corresponding segments are proportional, then to the point at infinity
+  in one corresponds the point at infinity in the other. If we call such
+  rows _similar_, we may state the result thus--
+
+  _Theorem._--Two projective rows are similar if to the point at
+  infinity in one corresponds the point at infinity in the other, and
+  conversely, if two rows are similar then they are projective, and the
+  points at infinity are corresponding points.
+
+  From this the well-known propositions follow:--
+
+  Two lines are cut proportionally (in similar rows) by a series of
+  parallels. The rows are perspective, with centre of projection at
+  infinity.
+
+  If two similar rows are placed parallel, then the lines joining
+  homologous points pass through a common point.
+
+  S 40. If two flat pencils be projective, then there exists in either,
+  one single pair of lines at right angles to one another, such that the
+  corresponding lines in the other pencil are again at right angles.
+
+  [Illustration: FIG. 14.]
+
+  To prove this, we place the pencils in perspective position (fig. 14)
+  by making one ray coincident with its corresponding ray. Corresponding
+  rays meet then on a line p. And now we draw the circle which has its
+  centre O on p, and which passes through the centres S and S' of the
+  two pencils. This circle cuts p in two points H and K. The two pairs
+  of rays, h, k, and h', k', joining these points to S and S' will be
+  pairs of corresponding rays at right angles. The construction gives in
+  general but one circle, but if the line p is the perpendicular
+  bisector of SS', there exists an infinite number, and _to every right
+  angle in the one pencil corresponds a right angle in the other_.
+
+
+  PRINCIPLE OF DUALITY
+
+  S 41. It has been stated in S 1 that not only points, but also planes
+  and lines, are taken as elements out of which figures are built up. We
+  shall now see that the construction of one figure which possesses
+  certain properties gives rise in many cases to the construction of
+  another figure, by replacing, according to definite rules, elements of
+  one kind by those of another. The new figure thus obtained will then
+  possess properties which may be stated as soon as those of the
+  original figure are known.
+
+  We obtain thus a principle, known as the _principle of duality_ or of
+  _reciprocity_, which enables us to construct to any figure not
+  containing any measurement in its construction a _reciprocal_ figure,
+  as it is called, and to deduce from any theorem a _reciprocal_
+  theorem, for which no further proof is needed.
+
+  It is convenient to print reciprocal propositions on opposite sides of
+  a page broken into two columns, and this plan will occasionally be
+  adopted.
+
+  We begin by repeating in this form a few of our former statements:--
+
+  Two points determine a line.        Two planes determine a line.
+
+  Three points which are not in a     Three planes which do not pass
+  line determine a plane.             through a line determine a point.
+
+  A line and a point without it       A line and a plane not through
+  determine a plane.                  it determine a point.
+
+  Two lines in a plane determine      Two lines through a point
+  a point.                            determine a plane.
+
+  These propositions show that it will be possible, when any figure is
+  given, to construct a second figure by taking planes instead of
+  points, and points instead of planes, but lines where we had lines.
+
+  For instance, if in the first figure we take a plane and three points
+  in it, we have to take in the second figure a point and three planes
+  through it. The three points in the first, together with the three
+  lines joining them two and two, form a triangle; the three planes in
+  the second and their three lines of intersection form a trihedral
+  angle. A triangle and a trihedral angle are therefore reciprocal
+  figures.
+
+  Similarly, to any figure in a plane consisting of points and lines
+  will correspond a figure consisting of planes and lines passing
+  through a point S, and hence belonging to the pencil which has S as
+  centre.
+
+  The figure reciprocal to four points in space which do not lie in a
+  plane will consist of four planes which do not meet in a point. In
+  this case each figure forms a tetrahedron.
+
+  S 42. As other examples we have the following:--
+
+  To a row                   is reciprocal  an axial pencil,
+
+  " a flat pencil                  "        a flat pencil,
+
+  " a field of points and lines    "        a pencil of planes and lines,
+
+  " the space of points            "        the space of planes.
+
+  For the row consists of a line and all the points in it, reciprocal to
+  it therefore will be a line with all planes through it, that is, an
+  axial pencil; and so for the other cases.
+
+  This correspondence of reciprocity breaks down, however, if we take
+  figures which contain measurement in their construction. For instance,
+  there is no figure reciprocal to two planes at _right angles_, because
+  there is no segment in a row which has a magnitude as definite as a
+  right angle.
+
+  We add a few examples of reciprocal propositions which are easily
+  proved.
+
+  _Theorem._--If A, B, C, D are        _Theorem._--If [alpha], [beta],
+  any four points in space, and if     [gamma], [delta] are four planes
+  the lines AB and CD meet, then       in space, and if the lines
+  all four points lie in a plane,      [alpha][beta] and [gamma][delta]
+  hence also AC and BD, as well        meet, then all four planes lie
+  as AD and BC, meet.                  in a point (pencil), hence also
+                                       [alpha][gamma] and [beta][delta],
+                                       well as [alpha][delta] and
+                                       as [beta][gamma], meet.
+
+  Theorem.--_If of any number of lines every one meets every other,
+  whilst all do not_
+
+  _lie in a point, then all lie in     _lie in a plane, then all lie in
+  a plane._                            a point (pencil)._
+
+  S 43. Reciprocal figures as explained lie both in space of three
+  dimensions. If the one is confined to a plane (is formed of elements
+  which lie in a plane), then the reciprocal figure is confined to a
+  pencil (is formed of elements which pass through a point).
+
+  But there is also a more special principle of duality, according to
+  which figures are reciprocal which lie both in a plane or both in a
+  pencil. In the plane we take points and lines as reciprocal elements,
+  for they have this fundamental property in common, that two elements
+  of one kind determine one of the other. In the pencil, on the other
+  hand, lines and planes have to be taken as reciprocal, and here it
+  holds again that two lines or planes determine one plane or line.
+
+  Thus, to one plane figure we can construct one reciprocal figure in
+  the plane, and to each one reciprocal figure in a pencil. We mention a
+  few of these. At first we explain a few names:--
+
+  A figure consisting of n points     A figure consisting of n lines
+  in a plane will be called an        in a plane will be called an
+  n-point.                            n-side.
+
+  A figure consisting of n planes     A figure consisting of n lines
+  in a pencil will be called an       in a pencil will be called an
+  n-flat.                             n-edge.
+
+  It will be understood that an n-side is different from a polygon of n
+  sides. The latter has sides of finite length and n vertices, the
+  former has sides all of infinite extension, and every point where two
+  of the sides meet will be a vertex. A similar difference exists
+  between a solid angle and an n-edge or an n-flat. We notice
+  particularly--
+
+  A four-point has six sides, of      A four-side has six vertices, of
+  which two and two are opposite,     which two and two are opposite,
+  and three diagonal points, which    and three diagonals, which join
+  are intersections of opposite       opposite vertices.
+  sides.
+
+  A four-flat has six edges, of       A four-edge has six faces, of
+  which two and two are opposite,     which two and two are opposite,
+  and three diagonal planes, which    and three diagonal edges, which
+  pass through opposite edges.        are intersections of opposite
+                                      faces.
+
+  A four-side is usually called a complete quadrilateral, and a
+  four-point a complete quadrangle. The above notation, however, seems
+  better adapted for the statement of reciprocal propositions.
+
+  S 44.
+
+  If a point moves in a plane it      If a line moves in a plane it
+  describes a plane curve.            envelopes a plane curve (fig. 15).
+
+  If a plane moves in a pencil it     If a line moves in a pencil it
+  envelopes a cone.                   describes a cone.
+
+  A curve thus appears as generated either by points, and then we call
+  it a "locus," or by lines, and then we call it an "envelope." In the
+  same manner a cone, which means here a surface, appears either as the
+  locus of lines passing through a fixed point, the "vertex" of the
+  cone, or as the envelope of planes passing through the same point.
+
+  [Illustration: FIG. 15.]
+
+  To a surface as locus of points corresponds, in the same manner, a
+  surface as envelope of planes; and to a curve in space as locus of
+  points corresponds a developable surface as envelope of planes.
+
+  It will be seen from the above that we may, by aid of the principle of
+  duality, construct for every figure a reciprocal figure, and that to
+  any property of the one a reciprocal property of the other will exist,
+  as long as we consider only properties which depend upon nothing but
+  the positions and intersections of the different elements and not upon
+  measurement.
+
+  For such propositions it will therefore be unnecessary to prove more
+  than one of two reciprocal theorems.
+
+
+  GENERATION OF CURVES AND CONES OF SECOND ORDER OR SECOND CLASS
+
+  S 45. _Conics._--If we have two projective pencils in a plane,
+  corresponding rays will meet, and their point of intersection will
+  constitute some locus which we have to investigate. Reciprocally, if
+  two projective rows in a plane are given, then the lines which join
+  corresponding points will envelope some curve. We prove first:--
+
+  _Theorem._--If two projective       _Theorem._--If two projective
+  flat pencils lie in a plane, but    rows lie in a plane, but are
+  are neither in perspective nor      neither in perspective nor on a
+  concentric, then the locus of       common base, then the envelope
+  intersections of corresponding      of lines joining corresponding
+  rays is a curve of the second       points is a curve of the second
+  order, that is, no line contains    class, that is, through no point
+  more than two points of the         pass more than two of the
+  locus.                              enveloping lines.
+
+  Proof.--We draw any line t.         _Proof._--We take any point T
+  This cuts each of the pencils in    and join it to all points in each
+  a row, so that we have on t two     row. This gives two concentric
+  rows, and these are projective      pencils, which are projective
+  because the pencils are             because the rows are projective.
+  projective. If corresponding rays   If a line joining corresponding
+  of the two pencils meet on the      points in the two rows passes
+  line t, their intersection will     through T, it will be a line in
+  be a point in the one row which     the one pencil which coincides
+  coincides with its corresponding    with its corresponding line in
+  point in the other. But two         the other. But two projective
+  projective rows on the same base    concentric flat pencils in the
+  cannot have more than two           same plane cannot have more than
+  points of one coincident with       two lines of one coincident with
+  their corresponding points in       their corresponding line in the
+  the other (S 34).                   other (S 34).
+
+  It will be seen that the proofs are reciprocal, so that the one may be
+  copied from the other by simply interchanging the words point and
+  line, locus and envelope, row and pencil, and so on. We shall
+  therefore in future prove seldom more than one of two reciprocal
+  theorems, and often state one theorem only, the reader being
+  recommended to go through the reciprocal proof by himself, and to
+  supply the reciprocal theorems when not given.
+
+  S 46. We state the theorems in the pencil reciprocal to the last,
+  without proving them:--
+
+  _Theorem._--If two projective       _Theorem._--If two projective
+  flat pencils are concentric, but    axial pencils lie in the same
+  are neither perspective nor         pencil (their axes meet in a
+  coplanar, then the envelope of      point), but are neither perspective
+  the planes joining corresponding    nor co-axial, then the locus
+  rays is a cone of the second        of lines joining corresponding
+  class; that is, no line through     planes is a cone of the second
+  the common centre contains more     order; that is, no plane in the
+  than two of the enveloping          pencil contains more than two
+  planes.
+
+  S 47. Of theorems about cones of second order and cones of second
+  class we shall state only very few. We point out, however, the
+  following connexion between the curves and cones under consideration:
+
+  The lines which join any point      Every plane section of a cone
+  in space to the points on a curve   of the second order is a curve of
+  of the second order form a cone     the second order.
+  of the second order.
+
+  The planes which join any           Every plane section of a cone
+  point in space to the lines         of the second class is a curve of
+  enveloping a curve of the           the second class.
+  second class envelope themselves
+  a cone of the second class.
+
+  By its aid, or by the principle of duality, it will be easy to obtain
+  theorems about them from the theorems about the curves.
+
+  We prove the first. A curve of the second order is generated by two
+  projective pencils. These pencils, when joined to the point in space,
+  give rise to two projective axial pencils, which generate the cone in
+  question as the locus of the lines where corresponding planes meet.
+
+  S48.
+
+  _Theorem._--The curve of second    _Theorem._--The envelope of
+  order which is generated by two    second class which is generated
+  projective flat pencils passes     by two projective rows contains
+  through the centres of the two     the bases of these rows as
+  pencils.                           enveloping lines or tangents.
+
+  _Proof._--If S and S' are the      _Proof._--If s and s' are the
+  two pencils, then to the ray SS'   two rows, then to the point ss'
+  or p' in the pencil S'             or P' as a point in s'
+  corresponds in the pencil S a      corresponds in s a point P,
+  ray p, which is different from     which is not coincident with P',
+  p', for the pencils are not        for the rows are not
+  perspective. But p and p' meet     perspective. But P and P' are
+  at S, so that S is a point on      joined by s, so that s is one of
+  the curve, and similarly S'.       the enveloping lines, and
+                                     similarly s'.
+
+  It follows that every line in one of the two pencils cuts the curve in
+  two points, viz. once at the centre S of the pencil, and once where it
+  cuts its corresponding ray in the other pencil. These two points,
+  however, coincide, if the line is cut by its corresponding line at S
+  itself. The line p in S, which corresponds to the line SS' in S', is
+  therefore the only line through S which has but one point in common
+  with the curve, or which cuts the curve in two coincident points. Such
+  a line is called a _tangent_ to the curve, touching the latter at the
+  point S, which is called the "point of contact."
+
+  In the same manner we get in the reciprocal investigation the result
+  that through every point in one of the rows, say in s, two tangents
+  may be drawn to the curve, the one being s, the other the line joining
+  the point to its corresponding point in s'. There is, however, one
+  point P in s for which these two lines coincide. Such a point in one
+  of the tangents is called the "point of contact" of the tangent. We
+  thus get--
+
+  _Theorem._--To the line joining    _Theorem._--To the point of
+  the centres of the projective      intersection of the bases of two
+  pencils as a line in one pencil    projective rows as a point in
+  corresponds in the other the       one row corresponds in the other
+  tangent at its centre.             the _point of contact_ of its
+                                     base.
+
+  S 49. Two projective pencils are determined if three pairs of
+  corresponding lines are given. Hence if a1, b1, c1 are three lines in
+  a pencil S1, and a2, b2, c2 the corresponding lines in a projective
+  pencil S2, the correspondence and therefore the curve of the second
+  order generated by the points of intersection of corresponding rays is
+  determined. Of this curve we know the two centres S1 and S2, and the
+  three points a1a2, b1b2, c1c2, hence five points in all. This and the
+  reciprocal considerations enable us to solve the following two
+  problems:
+
+  _Problem._--To construct a curve   _Problem._--To construct a curve
+  of the second order, of which      of the second class, of which
+  five points S1, S2, A, B, C are    five tangents u1, u2, a, b, c
+  given.                             are given.
+
+  In order to solve the left-hand problem, we take two of the given
+  points, say S1 and S2, as centres of pencils. These we make projective
+  by taking the rays a1, b1, c1, which join S1 to A, B, C respectively,
+  as corresponding to the rays a2, b2, c2, which join S2 to A, B, C
+  respectively, so that three rays meet their corresponding rays at the
+  given points A, B, C. This determines the correspondence of the
+  pencils which will generate a curve of the second order passing
+  through A, B, C and through the centres S1 and S2, hence through the
+  five given points. To find more points on the curve we have to
+  construct for any ray in S1 the corresponding ray in S2. This has been
+  done in S 36. But we repeat the construction in order to deduce
+  further properties from it. We also solve the right-hand problem. Here
+  we select two, viz. u1, u2 of the five given lines, u1, u2, a, b, c,
+  as bases of two rows, and the points A1, B1, C1 where a, b, c cut u1
+  as corresponding to the points A2, B2, C2 where a, b, c cut u2.
+
+  We get then the following solutions of the two problems:
+
+  _Solution._--Through the point A   _Solution._--In the line a take
+  draw any two lines, u1 and u2      any two points S1 and S2 as
+  (fig. 16), the first u1 to cut     centres of pencils (fig. 17),
+  the pencil S1 in a row AB1C1,      the first S1 (A1B1C1) to project
+  the other u2 to cut the pencil     the row u1, the other S2
+  S2 in a row AB2C2. These two       (A2B2C2) to project the row u2.
+  rows will be perspective, as the   These two pencils will be
+  point A corresponds to itself,     perspective, the line S1A1 being
+  and the centre of projection       the same as the corresponding
+  will be the point S, where the     line S2A2, and the axis of
+  lines B1B2 and C1C2 meet. To       projection will be the line u,
+  find now for any ray d1 in S1      which joins the intersection B
+  its corresponding ray d2 in S2,    of S1B1 and S2B2 to the
+  we determine the point D1 where    intersection C of S1C1 and S2C2.
+  d1 cuts u1, project this point     To find now for any point D1 in
+  from S to D2 on u2 and join S2     u1 the corresponding point D2 in
+  to D2. This will be the required   u2, we draw S1D1 and project the
+  ray d2 which cuts d1 at some       point D where this line cuts u
+  point D on the curve.              from S2 to u2. This will give
+                                     the required point D2, and the
+                                     line d joining D1 to D2 will be
+                                     a new tangent to the curve.
+
+  S 50. These constructions prove, when rightly interpreted, very
+  important properties of the curves in question.
+
+  [Illustration: FIG. 16.]
+
+  If in fig. 16 we draw in the pencil S1 the ray k1 which passes through
+  the auxiliary centre S, it will be found that the corresponding ray k2
+  cuts it on u2. Hence--
+
+  _Theorem._--In the above           _Theorem._--In the above
+  construction the bases of the      construction (fig. 17) the
+  auxiliary rows u1 and u2 cut the   tangents to the curve from the
+  curve where they cut the rays      centres of the auxiliary pencils
+  S2S and S1S respectively.          S1 and S2 are the lines which
+                                     pass through u2u and u1u
+                                     respectively.
+
+  As A is any given point on the curve, and u1 any line through it, we
+  have solved the problems:
+
+  _Problem._--To find the second     _Problem._--To find the second
+  point in which any line through    tangent which can be drawn from
+  a known point on the curve cuts    any point in a given tangent to
+  the curve.                         the curve.
+
+  If we determine in S1 (fig. 16) the ray corresponding to the ray S2S1
+  in S2, we get the tangent at S1. Similarly, we can determine the point
+  of contact of the tangents u1 or u2 in fig. 17.
+
+  [Illustration: FIG. 17.]
+
+  S 51. If five points are given, of which not three are in a line, then
+  we can, as has just been shown, always draw a curve of the second
+  order through them; we select two of the points as centres of
+  projective pencils, and then one such curve is determined. It will be
+  presently shown that we get always the same curve if two other points
+  are taken as centres of pencils, that therefore five points
+  _determine_ one curve of the second order, and reciprocally, that five
+  tangents determine one curve of the second class. Six points taken at
+  random will therefore not lie on a curve of the second order. In order
+  that this may be the case a certain condition has to be satisfied, and
+  this condition is easily obtained from the construction in S 49, fig.
+  16. If we consider the conic determined by the five points A, S1, S2,
+  K, L, then the point D will be on the curve if, and only if, the
+  points on D1, S, D2 be in a line.
+
+  [Illustration: FIG. 18.]
+
+  This may be stated differently if we take AKS1DS2L (figs. 16 and 18)
+  as a hexagon inscribed in the conic, then AK and DS2 will be opposite
+  sides, so will be KS1 and S2L, as well as S1D and LA. The first two
+  meet in D2, the others in S and D1 respectively. We may therefore
+  state the required condition, together with the reciprocal one, as
+  follows:--
+
+  _Pascal's Theorem._--If a hexagon  _Brianchon's Theorem._--If a
+  be inscribed in a curve of the     hexagon be circumscribed about
+  second order, then the             a curve of the second class, then
+  intersectionsof opposite sides     the lines joining opposite vertices
+  are three points in a line.        are three lines meeting in a point.
+
+  These celebrated theorems, which are known by the names of their
+  discoverers, are perhaps the most fruitful in the whole theory of
+  conics. Before we go over to their applications we have to show that
+  we obtain the same curve if we take, instead of S1, S2, any two other
+  points on the curve as centres of projective pencils.
+
+  S 52. We know that the curve depends only upon the correspondence
+  between the pencils S1 and S2, and not upon the special construction
+  used for finding new points on the curve. The point A (fig. 16 or 18),
+  through which the two auxiliary rows u1, u2 were drawn, may therefore
+  be changed to any other point on the curve. Let us now suppose the
+  curve drawn, and keep the points S1, S2, K, L and D, and hence also
+  the point S fixed, whilst we move A along the curve. Then the line AL
+  will describe a pencil about L as centre, and the point D1 a row on
+  S1D perspective to the pencil L. At the same time AK describes a
+  pencil about K and D2 a row perspective to it on S2D. But by Pascal's
+  theorem D1 and D2 will always lie in a line with S, so that the rows
+  described by D1 and D2 are perspective. It follows that the pencils K
+  and L will themselves be projective, corresponding rays meeting on the
+  curve. This proves that we get the same curve whatever pair of the
+  five given points we take as centres of projective pencils. Hence--
+
+  Only one curve of the second       Only one curve of the second
+  order can be drawn which passes    class can be drawn which touches
+  through five given points.         five given lines.
+
+  We have seen that if on a curve of the second order two points
+  coincide at A, the line joining them becomes the tangent at A. If,
+  therefore, a point on the curve and its tangent are given, this will
+  be equivalent to having given two points on the curve. Similarly, if
+  on the curve of second class a tangent and its point of contact are
+  given, this will be equivalent to two given tangents.
+
+  We may therefore extend the last theorem:
+
+  Only one curve of the second       Only one curve of the second
+  order can be drawn, of which       class can be drawn, of which four
+  four points and the tangent at     tangents and the point of contact
+  oneof them, or three points        at one of them, or three tangents
+  and the tangents at two of         and the points of contact at two
+  them, are given.                   of them, are given.
+
+  S 53. At the same time it has been proved:
+
+  If all points on a curve of the    All tangents to a curve of second
+  second order be joined to any      class are cut by any two of
+  two of them, then the two          them in projective rows, those
+  pencils thus formed are            being corresponding points which
+  projective, those rays being       lie on the same tangent. Hence--
+  corresponding which meet on the
+  curve. Hence--
+
+  The cross-ratio of four rays       The cross-ratio of the four
+  joining a point S on a curve of    points in which any tangent u is
+  second order to four fixed         cut by four fixed tangents a, b, c,
+  points A, B, C, D in the curve     d is independent of the position of
+  is independent of the position     u, and is called the cross-ratio of
+  of S, and is called the cross-     the four tangents a, b, c, d.
+  ratio of the four points A, B,
+  C, D.
+
+  If this cross-ratio equals -1     If this cross-ratio equals -1
+  the four points are said to be    the four tangents are said to be
+  four harmonic points.             four harmonic tangents.
+
+  We have seen that a curve of second order, as generated by projective
+  pencils, has at the centre of each pencil one tangent; and further,
+  that any point on the curve may be taken as centre of such pencil.
+  Hence--
+
+  A curve of second order has       A curve of second class has on
+  at every point one tangent.       every tangent a point of contact.
+
+  S 54. We return to Pascal's and Brianchon's theorems and their
+  applications, and shall, as before, state the results both for curves
+  of the second order and curves of the second class, but prove them
+  only for the former.
+
+  Pascal's theorem may be used when five points are given to find more
+  points on the curve, viz. it enables us to find the point where any
+  line through one of the given points cuts the curve again. It is
+  convenient, in making use of Pascal's theorem, to number the points,
+  to indicate the order in which they are to be taken in forming a
+  hexagon, which, by the way, may be done in 60 different ways. It will
+  be seen that 1 2 (leaving out 3) 4 5 are opposite sides, so are 2 3
+  and (leaving out 4) 5 6, and also 3 4 and (leaving out 5) 6 1.
+
+  If the points 1 2 3 4 5 are given, and we want a 6th point on a line
+  drawn through 1, we know all the sides of the hexagon with the
+  exception of 5 6, and this is found by Pascal's theorem.
+
+  If this line should happen to pass through 1, then 6 and 1 coincide,
+  or the line 6 1 is the tangent at 1. And always if two consecutive
+  vertices of the hexagon approach nearer and nearer, then the side
+  joining them will ultimately become a tangent.
+
+  We may therefore consider a pentagon inscribed in a curve of second
+  order and the tangent at one of its vertices as a hexagon, and thus
+  get the theorem:
+
+  Every pentagon inscribed in a      Every pentagon circumscribed
+  curve of second order has the      about a curve of the second class
+  property that the intersections    has the property that the lines
+  of two pairs of non-consecutive    which join two pairs of non-
+  sides lie in a line with the       consecutive vertices meet on that
+  point where the fifth side cuts    line which joins the fifth vertex
+  the tangent at the opposite        to the point of contact of the
+  vertex.                            opposite side.
+
+  This enables us also to solve the following problems.
+
+  Given five points on a curve of    Given five tangents to a curve
+  second order to construct the      of second class to construct the
+  tangent at any one of them.        point of contact of any one of
+                                     them.
+
+  [Illustration: FIG. 19.]
+
+  If two pairs of adjacent vertices coincide, the hexagon becomes a
+  quadrilateral, with tangents at two vertices. These we take to be
+  opposite, and get the following theorems:
+
+  If a quadrilateral be inscribed    If a quadrilateral be circumscribed
+  in a curve of second order, the    about a curve of second
+  intersections of opposite sides,   class, the lines joining opposite
+  and also the intersections of      vertices, and also the lines joining
+  the tangents at opposite           points of contact of opposite
+  vertices, lie in a line (fig.      sides, meet in a point.
+  19).
+
+  [Illustration: FIG. 20.]
+
+  If we consider the hexagon made up of a triangle and the tangents at
+  its vertices, we get--
+
+  If a triangle is inscribed in a    If a triangle be circumscribed
+  curve of the second order, the     about a curve of second class,
+  points in which the sides are      the lines which join the vertices
+  cut by the tangents at the         to the points of contact of the
+  opposite vertices meet in a        opposite sides meet in a point
+  point.                             (fig. 20).
+
+  S 55. Of these theorems, those about the quadrilateral give rise to a
+  number of others. Four points A, B, C, D may in three different ways
+  be formed into a quadrilateral, for we may take them in the order
+  ABCD, or ACBD, or ACDB, so that either of the points B, C, D may be
+  taken as the vertex opposite to A. Accordingly we may apply the
+  theorem in three different ways.
+
+  Let A, B, C, D be four points on a curve of second order (fig. 21),
+  and let us take them as forming a quadrilateral by taking the points
+  in the order ABCD, so that A, C and also B, D are pairs of opposite
+  vertices. Then P, Q will be the points where opposite sides meet, and
+  E, F the intersections of tangents at opposite vertices. The four
+  points P, Q, E, F lie therefore in a line. The quadrilateral ACBD
+  gives us in the same way the four points Q, R, G, H in a line, and the
+  quadrilateral ABDC a line containing the four points R, P, I, K. These
+  three lines form a triangle PQR.
+
+  The relation between the points and lines in this figure may be
+  expressed more clearly if we consider ABCD as a four-point inscribed
+  in a conic, and the tangents at these points as a four-side
+  circumscribed about it,--viz. it will be seen that P, Q, R are the
+  diagonal points of the four-point ABCD, whilst the sides of the
+  triangle PQR are the diagonals of the circumscribing four-side. Hence
+  the theorem--
+
+  _Any four-point on a curve of the second order and the four-side
+  formed by the tangents at these points stand in this relation that the
+  diagonal points of the four-point lie in the diagonals of the
+  four-side._ And conversely,
+
+  _If a four-point and a circumscribed four-side stand in the above
+  relation, then a curve of the second order may be described which
+  passes through the four points and touches there the four sides of
+  these figures._
+
+  That the last part of the theorem is true follows from the fact that
+  the four points A, B, C, D and the line a, as tangent at A, determine
+  a curve of the second order, and the tangents to this curve at the
+  other points B, C, D are given by the construction which leads to fig.
+  21.
+
+  [Illustration: FIG. 21.]
+
+  The theorem reciprocal to the last is--
+
+  _Any four-side circumscribed about a curve of second class and the
+  four-point formed by the points of contact stand in this relation that
+  the diagonals of the four-side pass through the diagonal points of the
+  four-point._ And conversely,
+
+  _If a four-side and an inscribed four-point stand in the above
+  relation, then a curve of the second class may be described which
+  touches the sides of the four-side at the points of the four-point._
+
+  S 56. The four-point and the four-side in the two reciprocal theorems
+  are alike. Hence if we have a four-point ABCD and a four-side abcd
+  related in the manner described, then not only may a curve of the
+  second order be drawn, but also a curve of the second class, which
+  both touch the lines a, b, c, d at the points A, B, C, D.
+
+  The curve of second order is already more than determined by the
+  points A, B, C and the tangents a, b, c at A, B and C. The point D may
+  therefore be _any_ point on this curve, and d any tangent to the
+  curve. On the other hand the curve of the second class is more than
+  determined by the three tangents a, b, c and their points of contact
+  A, B, C, so that d is any tangent to this curve. It follows that every
+  tangent to the curve of second order is a tangent of a curve of the
+  second class having the same point of contact. In other words, the
+  curve of second order is a curve of second class, and _vice versa_.
+  Hence the important theorems--
+
+  _Every curve of second order is    _Every curve of second class is a
+  a curve of second class._          curve of second order._
+
+  The curves of second order and of second class, having thus been
+  proved to be identical, shall henceforth be called by the common name
+  of _Conics_.
+
+  For these curves hold, therefore, all properties which have been
+  proved for curves of second order or of second class. We may therefore
+  now state Pascal's and Brianchon's theorem thus--
+
+  _Pascal's Theorem._--If a hexagon be inscribed in a conic, then the
+  intersections of opposite sides lie in a line.
+
+  _Brianchon's Theorem._--If a hexagon be circumscribed about a conic,
+  then the diagonals forming opposite centres meet in a point.
+
+  S 57. If we suppose in fig. 21 that the point D together with the
+  tangent d moves along the curve, whilst A, B, C and their tangents a,
+  b, c remain fixed, then the ray DA will describe a pencil about A, the
+  point Q a projective row on the fixed line BC, the point F the row b,
+  and the ray EF a pencil about E. But EF passes always through Q. Hence
+  the pencil described by AD is projective to the pencil described by
+  EF, and therefore to the row described by F on b. At the same time the
+  line BD describes a pencil about B projective to that described by AD
+  (S 53). Therefore the pencil BD and the row F on b are projective.
+  Hence--
+
+  _If on a conic a point A be taken and the tangent a at this point,
+  then the cross-ratio of the four rays which join A to any four points
+  on the curve is equal to the cross-ratio of the points in which the
+  tangents at these points cut the tangent at A._
+
+  S 58. There are theorems about cones of second order and second class
+  in a pencil which are reciprocal to the above, according to S 43. We
+  mention only a few of the more important ones.
+
+  The locus of intersections of corresponding planes in two projective
+  axial pencils whose axes meet is a cone of the second order.
+
+  The envelope of planes which join corresponding lines in two
+  projective flat pencils, not in the same plane, is a cone of the
+  second class.
+
+  Cones of second order and cones of second class are identical.
+
+  Every plane cuts a cone of the second order in a conic.
+
+  _A cone of second order is uniquely determined by five of its edges or
+  by five of its tangent planes, or by four edges and the tangent plane
+  at one of them, &c. &c._
+
+  _Pascal's Theorem._--If a solid angle of six faces be inscribed in a
+  cone of the second order, then the intersections of opposite faces are
+  three lines in a plane.
+
+  _Brianchon's Theorem._--If a solid angle of six edges be circumscribed
+  about a cone of the second order, then the planes through opposite
+  edges meet in a line.
+
+  Each of the other theorems about conics may be stated for cones of the
+  second order.
+
+  S 59. _Projective Definitions of the Conics._--We now consider the
+  shape of the conics. We know that any line in the plane of the conic,
+  and hence that the line at infinity, either has no point in common
+  with the curve, or one (counting for two coincident points) or two
+  distinct points. If the line at infinity has no point on the curve the
+  latter is altogether finite, and is called an _Ellipse_ (fig. 21). If
+  the line at infinity has only one point in common with the conic, the
+  latter extends to infinity, and has the line at infinity a tangent. It
+  is called a _Parabola_ (fig. 22). If, lastly, the line at infinity
+  cuts the curve in two points, it consists of two separate parts which
+  each extend in two branches to the points at infinity where they meet.
+  The curve is in this case called an _Hyperbola_ (see fig. 20). The
+  tangents at the two points at infinity are finite because the line at
+  infinity is not a tangent. They are called _Asymptotes_. The branches
+  of the hyperbola approach these lines indefinitely as a point on the
+  curves moves to infinity.
+
+  [Illustration: FIG. 22.]
+
+  S 60. That the circle belongs to the curves of the second order is
+  seen at once if we state in a slightly different form the theorem that
+  in a circle all angles at the circumference standing upon the same arc
+  are equal. If two points S1, S2 on a circle be joined to any other two
+  points A and B on the circle, then the angle included by the rays S1A
+  and S1B is equal to that between the rays S2A and S2B, so that as A
+  moves along the circumference the rays S1A and S2A describe equal and
+  therefore projective pencils. The circle can thus be generated by two
+  projective pencils, and is a curve of the second order.
+
+  If we join a point in space to all points on a circle, we get a
+  (circular) cone of the second order (S 43). Every plane section of
+  this cone is a conic. This conic will be an ellipse, a parabola, or an
+  hyperbola, according as the line at infinity in the plane has no, one
+  or two points in common with the conic in which the plane at infinity
+  cuts the cone. It follows that our curves of second order may be
+  obtained as sections of a circular cone, and that they are identical
+  with the "Conic Sections" of the Greek mathematicians.
+
+  S 61. Any two tangents to a parabola are cut by all others in
+  projective rows; but the line at infinity being one of the tangents,
+  the points at infinity on the rows are corresponding points, and the
+  rows therefore similar. Hence the theorem--
+
+  _The tangents to a parabola cut each other proportionally._
+
+
+  POLE AND POLAR
+
+  S 62. We return once again to fig. 21, which we obtained in S 55.
+
+  If a four-side be circumscribed about and a four-point inscribed in a
+  conic, so that the vertices of the second are the points of contact of
+  the sides of the first, then the triangle formed by the diagonals of
+  the first is the same as that formed by the diagonal points of the
+  other.
+
+  Such a triangle will be called a _polar-triangle_ of the conic, so
+  that PQR in fig. 21 is a polar-triangle. It has the property that on
+  the side p opposite P meet the tangents at A and B, and also those at
+  C and D. From the harmonic properties of four-points and four-sides it
+  follows further that the points L, M, where it cuts the lines AB and
+  CD, are harmonic conjugates with regard to AB and CD respectively.
+
+  If the point P is given, and we draw a line through it, cutting the
+  conic in A and B, then the point Q harmonic conjugate to P with regard
+  to AB, and the point H where the tangents at A and B meet, are
+  determined. But they lie both on p, and therefore this line is
+  determined. If we now draw a second line through P, cutting the conic
+  in C and D, then the point M harmonic conjugate to P with regard to
+  CD, and the point G where the tangents at C and D meet, must also lie
+  on p. As the first line through P already determines p, the second may
+  be any line through P. Now every two lines through P determine a
+  four-point ABCD on the conic, and therefore a polar-triangle which has
+  one vertex at P and its opposite side at p. This result, together with
+  its reciprocal, gives the theorems--
+
+  _All polar-triangles which have one vertex in common have also the
+  opposite side in common._
+
+  _All polar-triangles which have one side in common have also the
+  opposite vertex in common._
+
+  S 63. To any point P in the plane of, but not on, a conic corresponds
+  thus one line p as the side opposite to P in all polar-triangles which
+  have one vertex at P, and reciprocally to every line p corresponds one
+  point P as the vertex opposite to p in all triangles which have p as
+  one side.
+
+  We call the line p the _polar_ of P, and the point P the _pole_ of the
+  line p with regard to the conic.
+
+  If a point lies on the conic, we call the tangent at that point its
+  polar; and reciprocally we call the point of contact the pole of
+  tangent.
+
+  S 64. From these definitions and former results follow--
+
+  The polar of any point P not       The pole of any line p not a
+  on the conic is a line p, which    tangent to the conic is a point
+  has the following properties:--    P, which has the following
+                                     properties:--
+
+  1. On every line through P         1. Of all lines through a point
+  which cuts the conic, the polar    on p from which two tangents
+  of P contains the harmonic         may be drawn to the conic, the
+  conjugate  of P with regard to     pole P contains the line which is
+  those points on the conic.         harmonic conjugate to p, with
+                                     regard to the two tangents.
+
+  2. If tangents can be drawn        2. If p cuts the conic, the
+  from P, their points of contact    tangents at the intersections
+  lie on p.                          meet at P.
+
+  3. Tangents drawn at the           3. The point of contact of
+  points where any line through P    tangents drawn from any point
+  cuts the conic meet on p; and      on p to the conic lie in a line
+  conversely,                        with P; and conversely,
+
+  4. If from any point on p,         4. Tangents drawn at points
+  tangents be drawn, their points    where any line through P cuts the
+  of contact will lie in a line      conic meet on p.
+  with P.
+
+  5. Any four-point on the conic     5. Any four-side circumscribed
+  which has one diagonal point at    about a conic which has one
+  P has the other two lying on p.    diagonal on p has the other two
+                                     meeting at P.
+
+  The truth of 2 follows from 1. If T be a point where p cuts the conic,
+  then one of the points where PT cuts the conic, and which are harmonic
+  conjugates with regard to PT, coincides with T; hence the other
+  does--that is, PT touches the curve at T.
+
+  That 4 is true follows thus: If we draw from a point H on the polar
+  one tangent a to the conic, join its point of contact A to the pole P,
+  determine the second point of intersection B of this line with the
+  conic, and draw the tangent at B, it will pass through H, and will
+  therefore be the second tangent which may be drawn from H to the
+  curve.
+
+  S 65. The second property of the polar or pole gives rise to the
+  theorem--
+
+  From a point in the plane of a     A line in the plane of a conic
+  conic, two, one or no tangents     has two, one or no points in
+  may be drawn to the conic,         common with the conic, according
+  as its polar has two,              as two, one or no tangents
+  one, or no points in common        can be drawn from its pole to the
+  with the curve.                    conic.
+
+  Of any point in the plane of a conic we say that it was _without_, on
+  or _within_ the curve according as two, one or no tangents to the
+  curve pass through it. The points on the conic separate those within
+  the conic from those without. That this is true for a circle is known
+  from elementary geometry. That it also holds for other conics follows
+  from the fact that every conic may be considered as the projection of
+  a circle, which will be proved later on.
+
+  The fifth property of pole and polar stated in S 64 shows how to find
+  the polar of any point and the pole of any line by aid of the
+  straight-edge only. Practically it is often convenient to draw three
+  secants through the pole, and to determine only one of the diagonal
+  points for two of the four-points formed by pairs of these lines and
+  the conic (fig. 22).
+
+  These constructions also solve the problem--
+
+  From a point without a conic, to draw the two tangents to the conic by
+  aid of the straight-edge only.
+
+  For we need only draw the polar of the point in order to find the
+  points of contact.
+
+  S 66. The property of a polar-triangle may now be stated thus--
+
+  In a polar-triangle each side is the polar of the opposite vertex, and
+  each vertex is the pole of the opposite side.
+
+  [Illustration: FIG. 23.]
+
+  If P is one vertex of a polar-triangle, then the other vertices, Q and
+  R, lie on the polar p of P. One of these vertices we may choose
+  arbitrarily. For if from any point Q on the polar a secant be drawn
+  cutting the conic in A and D (fig. 23), and if the lines joining these
+  points to P cut the conic again at B and C, then the line BC will pass
+  through Q. Hence P and Q are two of the vertices on the polar-triangle
+  which is determined by the four-point ABCD. The third vertex R lies
+  also on the line p. It follows, therefore, also--
+
+  _If Q is a point on the polar of P, then P is a point on the polar of
+  Q_; and reciprocally,
+
+  _If q is a line through the pole of p, then p is a line through the
+  pole of q._
+
+  This is a very important theorem. It may also be stated thus--
+
+  _If a point moves along a line describing a row, its polar turns about
+  the pole of the line describing a pencil._
+
+  _This pencil is projective to the row, so that the cross-ratio of four
+  poles in a row equals the cross-ratio of its four polars, which pass
+  through the pole of the row._
+
+  To prove the last part, let us suppose that P, A and B in fig. 23
+  remain fixed, whilst Q moves along the polar p of P. This will make CD
+  turn about P and move R along p, whilst QD and RD describe projective
+  pencils about A and B. Hence Q and R describe projective rows, and
+  hence PR, which is the polar of Q, describes a pencil projective to
+  either.
+
+  S 67. Two points, of which one, and therefore each, lies on the polar
+  of the other, are said to be _conjugate with regard to the conic_; and
+  two lines, of which one, and therefore each, passes through the pole
+  of the other, are said to be _conjugate with regard to the conic_.
+  Hence all points conjugate to a point P lie on the polar of P; all
+  lines conjugate to a line p pass through the pole of p.
+
+  If the line joining two conjugate poles cuts the conic, then the poles
+  are harmonic conjugates with regard to the points of intersection;
+  hence one lies within the other without the conic, and all points
+  conjugate to a point within a conic lie without it.
+
+  Of a polar-triangle any two vertices are conjugate poles, any two
+  sides conjugate lines. If, therefore, one side cuts a conic, then one
+  of the two vertices which lie on this side is within and the other
+  without the conic. The vertex opposite this side lies also without,
+  for it is the pole of a line which cuts the curve. In this case
+  therefore one vertex lies within, the other two without. If, on the
+  other hand, we begin with a side which does not cut the conic, then
+  its pole lies within and the other vertices without. Hence--
+
+  Every polar-triangle has one and only one vertex within the conic.
+
+  We add, without a proof, the theorem--
+
+  The four points in which a conic is cut by two conjugate polars are
+  four harmonic points in the conic.
+
+  S 68. If two conics intersect in four points (they cannot have more
+  points in common, S 52), there exists one and only one four-point
+  which is inscribed in both, and therefore one polar-triangle common to
+  both.
+
+  _Theorem._--Two conics which intersect in four points have always one
+  and only one common polar-triangle; and reciprocally,
+
+  Two conics which have four common tangents have always one and only
+  one common polar-triangle.
+
+
+  DIAMETERS AND AXES OF CONICS
+
+  S 69. _Diameters._--The theorems about the harmonic properties of
+  poles and polars contain, as special cases, a number of important
+  metrical properties of conics. These are obtained if either the pole
+  or the polar is moved to infinity,--it being remembered that the
+  harmonic conjugate to a point at infinity, with regard to two points
+  A, B, is the middle point of the segment AB. The most important
+  properties are stated in the following theorems:--
+
+  _The middle points of parallel chords of a conic lie in a line--viz.
+  on the polar to the point at infinity on the parallel chords._
+
+  This line is called a _diameter_.
+
+  _The polar of every point at infinity is a diameter._
+
+  _The tangents at the end points of a diameter are parallel, and are
+  parallel to the chords bisected by the diameter._
+
+  _All diameters pass through a common point, the pole of the line at
+  infinity._
+
+  _All diameters of a parabola are parallel_, the pole to the line at
+  infinity being the point where the curve touches the line at
+  infinity.
+
+  In case of the ellipse and hyperbola, the pole to the line at infinity
+  is a finite point called the _centre_ of the curve.
+
+  _A centre of a conic bisects every chord through it._
+
+  _The centre of an ellipse is within the curve_, for the line at
+  infinity does not cut the ellipse.
+
+  _The centre of an hyperbola is without the curve_, because the line at
+  infinity cuts the curve. Hence also--
+
+  _From the centre of an hyperbola two tangents can be drawn to the
+  curve which have their point of contact at infinity._ These are called
+  _Asymptotes_ (S 59).
+
+  _To construct a diameter_ of a conic, draw two parallel chords and
+  join their middle points.
+
+  _To find the centre_ of a conic, draw two diameters; their
+  intersection will be the centre.
+
+  S 70. _Conjugate Diameters._--A polar-triangle with one vertex at the
+  centre will have the opposite side at infinity. The other two sides
+  pass through the centre, and are called _conjugate diameters_, each
+  being the polar of the point at infinity on the other.
+
+  _Of two conjugate diameters each bisects the chords parallel to the
+  other, and if one cuts the curve, the tangents at its ends are
+  parallel to the other diameter._
+
+  Further--
+
+  _Every parallelogram inscribed in a conic has its sides parallel to
+  two conjugate diameters_; and
+
+  _Every parallelogram circumscribed about a conic has as diagonals two
+  conjugate diameters._
+
+  This will be seen by considering the parallelogram in the first case
+  as an inscribed four-point, in the other as a circumscribed four-side,
+  and determining in each case the corresponding polar-triangle. The
+  first may also be enunciated thus--
+
+  _The lines which join any point on an ellipse or an hyperbola to the
+  ends of a diameter are parallel to two conjugate diameters._
+
+  S 71. _If every diameter is perpendicular to its conjugate the conic
+  is a circle._
+
+  For the lines which join the ends of a diameter to any point on the
+  curve include a right angle.
+
+  _A conic which has more than one pair of conjugate diameters at right
+  angles to each other is a circle._
+
+  [Illustration: FIG. 24.]
+
+  Let AA' and BB' (fig. 24) be one pair of conjugate diameters at right
+  angles to each other, CC and DD' a second pair. If we draw through the
+  end point A of one diameter a chord AP parallel to DD', and join P to
+  A', then PA and PA' are, according to S 70, parallel to two conjugate
+  diameters. But PA is parallel to DD', hence PA' is parallel to CC, and
+  therefore PA and PA' are perpendicular. If we further draw the
+  tangents to the conic at A and A', these will be perpendicular to AA',
+  they being parallel to the conjugate diameter BB'. We know thus five
+  points on the conic, viz. the points A and A' with their tangents, and
+  the point P. Through these a circle may be drawn having AA' as
+  diameter; and as through five points one conic only can be drawn, this
+  circle must coincide with the given conic.
+
+  S 72. _Axes._--Conjugate diameters perpendicular to each other are
+  called _axes_, and the points where they cut the curve _vertices_ of
+  the conic.
+
+  In a circle every diameter is an axis, every point on it is a vertex;
+  and any two lines at right angles to each other may be taken as a pair
+  of axes of any circle which has its centre at their intersection.
+
+  [Illustration: FIG. 25.]
+
+  If we describe on a diameter AB of an ellipse or hyperbola a circle
+  concentric to the conic, it will cut the latter in A and B (fig. 25).
+  Each of the semicircles in which it is divided by AB will be partly
+  within, partly without the curve, and must cut the latter therefore
+  again in a point. The circle and the conic have thus four points A, B,
+  C, D, and therefore one polar-triangle, in common (S 68). Of this the
+  centre is one vertex, for the line at infinity is the polar to this
+  point, both with regard to the circle and the other conic. The other
+  two sides are conjugate diameters of both, hence perpendicular to each
+  other. This gives--
+
+  An ellipse as well as an hyperbola has one pair of axes.
+
+  This reasoning shows at the same time _how to construct the axis of an
+  ellipse or of an hyperbola_.
+
+  _A parabola has one axis_, if we define an axis as a diameter
+  perpendicular to the chords which it bisects. It is easily
+  constructed. The line which bisects any two parallel chords is a
+  diameter. Chords perpendicular to it will be bisected by a parallel
+  diameter, and this is the axis.
+
+  S 73. The first part of the right-hand theorem in S 64 may be stated
+  thus: any two conjugate lines through a point P without a conic are
+  harmonic conjugates with regard to the two tangents that may be drawn
+  from P to the conic.
+
+  If we take instead of P the centre C of an hyperbola, then the
+  conjugate lines become conjugate diameters, and the tangents
+  asymptotes. Hence--
+
+  _Any two conjugate diameters of an hyperbola are harmonic conjugates
+  with regard to the asymptotes._
+
+  As the axes are conjugate diameters at right angles to one another, it
+  follows (S 23)--
+
+  _The axes of an hyperbola bisect the angles between the asymptotes._
+
+  [Illustration: FIG. 26.]
+
+  Let O be the centre of the hyperbola (fig. 26), t any secant which
+  cuts the hyperbola in C, D and the asymptotes in E, F, then the line
+  OM which bisects the chord CD is a diameter conjugate to the diameter
+  OK which is parallel to the secant t, so that OK and OM are harmonic
+  with regard to the asymptotes. The point M therefore bisects EF. But
+  by construction M bisects CD. It follows that DF = EC, and ED = CF; or
+
+  _On any secant of an hyperbola the segments between the curve and the
+  asymptotes are equal._
+
+  If the chord is changed into a tangent, this gives--
+
+  _The segment between the asymptotes on any tangent to an hyperbola is
+  bisected by the point of contact._
+
+  The first part allows a simple solution of the problem to find any
+  number of points on an hyperbola, of which the asymptotes and one
+  point are given. This is equivalent to three points and the tangents
+  at two of them. This construction requires measurement.
+
+  S 74. For the parabola, too, follow some metrical properties. A
+  diameter PM (fig. 27) bisects every chord conjugate to it, and the
+  pole P of such a chord BC lies on the diameter. But a diameter cuts
+  the parabola once at infinity. Hence--
+
+  _The segment PM which joins the middle point M of a chord of a
+  parabola to the pole P of the chord is bisected by the parabola at A._
+
+  S 75. Two asymptotes and any two tangents to an hyperbola may be
+  considered as a quadrilateral circumscribed about the hyperbola. But
+  in such a quadrilateral the intersections of the diagonals and the
+  points of contact of opposite sides lie in a line (S 54). If therefore
+  DEFG (fig. 28) is such a quadrilateral, then the diagonals DF and GE
+  will meet on the line which joins the points of contact of the
+  asymptotes, that is, on the line at infinity; hence they are parallel.
+  From this the following theorem is a simple deduction:
+
+  _All triangles formed by a tangent and the asymptotes of an hyperbola
+  are equal in area._
+
+  [Illustration: FIG. 27.]
+
+  [Illustration: FIG. 28.]
+
+  If we draw at a point P (fig. 28) on an hyperbola a tangent, the part
+  HK between the asymptotes is bisected at P. The parallelogram PQOQ'
+  formed by the asymptotes and lines parallel to them through P will be
+  half the triangle OHK, and will therefore be constant. If we now take
+  the asymptotes OX and OY as oblique axes of co-ordinates, the lines OQ
+  and QP will be the co-ordinates of P, and will satisfy the equation xy
+  = const. = a^2.
+
+  _For the asymptotes as axes of co-ordinates the equation of the
+  hyperbola is xy = const._
+
+
+  INVOLUTION
+
+  [Illustration: FIG. 29.]
+
+  S 76. If we have two projective rows, ABC on u and A'B'C' on u', and
+  place their bases on the same line, then each point in this line
+  counts twice, once as a point in the row u and once as a point in the
+  row u'. In fig. 29 we denote the points as points in the one row by
+  letters above the line A, B, C ..., and as points in the second row by
+  A', B', C' ... below the line. Let now A and B' be the same point,
+  then to A will correspond a point A' in the second, and to B' a point
+  B in the first row. In general these points A' and B will be
+  different. It may, however, happen that they coincide. Then the
+  correspondence is a peculiar one, as the following theorem shows:
+
+  _If two projective rows lie on the same base, and if it happens that
+  to one point in the base the same point corresponds, whether we
+  consider the point as belonging to the first or to the second row,
+  then the same will happen for every point in the base--that is to say,
+  to every point in the line corresponds the same point in the first as
+  in the second row._
+
+  [Illustration: FIG. 30.]
+
+  In order to determine the correspondence, we may assume three pairs of
+  corresponding points in two projective rows. Let then A', B', C', in
+  fig. 30, correspond to A, B, C, so that A and B', and also B and A',
+  denote the same point. Let us further denote the point C' when
+  considered as a point in the first row by D; then it is to be proved
+  that the point D', which corresponds to D, is the same point as C. We
+  know that the cross-ratio of four points is equal to that of the
+  corresponding row. Hence
+
+    (AB, CD) = (A'B', C'D')
+
+  but replacing the dashed letters by those undashed ones which denote
+  the same points, the second cross-ratio equals (BA, DD'), which,
+  according to S 15, equals (AB, D'D); so that the equation becomes
+
+    (AB, CD) = (AB, D'D).
+
+  This requires that C and D' coincide.
+
+  S 77. Two projective rows on the same base, which have the above
+  property, that to every point, whether it be considered as a point in
+  the one or in the other row, corresponds the same point, are said to
+  be in _involution_, or to form an _involution_ of points on the line.
+
+  We mention, but without proving it, that any two projective rows may
+  be placed so as to form an involution.
+
+  An involution may be said to consist of a row of pairs of points, to
+  every point A corresponding a point A', and to A' again the point A.
+  These points are said to be conjugate, or, better, one point is termed
+  the "mate" of the other.
+
+  From the definition, according to which an involution may be
+  considered as made up of two projective rows, follow at once the
+  following important properties:
+
+  1. The cross-ratio of four points equals that of the four conjugate
+  points.
+
+  2. If we call a point which coincides with its mate a "focus" or
+  "double point" of the involution, we may say: An involution has either
+  two foci, or one, or none, and is called respectively a hyperbolic,
+  parabolic or elliptic involution (S 34).
+
+  3. In an hyperbolic involution any two conjugate points are harmonic
+  conjugates with regard to the two foci.
+
+  For if A, A' be two conjugate points, F1, F2 the two foci, then to the
+  points F1, F2, A, A' in the one row correspond the points F1, F2, A',
+  A in the other, each focus corresponding to itself. Hence (F1F2, AA')
+  = (F1F2, A'A)--that is, we may interchange the two points AA' without
+  altering the value of the cross-ratio, which is the characteristic
+  property of harmonic conjugates (S 18).
+
+  4. The point conjugate to the point at infinity is called the "centre"
+  of the involution. Every involution has a centre, unless the point at
+  infinity be a focus, in which case we may say that the centre is at
+  infinity.
+
+  In an hyperbolic involution the centre is the middle point between the
+  foci.
+
+  5. The product of the distances of two conjugate points A, A' from the
+  centre O is constant: OA . OA' = c.
+
+  For let A, A' and B, B' be two pairs of conjugate points, the centre,
+  I the point at infinity, then
+
+    (AB, OI) = (A'B', IO),
+
+  or
+
+    OA . OA' = OB . OB'.
+
+  In order to determine the distances of the foci from the centre, we
+  write F for A and A' and get
+
+  OF^2 = c; OF = [+-][root]c.
+
+  Hence if c is positive OF is real, and has two values, equal and
+  opposite. The involution is hyperbolic.
+
+  If c = 0, OF = 0, and the two foci both coincide with the centre. If c
+  is negative, [root]c becomes imaginary, and there are no foci. Hence
+  we may write--
+
+    In an hyperbolic involution, OA.OA' = k^2,
+    In a parabolic involution, OA.OA' = 0,
+    In an elliptic involution, OA.OA' = -k^2.
+
+  From these expressions it follows that conjugate points A, A' in an
+  hyperbolic involution lie on the same side of the centre, and in an
+  elliptic involution on opposite sides of the centre, and that in a
+  parabolic involution one coincides with the centre.
+
+  In the first case, for instance, OA.OA' is positive; hence OA and OA'
+  have the same sign.
+
+  It also follows that two segments, AA' and BB', between pairs of
+  conjugate points have the following positions: in an hyperbolic
+  involution they lie either one altogether within or altogether without
+  each other; in a parabolic involution they have one point in common;
+  and in an elliptic involution they overlap, each being partly within
+  and partly without the other.
+
+  _Proof._--We have OA.OA' = OB.OB' = k^2 in case of an hyperbolic
+  involution. Let A and B be the points in each pair which are nearer to
+  the centre O. If now A, A' and B, B' lie on the same side of O, and if
+  B is nearer to O than A, so that OB < OA, then OB' > OA'; hence B' lies
+  farther away from O than A', or the segment AA' lies within BB'. And so
+  on for the other cases.
+
+  6. An involution is determined--
+
+    ([alpha]) By two pairs of conjugate points. Hence also
+    ([beta]) By one pair of conjugate points and the centre;
+    ([gamma]) By the two foci;
+    ([delta]) By one focus and one pair of conjugate points;
+    ([epsilon]) By one focus and the centre.
+
+  7. The condition that A, B, C and A', B', C' may form an involution
+  may be written in one of the forms--
+
+     (AB, CC') = (A'B', C'C),
+
+  or (AB, CA') = (A'B', C'A),
+
+  or (AB, C'A') = (A'B', CA),
+
+  for each expresses that in the two projective rows in which A, B, C
+  and A', B', C' are conjugate points two conjugate elements may be
+  interchanged.
+
+  8. Any three pairs. A, A', B, B', C, C', of conjugate points are
+  connected by the relations:
+
+    AB'.BC'.CA'   AB'.BC.C'A'   AB.B'C'.CA'   AB.B'C.C'A'
+    ----------- = ----------- = ----------- = ----------- = -1.
+    A'B.B'C.C'A   A'B.B'C'.CA   A'B'.BC.C'A   A'B'.BC'.CA
+
+  These relations readily follow by working out the relations in (7)
+  (above).
+
+  S 78. _Involution of a quadrangle.--The sides of any four-point are
+  cut by any line in six points in involution, opposite sides being cut
+  in conjugate points._
+
+  Let A1B1C1D1 (fig. 31) be the four-point. If its sides be cut by the
+  line p in the points A, A', B, B', C, C', if further, C1D1 cuts the
+  line A1B1 in C2, and if we project the row A1B1C2C to p once from D1
+  and once from C1, we get (A'B', C'C) = (BA, C'C).
+
+  Interchanging in the last cross-ratio the letters in each pair we get
+  (A'B', C'C) = (AB, CC'). Hence by S 77 (7) the points are in
+  involution.
+
+  The theorem may also be stated thus:
+
+  _The three points in which any line cuts the sides of a triangle and
+  the projections, from any point in the plane, of the vertices of the
+  triangle on to the same line are six points in involution._
+
+  [Illustration: FIG. 31.]
+
+  Or again--
+
+  The projections from any point on to any line of the six vertices of a
+  four-side are six points in involution, the projections of opposite
+  vertices being conjugate points.
+
+  This property gives a simple means to construct, by aid of the
+  straight edge only, in an involution of which two pairs of conjugate
+  points are given, to any point its conjugate.
+
+  S 79. _Pencils in Involution._--The theory of involution may at once
+  be extended from the row to the flat and the axial pencil--viz. we say
+  that there is an involution in a flat or in an axial pencil if any
+  line cuts the pencil in an involution of points. An involution in a
+  pencil consists of pairs of conjugate rays or planes; it has two, one
+  or no _focal rays_ (double lines) or _planes_, but nothing
+  corresponding to a centre.
+
+  An involution in a flat pencil contains always one, and in general
+  only one, pair of conjugate rays which are perpendicular to one
+  another. For in two projective flat pencils exist always two
+  corresponding right angles (S 40).
+
+  Each involution in an axial pencil contains in the same manner one
+  pair of conjugate planes at right angles to one another.
+
+  As a rule, there exists but one pair of conjugate lines or planes at
+  right angles to each other. But it is possible that there are more,
+  and then there is an infinite number of such pairs. An involution in a
+  flat pencil, in which every ray is perpendicular to its conjugate ray,
+  is said to be _circular_. That such involution is possible is easily
+  seen thus: if in two concentric flat pencils each ray on one is made
+  to correspond to that ray on the other which is perpendicular to it,
+  then the two pencils are projective, for if we turn the one pencil
+  through a right angle each ray in one coincides with its corresponding
+  ray in the other. But these two projective pencils are in involution.
+
+  A circular involution has no focal rays, because no ray in a pencil
+  coincides with the ray perpendicular to it.
+
+  S 80. _Every elliptical involution in a row may be considered as a
+  section of a circular involution._
+
+  In an elliptical involution any two segments AA' and BB' lie partly
+  within and partly without each other (fig. 32). Hence two circles
+  described on AA' and BB' as diameters will intersect in two points E
+  and E'. The line EE' cuts the base of the involution at a point O,
+  which has the property that OA.OA' = OB . OB', for each is equal to
+  OE . OE'. The point O is therefore the centre of the involution. If we
+  wish to construct to any point C the conjugate point C', we may draw
+  the circle through CEE'. This will cut the base in the required point
+  C' for OC.OC' = OA.OA'. But EC and EC' are at right angles. Hence the
+  involution which is obtained by joining E or E' to the points in the
+  given involution is circular. This may also be expressed thus:
+
+  [Illustration: FIG. 32.]
+
+  _Every elliptical involution has the property that there are two
+  definite points in the plane from which any two conjugate points are
+  seen under a right angle._
+
+  At the same time the following problem has been solved:
+
+  To determine the centre and also the point corresponding to any given
+  point in an elliptical involution of which two pairs of conjugate
+  points are given.
+
+  S 81. _Involution Range on a Conic._--By the aid of S 53, the points
+  on a conic may be made to correspond to those on a line, so that the
+  row of points on the conic is projective to a row of points on a line.
+  We may also have two projective rows on the same conic, and these will
+  be in involution as soon as one point on the conic has the same point
+  corresponding to it all the same to whatever row it belongs. An
+  involution of points on a conic will have the property (as follows
+  from its definition, and from S 53) that the lines which join
+  conjugate points of the involution to any point on the conic are
+  conjugate lines of an involution in a pencil, and that a fixed tangent
+  is cut by the tangents at conjugate points on the conic in points
+  which are again conjugate points of an involution on the fixed
+  tangent. For such involution on a conic the following theorem holds:
+
+  _The lines which join corresponding points in an involution on a conic
+  all pass through a fixed point; and reciprocally, the points of
+  intersection of conjugate lines in an involution among tangents to a
+  conic lie on a line._
+
+  [Illustration: FIG. 33]
+
+  We prove the first part only. The involution is determined by two
+  pairs of conjugate points, say by A, A' and B, B' (fig. 33). Let AA'
+  and BB' meet in P. If we join the points in involution to any point on
+  the conic, and the conjugate points to another point on the conic, we
+  obtain two projective pencils. We take A and A' as centres of these
+  pencils, so that the pencils A(A'BB') and A'(AB'B) are projective, and
+  in perspective position, because AA' corresponds to A'A. Hence
+  corresponding rays meet in a line, of which two points are found by
+  joining AB' to A'B and AB to A'B'. It follows that the _axis_ of
+  perspective is the polar of the point P, where AA' and BB' meet. If we
+  now wish to construct to any other point C on the conic the
+  corresponding point C', we join C to A' and the point where this line
+  cuts p to A. The latter line cuts the conic again in C'. But we know
+  from the theory of pole and polar that the line CC' passes through P.
+  The point of concurrence is called the "pole of the involution," and
+  the line of collinearity of the meets is called the "axis of the
+  involution."
+
+
+  INVOLUTION DETERMINED BY A CONIC ON A LINE.--FOCI
+
+  S 82. The polars, with regard to a conic, of points in a row p form a
+  pencil P projective to the row (S 66). This pencil cuts the base of
+  the row p in a projective row.
+
+  If A is a point in the given row, A' the point where the polar of A
+  cuts p, then A and A' will be corresponding points. If we take A' a
+  point in the first row, then the polar of A' will pass through A, so
+  that A corresponds to A'--in other words, the rows are in involution.
+  The conjugate points in this involution are conjugate points with
+  regard to the conic. Conjugate points coincide only if the polar of a
+  point A passes through A--that is, if A lies on the conic. Hence--
+
+  _A conic determines on every line in its plane an involution, in which
+  those points are conjugate which are also conjugate with regard to the
+  conic._
+
+  _If the line cuts the conic the involution is hyperbolic, the points
+  of intersection being the foci._
+
+  _If the line touches the conic the involution is parabolic, the two
+  foci coinciding at the point of contact._
+
+  _If the line does not cut the conic the involution is elliptic, having
+  no foci._
+
+  If, on the other hand, we take a point P in the plane of a conic, we
+  get to each line a through P one conjugate line which joins P to the
+  pole of a. These pairs of conjugate lines through P form an involution
+  in the pencil at P. The focal rays of this involution are the tangents
+  drawn from P to the conic. This gives the theorem reciprocal to the
+  last, viz:--
+
+  _A conic determines in every pencil in its plane an involution,
+  corresponding lines being conjugate lines with regard to the conic._
+
+  _If the point is without the conic the involution is hyperbolic, the
+  tangents from the points being the focal rays._
+
+  _If the point lies on the conic the involution is parabolic, the
+  tangent at the point counting for coincident focal rays._
+
+  _If the point is within the conic the involution is elliptic, having
+  no focal rays._
+
+  It will further be seen that the involution determined by a conic on
+  any line p is a section of the involution, which is determined by the
+  conic at the pole P of p.
+
+  S 83. _Foci._--The centre of a pencil in which the conic determines a
+  circular involution is called a "focus" of the conic.
+
+  In other words, a focus is such a point that every line through it is
+  perpendicular to its conjugate line. The polar to a focus is called a
+  _directrix_ of the conic.
+
+  From the definition it follows that _every focus lies on an axis_, for
+  the line joining a focus to the centre of the conic is a diameter to
+  which the conjugate lines are perpendicular; and _every line joining
+  two foci is an axis_, for the perpendiculars to this line through the
+  foci are conjugate to it. These conjugate lines pass through the pole
+  of the line, the pole lies therefore at infinity, and the line is a
+  diameter, hence by the last property an axis.
+
+  It follows that all _foci lie on one axis_, for no line joining a
+  point in one axis to a point in the other can be an axis.
+
+  As the conic determines in the pencil which has its centre at a focus
+  a circular involution, no tangents can be drawn from the focus to the
+  conic. Hence _each focus lies within a conic_; and _a directrix does
+  not cut the conic_.
+
+  Further properties are found by the following considerations:
+
+  S 84. Through a point P one line p can be drawn, which is with regard
+  to a given conic conjugate to a given line q, viz. that line which
+  joins the point P to the pole of the line q. If the line q is made to
+  describe a pencil about a point Q, then the line p will describe a
+  pencil about P. These two pencils will be projective, for the line p
+  passes through the pole of q, and whilst q describes the pencil Q, its
+  pole describes a projective row, and this row is perspective to the
+  pencil P.
+
+  We now take the point P on an axis of the conic, draw any line p
+  through it, and from the pole of p draw a perpendicular q to p. Let q
+  cut the axis in Q. Then, in the pencils of conjugate lines, which have
+  their centres at P and Q, the lines p and q are conjugate lines at
+  right angles to one another. Besides, to the axis as a ray in either
+  pencil will correspond in the other the perpendicular to the axis (S
+  72). The conic generated by the intersection of corresponding lines in
+  the two pencils is therefore the circle on PQ as diameter, _so that
+  every line in P is perpendicular to its corresponding line in Q_.
+
+  To every point P on an axis of a conic corresponds thus a point Q,
+  such that conjugate lines through P and Q are perpendicular.
+
+  We shall show that these _point-pairs_ P, Q _form an involution_. To
+  do this let us move P along the axis, and with it the line p, keeping
+  the latter parallel to itself. Then P describes a row, p a perspective
+  pencil (of parallels), and the pole of p a projective row. At the same
+  time the line q describes a pencil of parallels perpendicular to p,
+  and perspective to the row formed by the pole of p. The point Q,
+  therefore, where q cuts the axis, describes a row projective to the
+  row of points P. The two points P and Q describe thus two projective
+  rows on the axis; and not only does P as a point in the first row
+  correspond to Q, but also Q as a point in the first corresponds to P.
+  The two rows therefore form an involution. _The centre of this
+  involution, it is easily seen, is the centre of the conic._
+
+  _A focus of this involution has the property that any two conjugate
+  lines through it are perpendicular; hence, it is a focus to the
+  conic._
+
+  Such involution exists on each axis. But only one of these can have
+  foci, because all foci lie on the same axis. The involution on one of
+  the axes is elliptic, and appears (S 80) therefore as the section of
+  two circular involutions in two pencils whose centres lie in the other
+  axis. These centres are foci, hence the one axis contains two foci,
+  the other axis none; _or every central conic has two foci which lie on
+  one axis equidistant from the centre_.
+
+  The axis which contains the foci is called the _principal axis_; in
+  case of an hyperbola it is the axis which cuts the curve, because the
+  foci lie within the conic.
+
+  In case of the parabola there is but one axis. The involution on this
+  axis has its centre at infinity. One focus is therefore at infinity,
+  the one focus only is finite. _A parabola has only one focus._
+
+  [Illustration: FIG. 34.]
+
+  S 85. If through any point P (fig. 34) on a conic the tangent PT and
+  the normal PN (i.e. the perpendicular to the tangent through the point
+  of contact) be drawn, these will be conjugate lines with regard to the
+  conic, and at right angles to each other. They will therefore cut the
+  principal axis in two points, which are conjugate in the involution
+  considered in S 84; hence they are harmonic conjugates with regard to
+  the foci. If therefore the two foci F1 and F2 be joined to P, these
+  lines will be harmonic with regard to the tangent and normal. As the
+  latter are perpendicular, they will bisect the angles between the
+  other pair. Hence--
+
+  _The lines joining any point on a conic to the two foci are equally
+  inclined to the tangent and normal at that point._
+
+  In case of the parabola this becomes--
+
+  _The line joining any point on a parabola to the focus and the
+  diameter through the point, are equally inclined to the tangent and
+  normal at that point._
+
+  From the definition of a focus it follows that--
+
+  _The segment of a tangent between the directrix and the point of
+  contact is seen from the focus belonging to the directrix under a
+  right angle_, because the lines joining the focus to the ends of this
+  segment are conjugate with regard to the conic, and therefore
+  perpendicular.
+
+  With equal ease the following theorem is proved:
+
+  _The two lines which join the points of contact of two tangents each
+  to one focus, but not both to the same, are seen from the intersection
+  of the tangents under equal angles._
+
+  S 86. Other focal properties of a conic are obtained by the following
+  considerations:
+
+  [Illustration: FIG. 35.]
+
+  Let F (fig. 35) be a focus to a conic, f the corresponding directrix,
+  A and B the points of contact of two tangents meeting at T, and P the
+  point where the line AB cuts the directrix. Then TF will be the polar
+  of P (because polars of F and T meet at P). Hence TF and PF are
+  conjugate lines through a focus, and therefore perpendicular. They are
+  further harmonic conjugates with regard to FA and FB (SS 64 and 13),
+  so that they bisect the angles formed by these lines. This by the way
+  proves--
+
+  _The segments between the point of intersection of two tangents to a
+  conic and their points of contact are seen from a focus under equal
+  angles._
+
+  If we next draw through A and B lines parallel to TF, then the points
+  A1, B1 where these cut the directrix will be harmonic conjugates with
+  regard to P and the point where FT cuts the directrix. The lines FT
+  and FP bisect therefore also the angles between FA1 and FB1. From this
+  it follows easily that the triangles FAA1 and FBB1 are equiangular,
+  and therefore similar, so that FA : AA1 = FB : BB1.
+
+  The triangles AA1A2 and BB1B2 formed by drawing perpendiculars from A
+  and B to the directrix are also similar, so that AA1 : AA2 = = BB1 :
+  BB2. This, combined with the above proportion, gives FA : AA2 = FB :
+  BB2. Hence the theorem:
+
+  _The ratio of the distances of any point on a conic from a focus and
+  the corresponding directrix is constant._
+
+  To determine this ratio we consider its value for a vertex on the
+  principal axis. In an ellipse the focus lies between the two vertices
+  on this axis, hence the focus is nearer to a vertex than to the
+  corresponding directrix. Similarly, in an hyperbola a vertex is nearer
+  to the directrix than to the focus. In a parabola the vertex lies
+  halfway between directrix and focus.
+
+  It follows in an ellipse the ratio between the distance of a point
+  from the focus to that from the directrix is less than unity, in the
+  parabola it equals unity, and in the hyperbola it is greater than
+  unity.
+
+  It is here the same which focus we take, because the two foci lie
+  symmetrical to the axis of the conic. If now P is any point on the
+  conic having the distances r1 and r2 from the foci and the distances
+  d1 and d2 from the corresponding directrices, then r1/d1 = r2/d2 =
+  e, where e is constant. Hence also r1 [+-] r2 / d1 [+-] d2 = e.
+
+  In the ellipse, which lies between the directrices, d1 + d2 is
+  constant, therefore also r1 +r2. In the hyperbola on the other hand d1
+  - d2 is constant, equal to the distance between the directrices,
+  therefore in this case r1 - r2 is constant.
+
+  If we call the distances of a point on a conic from the focus its
+  focal distances we have the theorem:
+
+  _In an ellipse the sum of the focal distances is constant; and in an
+  hyperbola the difference of the focal distances is constant._
+
+  _This constant sum or difference equals in both cases the length of
+  the principal axis._
+
+
+  PENCIL OF CONICS
+
+  S 87. Through four points A, B, C, D in a plane, of which no three lie
+  in a line, an infinite number of conics may be drawn, viz. through
+  these four points and any fifth one single conic. This system of
+  conics is called a pencil of conics. Similarly, all conics touching
+  four fixed lines form a system such that any fifth tangent determines
+  one and only one conic. We have here the theorems:
+
+  The pairs of points in which        The pairs of tangents which
+  any line is cut by a system of      can be drawn from a point to
+  conics through four fixed points    a system of conics touching four
+  are in involution.                  fixed lines are in involution.
+
+  [Illustration: FIG. 36.]
+
+  We prove the first theorem only. Let ABCD (fig. 36) be the four-point,
+  then any line t will cut two opposite sides AC, BD in the points E,
+  E', the pair AD, BC in points F, F', and any conic of the system in M,
+  N, and we have A(CD, MN) = B(CD, MN).
+
+  If we cut these pencils by t we get
+
+     (EF, MN) = (F'E', MN)
+
+  or (EF, MN) = (E'F', NM).
+
+  But this is, according to S 77 (7), the condition that M, N are
+  corresponding points in the involution determined by the point pairs
+  E, E', F, F' in which the line t cuts pairs of opposite sides of the
+  four-point ABCD. This involution is independent of the particular
+  conic chosen.
+
+  S 88. There follow several important theorems:
+
+  _Through four points two, one, or no conics may be drawn which touch
+  any given line, according as the involution determined by the given
+  four-point on the line has real, coincident or imaginary foci._
+
+  _Two, one, or no conics may be drawn which touch four given lines and
+  pass through a given point, according as the involution determined by
+  the given four-side at the point has real, coincident or imaginary
+  focal rays._
+
+  For the conic through four points which touches a given line has its
+  point of contact at a focus of the involution determined by the
+  four-point on the line.
+
+  As a special case we get, by taking the line at infinity:
+
+  _Through four points of which none is at infinity either two or no
+  parabolas may be drawn._
+
+  The problem of drawing a conic through four points and touching a
+  given line is solved by determining the points of contact on the line,
+  that is, by determining the foci of the involution in which the line
+  cuts the sides of the four-point. The corresponding remark holds for
+  the problem of drawing the conics which touch four lines and pass
+  through a given point.
+
+
+  RULED QUADRIC SURFACES
+
+  S 89. We have considered hitherto projective rows which lie in the
+  same plane, in which case lines joining corresponding points envelop a
+  conic. We shall now consider projective rows whose bases do not meet.
+  In this case, corresponding points will be joined by lines which do
+  not lie in a plane, but on some surface, which like every surface
+  generated by lines is called a _ruled_ surface. This surface clearly
+  contains the bases of the two rows.
+
+  If the points in either row be joined to the base of the other, we
+  obtain two axial pencils which are also projective, those planes being
+  corresponding which pass through corresponding points in the given
+  rows. If A', A be two corresponding points, [alpha], [alpha]' the
+  planes in the axial pencils passing through them, then AA' will be the
+  line of intersection of the corresponding planes [alpha], [alpha]' and
+  also the line joining corresponding points in the rows.
+
+  If we cut the whole figure by a plane this will cut the axial pencils
+  in two projective flat pencils, and the curve of the second order
+  generated by these will be the curve in which the plane cuts the
+  surface. Hence
+
+  _The locus of lines joining corresponding points in two projective
+  rows which do not lie in the same plane is a surface which contains
+  the bases of the rows, and which can also be generated by the lines of
+  intersection of corresponding planes in two projective axial pencils.
+  This surface is cut by every plane in a curve of the second order,
+  hence either in a conic or in a line-pair. No line which does not lie
+  altogether on the surface can have more than two points in common with
+  the surface, which is therefore said to be of the second order or is
+  called a ruled quadric surface._
+
+  That no line which does not lie on the surface can cut the surface in
+  more than two points is seen at once if a plane be drawn through the
+  line, for this will cut the surface in a conic. It follows also that a
+  line which contains more than two points of the surface lies
+  altogether on the surface.
+
+  S 90. Through any point in space one line can always be drawn cutting
+  two given lines which do not themselves meet.
+
+  If therefore three lines in space be given of which no two meet, then
+  through every point in either one line may be drawn cutting the other
+  two.
+
+  _If a line moves so that it always cuts three given lines of which no
+  two meet, then it generates a ruled quadric surface._
+
+  Let a, b, c be the given lines, and p, q, r ... lines cutting them in
+  the points A, A', A" ...; B, B', B" ...; C, C', C" ... respectively;
+  then the planes through a containing p, q, r, and the planes through b
+  containing the same lines, may be taken as corresponding planes in two
+  axial pencils which are projective, because both pencils cut the line
+  c in the same row, C, C', C" ...; the surface can therefore be
+  generated by projective axial pencils.
+
+  Of the lines p, q, r ... no two can meet, for otherwise the lines a,
+  b, c which cut them would also lie in their plane. There is a single
+  infinite number of them, for one passes through each point of a. These
+  lines are said to form a set of lines on the surface.
+
+  If now three of the lines p, q, r be taken, then every line d cutting
+  them will have three points in common with the surface, and will
+  therefore lie altogether on it. This gives rise to a second set of
+  lines on the surface. From what has been said the theorem follows:
+
+  _A ruled quadric surface contains two sets of straight lines. Every
+  line of one set cuts every line of the other, but no two lines of the
+  same set meet._
+
+  _Any two lines of the same set may be taken as bases of two projective
+  rows, or of two projective pencils which generate the surface. They
+  are cut by the lines of the other set in two projective rows._
+
+  The plane at infinity like every other plane cuts the surface either
+  in a conic proper or in a line-pair. In the first case the surface is
+  called an _Hyperboloid of one sheet_, in the second an _Hyperbolic
+  Paraboloid_.
+
+  The latter may be generated by a line cutting three lines of which one
+  lies at infinity, that is, cutting two lines and remaining parallel to
+  a given plane.
+
+
+  QUADRIC SURFACES
+
+  S 91. The conics, the cones of the second order, and the ruled quadric
+  surfaces complete the figures which can be generated by projective
+  rows or flat and axial pencils, that is, by those aggregates of
+  elements which are of one dimension (SS 5, 6). We shall now consider
+  the simpler figures which are generated by aggregates of two
+  dimensions. The space at our disposal will not, however, allow us to
+  do more than indicate a few of the results.
+
+  S 92. We establish a correspondence between the lines and planes in
+  pencils in space, or reciprocally between the points and lines in two
+  or more planes, but consider principally pencils.
+
+  In two pencils we may either make planes correspond to planes and
+  lines to lines, or else planes to lines and lines to planes. If hereby
+  the condition be satisfied that to a flat, or axial, pencil
+  corresponds in the first case a projective flat, or axial, pencil, and
+  in the second a projective axial, or flat, pencil, the pencils are
+  said to be _projective_ in the first case and _reciprocal_ in the
+  second.
+
+  For instance, two pencils which join two points S1 and S2 to the
+  different points and lines in a given plane [pi] are projective (and
+  in perspective position), if those lines and planes be taken as
+  corresponding which meet the plane [pi] in the same point or in the
+  same line. In this case every plane through both centres S1 and S2 of
+  the two pencils will correspond to itself. If these pencils are
+  brought into any other position they will be projective (but not
+  perspective).
+
+  _The correspondence between two projective pencils is uniquely
+  determined, if to four rays (or planes) in the one the corresponding
+  rays (or planes) in the other are given, provided that no three rays
+  of either set lie in a plane._
+
+  Let a, b, c, d be four rays in the one, a', b', c', d' the
+  corresponding rays in the other pencil. We shall show that we can find
+  for every ray e in the first a single corresponding ray e' in the
+  second. To the axial pencil a (b, c, d ...) formed by the planes which
+  join a to b, c, d ..., respectively corresponds the axial pencil a'
+  (b', c', d' ... ), and this correspondence is determined. Hence, the
+  plane a'e' which corresponds to the plane ae is determined. Similarly
+  the plane b'e' may be found and both together determine the ray e'.
+
+  Similarly the correspondence between two reciprocal pencils is
+  determined if for four rays in the one the corresponding planes in the
+  other are given.
+
+  S 93. We may now combine--
+
+  1. Two reciprocal pencils.
+
+    Each ray cuts its corresponding plane in a point, the locus of these
+    points is a quadric surface.
+
+  2. Two projective pencils.
+
+    Each plane cuts its corresponding plane in a line, but a ray as a
+    rule does not cut its corresponding ray. The locus of points where a
+    ray cuts its corresponding ray is a twisted cubic. The lines where a
+    plane cuts its corresponding plane are secants.
+
+  3. Three projective pencils.
+
+    The locus of intersection of corresponding planes is a cubic
+    surface.
+
+  Of these we consider only the first two cases.
+
+  S 94. If two pencils are reciprocal, then to a plane in either
+  corresponds a line in the other, to a flat pencil an axial pencil, and
+  so on. Every line cuts its corresponding plane in a point. If S1 and
+  S2 be the centres of the two pencils, and P be a point where a line a1
+  in the first cuts its corresponding plane [alpha]2, _then the line b2
+  in the pencil S2 which passes through P will meet its corresponding
+  plane [beta]1 in P_. For b2 is a line in the plane [alpha]2. The
+  corresponding plane [beta]1 must therefore pass through the line a1,
+  hence through P.
+
+  The points in which the lines in S1 cut the planes corresponding to
+  them in S2 are therefore the same as the points in which the lines in
+  S2 cut the planes corresponding to them in S1.
+
+  _The locus of these points is a surface which is cut by a plane in a
+  conic or in a line-pair and by a line in not more than two points
+  unless it lies altogether on the surface. The surface itself is
+  therefore called a quadric surface, or a surface of the second order._
+
+  To prove this we consider any line p in space.
+
+  The flat pencil in S1 which lies in the plane drawn through p and the
+  corresponding axial pencil in S2 determine on p two projective rows,
+  and those points in these which coincide with their corresponding
+  points lie on the surface. But there exist only two, or one, or no
+  such points, unless every point coincides with its corresponding
+  point. In the latter case the line lies altogether on the surface.
+
+  This proves also that a plane cuts the surface in a curve of the
+  second order, as no line can have more than two points in common with
+  it. To show that this is a curve of the same kind as those considered
+  before, we have to show that it can be generated by projective flat
+  pencils. We prove first that this is true for any plane through the
+  centre of one of the pencils, and afterwards that every point on the
+  surface may be taken as the centre of such pencil. Let then [alpha]1
+  be a plane through S1. To the flat pencil in S1 which it contains
+  corresponds in S2 a projective axial pencil with axis a2 and this cuts
+  [alpha]1 in a second flat pencil. These two flat pencils in [alpha]1
+  are projective, and, in general, neither concentric nor perspective.
+  They generate therefore a conic. But if the line a2 passes through S1
+  the pencils will have S1 as common centre, and may therefore have two,
+  or one, or no lines united with their corresponding lines. The section
+  of the surface by the plane [alpha]1 will be accordingly a line-pair
+  or a single line, or else the plane [alpha]1 will have only the point
+  S1 in common with the surface.
+
+  Every line l1 through S1 cuts the surface in two points, viz. first in
+  S1 and then at the point where it cuts its corresponding plane. If now
+  the corresponding plane passes through S1, as in the case just
+  considered, then the two points where l1 cuts the surface coincide at
+  S1, and the line is called a tangent to the surface with S1 as point
+  of contact. Hence if l1 be a tangent, it lies in that plane [tau]1
+  which corresponds to the line S2S1 as a line in the pencil S2. The
+  section of this plane has just been considered. It follows that--
+
+  _All tangents to quadric surface at the centre of one of the
+  reciprocal pencils lie in a plane which is called the tangent plane to
+  the surface at that point as point of contact._
+
+  _To the line joining the centres of the two pencils as a line in one
+  corresponds in the other the tangent plane at its centre._
+
+  _The tangent plane to a quadric surface either cuts the surface in two
+  lines, or it has only a single line, or else only a single point in
+  common with the surface._
+
+  _In the first case the point of contact is said to be hyperbolic, in
+  the second parabolic, in the third elliptic._
+
+  S 95. It remains to be proved that every point S on the surface may be
+  taken as centre of one of the pencils which generate the surface. Let
+  S be any point on the surface [Phi]' generated by the reciprocal
+  pencils S1 and S2. We have to establish a reciprocal correspondence
+  between the pencils S and S1, so that the surface generated by them is
+  identical with [Phi]. To do this we draw two planes [alpha]1 and
+  [beta]1 through S1, cutting the surface [Phi] in two conics which we
+  also denote by [alpha]1 and [beta]1. These conics meet at S1, and at
+  some other point T where the line of intersection of [alpha]1 and
+  [beta]1 cuts the surface.
+
+  In the pencil S we draw some plane [sigma] which passes through T, but
+  not through S1 or S2. It will cut the two conics first at T, and
+  therefore each at some other point which we call A and B respectively.
+  These we join to S by lines a and b, and now establish the required
+  correspondence between the pencils S1 and S as follows:--To S1T shall
+  correspond the plane [sigma], to the plane [alpha]1 the line a, and to
+  [beta]1 the line b, hence to the flat pencil in [alpha]1 the axial
+  pencil a. These pencils are made projective by aid of the conic in
+  [alpha]1.
+
+  In the same manner the flat pencil in [beta]1 is made projective to
+  the axial pencil b by aid of the conic in [beta]1, corresponding
+  elements being those which meet on the conic. This determines the
+  correspondence, for we know for more than four rays in S1 the
+  corresponding planes in S. The two pencils S and S1 thus made
+  reciprocal generate a quadric surface [Phi]', which passes through the
+  point S and through the two conics [alpha]1 and [beta]1.
+
+  The two surfaces [Phi] and [Phi]' have therefore the points S and S1
+  and the conics [alpha]1 and [beta]1 in common. To show that they are
+  identical, we draw a plane through S and S2, cutting each of the
+  conics [alpha]1 and [beta]1 in two points, which will always be
+  possible. This plane cuts [Phi] and [Phi]' in two conics which have
+  the point S and the points where it cuts [alpha]1 and [beta]1 in
+  common, that is five points in all. The conics therefore coincide.
+
+  This proves that all those points P on [Phi]' lie on [Phi] which have
+  the property that the plane SS2P cuts the conics [alpha]1, [beta]1 in
+  two points each. If the plane SS2P has not this property, then we draw
+  a plane SS1P. This cuts each surface in a conic, and these conics have
+  in common the points S, S1, one point on each of the conics [alpha]1,
+  [beta]1, and one point on one of the conics through S and S2 which lie
+  on both surfaces, hence five points. They are therefore coincident,
+  and our theorem is proved.
+
+  S 96. The following propositions follow:--
+
+  _A quadric surface has at every point a tangent plane._
+
+  _Every plane section of a quadric surface is a conic or a line-pair._
+
+  _Every line which has three points in common with a quadric surface
+  lies on the surface._
+
+  _Every conic which has five points in common with a quadric surface
+  lies on the surface._
+
+  _Through two conics which lie in different planes, but have two points
+  in common, and through one external point always one quadric surface
+  may be drawn._
+
+  S 97. _Every plane which cuts a quadric surface in a line-pair is a
+  tangent plane._ For every line in this plane through the centre of the
+  line-pair (the point of intersection of the two lines) cuts the
+  surface in two coincident points and is therefore a tangent to the
+  surface, _the centre of the line-pair being the point of contact_.
+
+  _If a quadric surface contains a line, then every plane through this
+  line cuts the surface in a line-pair (or in two coincident lines)._
+  For this plane cannot cut the surface in a conic. Hence:--
+
+  _If a quadric surface contains one line p then it contains an infinite
+  number of lines, and through every point Q on the surface, one line q
+  can be drawn which cuts p._ For the plane through the point Q and the
+  line p cuts the surface in a line-pair which must pass through Q and
+  of which p is one line.
+
+  _No two such lines q on the surface can meet_. For as both meet p
+  their plane would contain p and therefore cut the surface in a
+  triangle.
+
+  _Every line which cuts three lines q will be on the surface_; for it
+  has three points in common with it.
+
+  _Hence the quadric surfaces which contain lines are the same as the
+  ruled quadric surfaces considered in_ SS 89-93, but with one important
+  exception. In the last investigation we have left out of consideration
+  the possibility of a plane having only one line (two coincident lines)
+  in common with a quadric surface.
+
+  S 98. To investigate this case we suppose first that there is one
+  point A on the surface through which two different lines a, b can be
+  drawn, which lie altogether on the surface.
+
+  If P is any other point on the surface which lies neither on a nor b,
+  then the plane through P and a will cut the surface in a second line
+  a' which passes through P and which cuts a. Similarly there is a line
+  b' through P which cuts b. These two lines a' and b' _may_ coincide,
+  but then they must coincide with PA.
+
+  If this happens for one point P, it happens for every other point Q.
+  For if two different lines could be drawn through Q, then by the same
+  reasoning the line PQ would be altogether on the surface, hence two
+  lines would be drawn through P against the assumption. From this
+  follows:--
+
+  _If there is one point on a quadric surface through which one, but
+  only one, line can be drawn on the surface, then through every point
+  one line can be drawn, and all these lines meet in a point. The
+  surface is a cone of the second order_.
+
+  _If through one point on a quadric surface, two, and only two, lines
+  can be drawn on the surface, then through every point two lines may be
+  drawn, and the surface is ruled quadric surface._
+
+  _If through one point on a quadric surface no line on the surface can
+  be drawn, then the surface contains no lines._
+
+  Using the definitions at the end of S 95, we may also say:--
+
+  _On a quadric surface the points are all hyperbolic, or all parabolic,
+  or all elliptic._
+
+  As an example of a quadric surface with elliptical points, we mention
+  the sphere which may be generated by two reciprocal pencils, where to
+  each line in one corresponds the plane perpendicular to it in the
+  other.
+
+  S 99. _Poles and Polar Planes._--The theory of poles and polars with
+  regard to a conic is easily extended to quadric surfaces.
+
+  Let P be a point in space not on the surface, which we suppose not to
+  be a cone. On every line through P which cuts the surface in two
+  points we determine the harmonic conjugate Q of P with regard to the
+  points of intersection. Through one of these lines we draw two planes
+  [alpha] and [beta]. The locus of the points Q in [alpha] is a line a,
+  the polar of P with regard to the conic in which [alpha] cuts the
+  surface. Similarly the locus of points Q in [beta] is a line b. This
+  cuts a, because the line of intersection of [alpha] and [beta]
+  contains but one point Q. The locus of all points Q therefore is a
+  plane. _This plane is called the polar plane of the point P, with
+  regard to the quadric surface. If P lies on the surface we take the
+  tangent plane of P as its polar._
+
+  The following propositions hold:--
+
+  1. _Every point has a polar plane_, which is constructed by drawing
+  the polars of the point with regard to the conics in which two planes
+  through the point cut the surface.
+
+  2. _If Q is a point in the polar of P, then P is a point in the polar
+  of Q_, because this is true with regard to the conic in which a plane
+  through PQ cuts the surface.
+
+  3. _Every plane is the polar plane of one point, which is called the
+  Pole of the plane._
+
+  The pole to a plane is found by constructing the polar planes of three
+  points in the plane. Their intersection will be the pole.
+
+  4. _The points in which the polar plane of P cuts the surface are
+  points of contact of tangents drawn from P to the surface_, as is
+  easily seen. Hence:--
+
+  5. _The tangents drawn from a point P to a quadric surface form a cone
+  of the second order_, for the polar plane of P cuts it in a conic.
+
+  6. _If the pole describes a line a, its polar plane will turn about
+  another line a'_, as follows from 2. _These lines a and a' are said to
+  be conjugate with regard to the surface._
+
+  S 100. The pole of the line at infinity is called the _centre_ of the
+  surface. If it lies at the infinity, the plane at infinity is a
+  tangent plane, and the surface is called a _paraboloid_.
+
+  _The polar plane to any point at infinity passes through the centre,
+  and is called a diametrical plane._
+
+  _A line through the centre is called a diameter. It is bisected at the
+  centre. The line conjugate to it lies at infinity._
+
+  _If a point moves along a diameter its polar plane turns about the
+  conjugate line at infinity_; that is, _it moves parallel to itself,
+  its centre moving on the first line._
+
+  _The middle points of parallel chords lie in a plane_, viz. in the
+  polar plane of the point at infinity through which the chords are
+  drawn.
+
+  _The centres of parallel sections lie in a diameter which is a line
+  conjugate to the line at infinity in which the planes meet._
+
+
+  TWISTED CUBICS
+
+  S 101. If two pencils with centres S1 and S2 are made projective, then
+  to a ray in one corresponds a ray in the other, to a plane a plane, to
+  a flat or axial pencil a projective flat or axial pencil, and so on.
+
+  There is a double infinite number of lines in a pencil. We shall see
+  that a single infinite number of lines in one pencil meets its
+  corresponding ray, and that the points of intersection form a curve in
+  space.
+
+  Of the double infinite number of planes in the pencils each will meet
+  its corresponding plane. This gives a system of a double infinite
+  number of lines in space. We know (S 5) that there is a quadruple
+  infinite number of lines in space. From among these we may select
+  those which satisfy one or more given conditions. The systems of lines
+  thus obtained were first systematically investigated and classified by
+  Plucker, in his _Geometrie des Raumes_. He uses the following names:--
+
+  A _treble infinite_ number of lines, that is, all lines which satisfy
+  one condition, are said to form a _complex of lines_; e.g. all lines
+  cutting a given line, or all lines touching a surface.
+
+  A _double infinite_ number of lines, that is, all lines which satisfy
+  two conditions, or which are common to two complexes, are said to form
+  a _congruence of lines_; e.g. all lines in a plane, or all lines
+  cutting two curves, or all lines cutting a given curve twice.
+
+  A _single infinite_ number of lines, that is, all lines which satisfy
+  three conditions, or which belong to three complexes, form a _ruled
+  surface_; e.g. one set of lines on a ruled quadric surface, or
+  developable surfaces which are formed by the tangents to a curve.
+
+  It follows that all lines in which corresponding planes in two
+  projective pencils meet form a congruence. We shall see this
+  congruence consists of all lines which cut a twisted cubic twice, or
+  of all _secants_ to a twisted cubic.
+
+  S 102. Let l1 be the line S1S2 as a line in the pencil S1. To it
+  corresponds a line l2 in S2. _At each of the centres two corresponding
+  lines meet._ The two axial pencils with l1 and l2 as axes are
+  projective, and, as, their axes meet at S2, the intersections of
+  corresponding planes form a cone of the second order (S 58), with S2
+  as centre. If [pi]1 and [pi]2 be corresponding planes, then their
+  intersection will be a line p2 which passes through S2. Corresponding
+  to it in S1 will be a line p1 which lies in the plane [pi]1, and which
+  therefore meets p2 at some point P. Conversely, if p2 be any line in
+  S2 which meets its corresponding line p1 at a point P, then to the
+  plane l2p2 will correspond the plane l1p1, that is, the plane S1S2P.
+  These planes intersect in p2, so that p2 is a line on the quadric cone
+  generated by the axial pencils l1 and l2. Hence:--
+
+  _All lines in one pencil which meet their corresponding lines in the
+  other form a cone of the second order which has its centre at the
+  centre of the first pencil, and passes through the centre of the
+  second._
+
+  From this follows that the points in which corresponding rays meet lie
+  on two cones of the second order which have the ray joining their
+  centres in common, and form therefore, together with the line S1S2 or
+  l1, the intersection of these cones. Any plane cuts each of the cones
+  in a conic. These two conics have necessarily that point in common in
+  which it cuts the line l1, and therefore besides either one or three
+  other points. It follows that the curve is of the third order as a
+  plane may cut it in three, but not in more than three, points.
+  Hence:--
+
+  _The locus of points in which corresponding lines on two projective
+  pencils meet is a curve of the third order or a "twisted cubic" k,
+  which passes through the centres of the pencils, and which appears as
+  the intersection of two cones of the second order, which have one line
+  in common._
+
+  _A line belonging to the congruence determined by the pencils is a
+  secant of the cubic; it has two, or one, or no points in common with
+  this cubic, and is called accordingly a secant proper, a tangent, or a
+  secant improper of the cubic._ A secant improper may be considered, to
+  use the language of coordinate geometry, as a secant with imaginary
+  points of intersection.
+
+  S 103. If a1 and a2 be any two corresponding lines in the two pencils,
+  then corresponding planes in the axial pencils having a1 and a2 as
+  axes generate a ruled quadric surface. If P be any point on the cubic
+  k, and if p1, p2 be the corresponding rays in S1 and S2 which meet at
+  P, then to the plane a1p1 in S1 corresponds a2p2 in S2. These
+  therefore meet in a line through P.
+
+  This may be stated thus:--
+
+  _Those secants of the cubic which cut a ray a1, drawn through the
+  centre S1 of one pencil, form a ruled quadric surface which passes
+  through both centres, and which contains the twisted cubic k. Of such
+  surfaces an infinite number exists. Every ray through S1 or S2 which
+  is not a secant determines one of them._
+
+  If, however, the rays a1 and a2 are secants meeting at A, then the
+  ruled quadric surface becomes a cone of the second order, having A as
+  centre. Or _all lines of the congruence which pass through a point on
+  the twisted cubic k form a cone of the second order_. In other words,
+  the projection of a twisted cubic from any point in the curve on to
+  any plane is a conic.
+
+  If a1 is not a secant, but made to pass through any point Q in space,
+  the ruled quadric surface determined by a1 will pass through Q. _There
+  will therefore be one line of the congruence passing through Q, and
+  only one._ For if two such lines pass through Q, then the lines S1Q
+  and S2Q will be corresponding lines; hence Q will be a point on the
+  cubic k, and an infinite number of secants will pass through it.
+  Hence:--
+
+  _Through every point in space not on the twisted cubic one and only
+  one secant to the cubic can be drawn._
+
+  S 104. The fact that all the secants through a point on the cubic form
+  a quadric cone shows that the centres of the projective pencils
+  generating the cubic are not distinguished from any other points on
+  the cubic. If we take any two points S, S' on the cubic, and draw the
+  secants through each of them, we obtain two quadric cones, which have
+  the line SS' in common, and which intersect besides along the cubic.
+  If we make these two pencils having S and S' as centres projective by
+  taking four rays on the one cone as corresponding to the four rays on
+  the other which meet the first on the cubic, the correspondence is
+  determined. These two pencils will generate a cubic, and the two cones
+  of secants having S and S' as centres will be identical with the above
+  cones, for each has five rays in common with one of the first, viz.
+  the line SS' and the four lines determined for the correspondence;
+  therefore these two cones intersect in the original cubic. This gives
+  the theorem:--
+
+  _On a twisted cubic any two points may be taken as centres of
+  projective pencils which generate the cubic, corresponding planes
+  being those which meet on the same secant._
+
+  Of the two projective pencils at S and S' we may keep the first fixed,
+  and move the centre of the other along the curve. The pencils will
+  hereby remain projective, and a plane [alpha] in S will be cut by its
+  corresponding plane [alpha]' always in the same secant a. Whilst S'
+  moves along the curve the plane [alpha]' will turn about a, describing
+  an axial pencil.
+
+  AUTHORITIES.--In this article we have given a purely geometrical
+  theory of conics, cones of the second order, quadric surfaces, &c. In
+  doing so we have followed, to a great extent, Reye's _Geometrie der
+  Lage_, and to this excellent work those readers are referred who wish
+  for a more exhaustive treatment of the subject. Other works especially
+  valuable as showing the development of the subject are: Monge,
+  _Geometrie descriptive_: Carnot, _Geometrie de position_ (1803),
+  containing a theory of transversals; Poncelet's great work _Traite des
+  proprietes projectives des figures_ (1822); Mobins, _Barycentrischer
+  Calcul_ (1826); Steiner, _Abhangigkeit geometrischer Gestalten_
+  (1832), containing the first full discussion of the projective
+  relations between rows, pencils, &c.; Von Staudt, _Geometrie der Lage_
+  (1847) and _Beitrage zur Geometrie der Lage_ (1856-1860), in which a
+  system of geometry is built up from the beginning without any
+  reference to number, so that ultimately a number itself gets a
+  geometrical definition, and in which imaginary elements are
+  systematically introduced into pure geometry; Chasles, _Apercu
+  historique_ (1837), in which the author gives a brilliant account of
+  the progress of modern geometrical methods, pointing out the
+  advantages of the different purely geometrical methods as compared
+  with the analytical ones, but without taking as much account of the
+  German as of the French authors; Id., _Rapport sur les progres de la
+  geometrie_ (1870), a continuation of the _Apercu_; Id., _Traite de
+  geometrie superieure_ (1852); Cremona, _Introduzione ad una teoria
+  geometrica delle curve piane_ (1862) and its continuation _Preliminari
+  di una teoria geometrica delle superficie_ (German translations by
+  Curtze). As more elementary books, we mention: Cremona, _Elements of
+  Projective Geometry_, translated from the Italian by C. Leudesdorf
+  (2nd ed., 1894); J.W. Russell, _Pure Geometry_ (2nd ed., 1905).
+       (O. H.)
+
+
+III. DESCRIPTIVE GEOMETRY
+
+This branch of geometry is concerned with the methods for representing
+solids and other figures in three dimensions by drawings in one plane.
+The most important method is that which was invented by Monge towards
+the end of the 18th century. It is based on parallel projections to a
+plane by rays perpendicular to the plane. Such a projection is called
+orthographic (see PROJECTION, S 18). If the plane is horizontal the
+projection is called the plan of the figure, and if the plane is
+vertical the elevation. In Monge's method a figure is represented by its
+plan and elevation. It is therefore often called drawing in plan and
+elevation, and sometimes simply orthographic projection.
+
+  S 1. We suppose then that we have two planes, one horizontal, the
+  other vertical, and these we call the planes of plan and of elevation
+  respectively, or the horizontal and the vertical plane, and denote
+  them by the letters [pi]1 and [pi]2. Their line of intersection is
+  called the axis, and will be denoted by xy.
+
+  If the surface of the drawing paper is taken as the plane of the plan,
+  then the vertical plane will be the plane perpendicular to it through
+  the axis xy. To bring this also into the plane of the drawing paper we
+  turn it about the axis till it coincides with the horizontal plane.
+  This process of turning one plane down till it coincides with another
+  is called _rabatting_ one to the other. Of course there is no
+  necessity to have one of the two planes horizontal, but even when this
+  is not the case it is convenient to retain the above names.
+
+  [Illustration: FIG. 37.]
+
+  [Illustration: FIG. 38.]
+
+  The whole arrangement will be better understood by referring to fig.
+  37. A point A in space is there projected by the perpendicular AA1 and
+  AA2 to the planes [pi]1 and [pi]2 so that A1 and A2 are the horizontal
+  and vertical projections of A.
+
+  If we remember that a line is perpendicular to a plane that is
+  perpendicular to every line in the plane if only it is perpendicular
+  to any two intersecting lines in the plane, we see that the axis which
+  is perpendicular both to AA1 and to AA2 is also perpendicular to A1A0
+  and to A2A0 because these four lines are all in the same plane. Hence,
+  if the plane [pi]2 be turned about the axis till it coincides with the
+  plane [pi]1, then A2A0 will be the continuation of A1A0. This position
+  of the planes is represented in fig. 38, in which the line A1A2 is
+  perpendicular to the axis x.
+
+  Conversely any two points A1, A2 in a line perpendicular to the axis
+  will be the projections of some point in space when the plane [pi]2 is
+  turned about the axis till it is perpendicular to the plane [pi]1,
+  because in this position the two perpendiculars to the planes [pi]1
+  and [pi]2 through the points A1 and A2 will be in a plane and
+  therefore meet at some point A.
+
+  _Representation of Points._--We have thus the following method of
+  representing in a single plane the position of points in space:--_we
+  take in the plane a line xy as the axis, and then any pair of points
+  A1, A2 in the plane on a line perpendicular to the axis represent a
+  point A in space_. If the line A1A2 cuts the axis at A0, and if at A1
+  a perpendicular be erected to the plane, then the point A will be in
+  it at a height A1A = A0A2 above the plane. This gives the position of
+  the point A relative to the plane [pi]1. In the same way, if in a
+  perpendicular to [pi]2 through A2 a point A be taken such that A2A =
+  A0A1, then this will give the point A relative to the plane [pi]2.
+
+  [Illustration: FIG. 39.]
+
+  S 2. The two planes [pi]1, [pi]2 in their original position divide
+  space into four parts. These are called the four quadrants. We suppose
+  that the plane [pi]2 is turned as indicated in fig. 37, so that the
+  point P comes to Q and R to S, then the quadrant in which the point A
+  lies is called the first, and we say that in the first quadrant a
+  point lies above the horizontal and in front of the vertical plane.
+  Now we go round the axis in the sense in which the plane [pi]2 is
+  turned and come in succession to the second, third and fourth
+  quadrant. In the second a point lies above the plane of the plan and
+  behind the plane of elevation, and so on. In fig. 39, which represents
+  a side view of the planes in fig. 37 the quadrants are marked, and in
+  each a point with its projection is taken. Fig. 38 shows how these are
+  represented when the plane [pi]2 is turned down. We see that
+
+  _A point lies in the first quadrant if the plan lies below, the
+  elevation above the axis; in the second if plan and elevation both lie
+  above; in the third if the plan lies above, the elevation below; in
+  the fourth if plan and elevation both lie below the axis._
+
+  _If a point lies in the horizontal plane_, its elevation lies in the
+  axis and the plan coincides with the point itself. _If a point lies in
+  the vertical plane_, its plan lies in the axis and the elevation
+  coincides with the point itself. _If a point lies in the axis_, both
+  its plan and elevation lie in the axis and coincide with it.
+
+  Of each of these propositions, which will easily be seen to be true,
+  the converse holds also.
+
+  S 3. _Representation of a Plane._--As we are thus enabled to represent
+  points in a plane, we can represent any finite figure by representing
+  its separate points. It is, however, not possible to represent a plane
+  in this way, for the projections of its points completely cover the
+  planes [pi]1 and [pi]2, and no plane would appear different from any
+  other. But any plane [alpha] cuts each of the planes [pi]1, [pi]2 in a
+  line. These are called the traces of the plane. They cut each other in
+  the axis at the point where the latter cuts the plane [alpha].
+
+  _A plane is determined by its two traces, which are two lines that
+  meet on the axis_, and, conversely, _any two lines which meet on the
+  axis determine a plane_.
+
+  _If the plane is parallel to the axis its traces are parallel to the
+  axis._ Of these one may be at infinity; then the plane will cut one of
+  the planes of projection at infinity and will be parallel to it. Thus
+  a plane parallel to the horizontal plane of the plan has only one
+  finite trace, viz. that with the plane of elevation.
+
+  [Illustration: FIG. 40.]
+
+  _If the plane passes through the axis both its traces coincide with
+  the axis._ This is the only case in which the representation of the
+  plane by its two traces fails. A third plane of projection is
+  therefore introduced, which is best taken perpendicular to the other
+  two. We call it simply the third plane and denote it by [pi]3. As it
+  is perpendicular to [pi]1, it may be taken as the plane of elevation,
+  its line of intersection [gamma] with [pi]1 being the axis, and be
+  turned down to coincide with [pi]1. This is represented in fig. 40. OC
+  is the axis xy whilst OA and OB are the traces of the third plane.
+  They lie in one line [gamma]. The plane is rabatted about [gamma] to
+  the horizontal plane. A plane [alpha] through the axis xy will then
+  show in it a trace [alpha]3. In fig. 40 the lines OC and OP will thus
+  be the traces of a plane through the axis xy, which makes an angle POQ
+  with the horizontal plane.
+
+  We can also find the trace which any other plane makes with [pi]3. In
+  rabatting the plane [pi]3 its trace OB with the plane [pi]2 will come
+  to the position OD. Hence a plane [beta] having the traces CA and CB
+  will have with the third plane the trace [beta]3, or AD if OD = OB.
+
+  It also follows immediately that--
+
+  _If a plane [alpha] is perpendicular to the horizontal plane, then
+  every point in it has its horizontal projection in the horizontal
+  trace of the plane_, as all the rays projecting these points lie in
+  the plane itself.
+
+  _Any plane which is perpendicular to the horizontal plane has its
+  vertical trace perpendicular to the axis._
+
+  _Any plane which is perpendicular to the vertical plane has its
+  horizontal trace perpendicular to the axis and the vertical
+  projections of all points in the plane lie in this trace._
+
+  S 4. _Representation of a Line._--A line is determined either by two
+  points in it or by two planes through it. We get accordingly two
+  representations of it either by projections or by traces.
+
+  First.--_A line a is represented by its projections a1 and a2 on the
+  two planes [pi]1 and [pi]2._ These may be any two lines, for, bringing
+  the planes [pi]1, [pi]2 into their original position, the planes
+  through these lines perpendicular to [pi]1 and [pi]2 respectively will
+  intersect in some line a which has a1, a2 as its projections.
+
+  Secondly.--_A line a is represented by its traces--that is, by the
+  points in which it cuts the two planes [pi]1, [pi]2._ Any two points
+  may be taken as the traces of a line in space, for it is determined
+  when the planes are in their original position as the line joining the
+  two traces. This representation becomes undetermined if the two traces
+  coincide in the axis. In this case we again use a third plane, or else
+  the projections of the line.
+
+  The fact that there are different methods of representing points and
+  planes, and hence two methods of representing lines, suggests the
+  principle of duality (section ii., _Projective Geometry_, S 41). It is
+  worth while to keep this in mind. It is also worth remembering that
+  traces of planes or lines always lie in the planes or lines which they
+  represent. Projections do not as a rule do this excepting when the
+  point or line projected lies in one of the planes of projection.
+
+  Having now shown how to represent points, planes and lines, we have to
+  state the conditions which must hold in order that these elements may
+  lie one in the other, or else that the figure formed by them may
+  possess certain metrical properties. It will be found that the former
+  are very much simpler than the latter.
+
+  Before we do this, however, we shall explain the notation used; for it
+  is of great importance to have a systematic notation. We shall denote
+  points in space by capitals A, B, C; planes in space by Greek letters
+  [alpha], [beta], [gamma]; lines in space by small letters a, b, c;
+  horizontal projections by suffixes 1, like A1, a1; vertical
+  projections by suffixes 2, like A2, a2; traces by single and double
+  dashes [alpha]' [alpha]", a', a". Hence P1 will be the horizontal
+  projection of a point P in space; a line a will have the projections
+  a1, a2 and the traces a' and a"; a plane [alpha] has the traces
+  [alpha]' and [alpha]".
+
+  S 5. _If a point lies in a line, the projections of the point lie in
+  the projections of the line._
+
+  _If a line lies in a plane, the traces of the line lie in the traces
+  of the plane._
+
+  These propositions follow at once from the definitions of the
+  projections and of the traces.
+
+  If a point lies in two lines its projections must lie in the
+  projections of both. Hence
+
+  _If two lines, given by their projections, intersect, the intersection
+  of their planes and the intersection of their elevations must lie in a
+  line perpendicular to the axis_, because they must be the projections
+  of the point common to the two lines.
+
+  Similarly--_If two lines given by their traces lie in the same plane
+  or intersect, then the lines joining their horizontal and vertical
+  traces respectively must meet on the axis_, because they must be the
+  traces of the plane through them.
+
+  S 6. _To find the projections of a line which joins two points A, B
+  given by their projections A1, A2 and B1, B2_, we join A1, B1 and A2,
+  B2; these will be the projections required. For example, the traces of
+  a line are two points in the line whose projections are known or at
+  all events easily found. They are the traces themselves and the feet
+  of the perpendiculars from them to the axis.
+
+  Hence _if a' a" (fig. 41) are the traces of a line a, and if the
+  perpendiculars from them cut the axis in P and Q respectively, then
+  the line a'Q will be the horizontal and a"P the vertical projection of
+  the line_.
+
+  [Illustration: FIG. 41.]
+
+  Conversely, if the projections a1, a2 of a line are given, and if
+  these cut the axis in Q and P respectively, then _the perpendiculars
+  Pa' and Qa" to the axis drawn through these points cut the projections
+  a1 and a2 in the traces a' and a"_.
+
+  _To find the line of intersection of two planes_, we observe that this
+  line lies in both planes; its traces must therefore lie in the traces
+  of both. Hence the points where the horizontal traces of the given
+  planes meet will be the horizontal, and the point where the vertical
+  traces meet the vertical trace of the line required.
+
+  S 7. _To decide whether a point A, given by its projections, lies in a
+  plane [alpha], given by its traces_, we draw a line p by joining A to
+  some point in the plane [alpha] and determine its traces. If these lie
+  in the traces of the plane, then the line, and therefore the point A,
+  lies in the plane; otherwise not. This is conveniently done by joining
+  A1 to some point p' in the trace [alpha]'; this gives p1; and the
+  point where the perpendicular from p' to the axis cuts the latter we
+  join to A2; this gives p2. If the vertical trace of this line lies in
+  the vertical trace of the plane, then, and then only, does the line p,
+  and with it the point A, lie in the plane [alpha].
+
+  S 8. _Parallel planes have parallel traces_, because parallel planes
+  are cut by any plane, hence also by [pi]1 and by [pi]2, in parallel
+  lines.
+
+  _Parallel lines have parallel projections_, because points at infinity
+  are projected to infinity.
+
+  _If a line is parallel to a plane, then lines through the traces of
+  the line and parallel to the traces of the plane must meet on the
+  axis_, because these lines are the traces of a plane parallel to the
+  given plane.
+
+  S 9. _To draw a plane through two intersecting lines or through two
+  parallel lines_, we determine the traces of the lines; the lines
+  joining their horizontal and vertical traces respectively will be the
+  horizontal and vertical traces of the plane. They will meet, at a
+  finite point or at infinity, on the axis if the lines do intersect.
+
+  _To draw a plane through a line and a point without the line_, we join
+  the given point to any point in the line and determine the plane
+  through this and the given line.
+
+  _To draw a plane through three points which are not in a line_, we
+  draw two of the lines which each join two of the given points and draw
+  the plane through them. If the traces of all three lines AB, BC, CA be
+  found, these must lie in two lines which meet on the axis.
+
+  S 10. We have in the last example got more points, or can easily get
+  more points, than are necessary for the determination of the figure
+  required--in this case the traces of the plane. This will happen in a
+  great many constructions and is of considerable importance. It may
+  happen that some of the points or lines obtained are not convenient in
+  the actual construction. The horizontal traces of the lines AB and AC
+  may, for instance, fall very near together, in which case the line
+  joining them is not well defined. Or, one or both of them may fall
+  beyond the drawing paper, so that they are practically non-existent
+  for the construction. In this case the traces of the line BC may be
+  used. Or, if the vertical traces of AB and AC are both in convenient
+  position, so that the vertical trace of the required plane is found
+  and one of the horizontal traces is got, then we may join the latter
+  to the point where the vertical trace cuts the axis.
+
+  The draughtsman must remember that the lines which he draws are not
+  mathematical lines without thickness, and therefore every drawing is
+  affected by some errors. It is therefore very desirable to be able
+  constantly to check the latter. Such checks always present themselves
+  when the same result can be obtained by different constructions, or
+  when, as in the above case, some lines must meet on the axis, or if
+  three points must lie in a line. A careful draughtsman will always
+  avail himself of these checks.
+
+  S 11. _To draw a plane through a given point parallel to a given plane
+  [alpha]_, we draw through the point two lines which are parallel to
+  the plane [alpha], and determine the plane through them; or, as we
+  know that the traces of the required plane are parallel to those of
+  the given one (S 8), we need only draw one line l through the point
+  parallel to the plane and find one of its traces, say the vertical
+  trace l"; a line through this parallel to the vertical trace of
+  [alpha] will be the vertical trace [beta]" of the required plane
+  [beta], and a line parallel to the horizontal trace of [alpha] meeting
+  [beta]" on the axis will be the horizontal trace [beta]'.
+
+  [Illustration: FIG. 42.]
+
+  Let A1 A2 (fig. 42) be the given point, [alpha]' [alpha]" the given
+  plane, a line l1 through A1, parallel to [alpha]' and a horizontal
+  line l2 through A2 will be the projections of a line l through A
+  parallel to the plane, because the horizontal plane through this line
+  will cut the plane [alpha] in a line c which has its horizontal
+  projection c1 parallel to [alpha]'.
+
+  S 12. We now come to the metrical properties of figures.
+
+  _A line is perpendicular to a plane if the projections of the line are
+  perpendicular to the traces of the plane._ We prove it for the
+  horizontal projection. If a line p is perpendicular to a plane
+  [alpha], every plane through p is perpendicular to [alpha]; hence also
+  the vertical plane which projects the line p to p1. As this plane is
+  perpendicular both to the horizontal plane and to the plane [alpha],
+  it is also perpendicular to their intersection--that is, to the
+  horizontal trace of [alpha]. It follows that every line in this
+  projecting plane, therefore also p1, the plan of p, is perpendicular
+  to the horizontal trace of [alpha].
+
+  _To draw a plane through a given point A perpendicular to a given line
+  p_, we first draw through some point O in the axis lines [gamma]',
+  [gamma]" perpendicular respectively to the projections p1 and p2 of
+  the given line. These will be the traces of a plane [gamma] which is
+  perpendicular to the given line. We next draw through the given point
+  A a plane parallel to the plane [gamma]; this will be the plane
+  required.
+
+  Other metrical properties depend on the determination of the real size
+  or shape of a figure.
+
+  In general the projection of a figure differs both in size and shape
+  from the figure itself. But figures in a plane parallel to a plane of
+  projection will be identical with their projections, and will thus be
+  given in their true dimensions. In other cases there is the problem,
+  constantly recurring, either to find the true shape and size of a
+  plane figure when plan and elevation are given, or, conversely, to
+  find the latter from the known true shape of the figure itself. To do
+  this, the plane is turned about one of its traces till it is laid down
+  into that plane of projection to which the trace belongs. This is
+  technically called rabatting the plane respectively into the plane of
+  the plan or the elevation. As there is no difference in the treatment
+  of the two cases, we shall consider only the case of rabatting a plane
+  [alpha] into the plane of the plan. The plan of the figure is a
+  parallel (orthographic) projection of the figure itself. The results
+  of parallel projection (see PROJECTION, SS 17 and 18) may therefore
+  now be used. The trace [alpha]' will hereby take the place of what
+  formerly was called the axis of projection. Hence we see that
+  corresponding points in the plan and in the rabatted plane are joined
+  by lines which are perpendicular to the trace [alpha]' and that
+  corresponding lines meet on this trace. We also see that the
+  correspondence is completely determined if we know for one point or
+  one line in the plan the corresponding point or line in the rabatted
+  plane.
+
+  Before, however, we treat of this we consider some special cases.
+
+  S 13. _To determine the distance between two points A, B given by
+  their projections A1, B1 and A2, B2, or, in other words, to determine
+  the true length of a line the plan and elevation of which are given._
+
+  [Illustration: FIG. 43.]
+
+  _Solution._--The two points A, B in space lie vertically above their
+  plans A1, B1 (fig. 43) and A1A = A0A2, B1B = B0B2. The four points A,
+  B, A1, B1 therefore form a plane quadrilateral on the base A1B1 and
+  having right angles at the base. This plane we rabatt about A1B1 by
+  drawing A1A and B1B perpendicular to A1B1 and making A1A = A0A2, B1B =
+  B0B2. Then AB will give the length required.
+
+  The construction might have been performed in the elevation by making
+  A2A = A0A1 and B2B = B0B1 on lines perpendicular to A2B2. Of course AB
+  must have the same length in both cases.
+
+  This figure may be turned into a model. Cut the paper along A1A, AB
+  and BB1, and fold the piece A1ABB1 over along A1B1 till it stands
+  upright at right angles to the horizontal plane. The points A, B will
+  then be in their true position in space relative to [pi]1. Similarly
+  if B2BAA2 be cut out and turned along A2B2 through a right angle we
+  shall get AB in its true position relative to the plane [pi]2. Lastly
+  we fold the whole plane of the paper along the axis x till the plane
+  [pi]2 is at right angles to [pi]1. In this position the two sets of
+  points AB will coincide if the drawing has been accurate.
+
+  Models of this kind can be made in many cases and their construction
+  cannot be too highly recommended in order to realize orthographic
+  projection.
+
+  S 14. _To find the angle between two given lines a, b of which the
+  projections a1, b1 and a2, b2 are given._
+
+  [Illustration: FIG. 44.]
+
+  _Solution._--Let a1, b1 (fig. 44) meet in P1, a2, b2 in T, then if the
+  line P1T is not perpendicular to the axis the two lines will not meet.
+  In this case we draw a line parallel to b to meet the line a. This is
+  easiest done by drawing first the line P1P2 perpendicular to the axis
+  to meet a2 in P2, and then drawing through P2 a line c2 parallel to
+  b2; then b1, c2 will be the projections of a line c which is parallel
+  to b and meets a in P. The plane [alpha] which these two lines
+  determine we rabatt to the plan. We determine the traces a' and c' of
+  the lines a and c; then a'c' is the trace [alpha]' of their plane. On
+  rabatting the point P comes to a point S on the line P1Q perpendicular
+  to a'c', so that QS = QP. But QP is the hypotenuse of a triangle PP1Q
+  with a right angle P1. This we construct by making QR = P0P2; then P1R
+  = PQ. The lines a'S and c'S will therefore include angles equal to
+  those made by the given lines. It is to be remembered that two lines
+  include two angles which are supplementary. Which of these is to be
+  taken in any special case depends upon the circumstances.
+
+  _To determine the angle between a line and a plane_, we draw through
+  any point in the line a perpendicular to the plane (S 12) and
+  determine the angle between it and the given line. The complement of
+  this angle is the required one.
+
+  _To determine the angle between two planes_, we draw through any point
+  two lines perpendicular to the two planes and determine the angle
+  between the latter as above.
+
+  In special cases it is simpler to determine at once the angle between
+  the two planes by taking a plane section perpendicular to the
+  intersection of the two planes and rabatt this. This is especially the
+  case if one of the planes is the horizontal or vertical plane of
+  projection.
+
+  Thus in fig. 45 the angle P1QR is the angle which the plane [alpha]
+  makes with the horizontal plane.
+
+  S 15. We return to the general case of rabatting a plane [alpha] of
+  which the traces [alpha]' [alpha]" are given.
+
+  [Illustration: FIG. 45.]
+
+  Here it will be convenient to determine first the position which the
+  trace [alpha]"--which is a line in [alpha]--assumes when rabatted.
+  Points in this line coincide with their elevations. Hence it is given
+  in its true dimension, and we can measure off along it the true
+  distance between two points in it. If therefore (fig. 45) P is any
+  point in [alpha]" originally coincident with its elevation P2, and if
+  O is the point where [alpha]" cuts the axis xy, so that O is also in
+  [alpha]', then the point P will after rabatting the plane assume such
+  a position that OP = OP2. At the same time the plan is an orthographic
+  projection of the plane [alpha]. Hence the line joining P to the plan
+  P1 will after rabatting be perpendicular to [alpha]'. But P1 is known;
+  it is the foot of the perpendicular from P2 to the axis xy. We draw
+  therefore, to find P, from P1 a perpendicular P1Q to [alpha]' and find
+  on it a point P such that OP = OP2. Then the line OP will be the
+  position of [alpha]" when rabatted. This line corresponds therefore to
+  the plan of [alpha]"--that is, to the axis xy, corresponding points on
+  these lines being those which lie on a perpendicular to [alpha]'.
+
+  We have thus one pair of corresponding lines and can now find for any
+  point B1 in the plan the corresponding point B in the rabatted plane.
+  We draw a line through B1, say B1P1, cutting [alpha]' in C. To it
+  corresponds the line CP, and the point where this is cut by the
+  projecting ray through B1, perpendicular to [alpha]', is the required
+  point B.
+
+  Similarly any figure in the rabatted plane can be found when the plan
+  is known; but this is usually found in a different manner without any
+  reference to the general theory of parallel projection. As this method
+  and the reasoning employed for it have their peculiar advantages, we
+  give it also.
+
+  Supposing the planes [pi]1 and [pi]2 to be in their positions in space
+  perpendicular to each other, we take a section of the whole figure by
+  a plane perpendicular to the trace [alpha]' about which we are going
+  to rabatt the plane [alpha]. Let this section pass through the point Q
+  in [alpha]'. Its traces will then be the lines QP1 and P1P2 (fig. 9).
+  These will be at right angles, and will therefore, together with the
+  section QP2 of the plane [alpha], form a right-angled triangle QP1P2
+  with the right angle at P1, and having the sides P1Q and P1P2 which
+  both are given in their true lengths. This triangle we rabatt about
+  its base P1Q, making P1R = P1P2. The line QR will then give the true
+  length of the line QP in space. If now the plane [alpha] be turned
+  about [alpha]' the point P will describe a circle about Q as centre
+  with radius QP = QR, in a plane perpendicular to the trace [alpha]'.
+  Hence when the plane [alpha] has been rabatted into the horizontal
+  plane the point P will lie in the perpendicular P1Q to [alpha]', so
+  that QP = QR.
+
+  If A1 is the plan of a point A in the plane [alpha], and if A1 lies in
+  QP1, then the point A will lie vertically above A1 in the line QP. On
+  turning down the triangle QP1P2, the point A will come to A0, the line
+  A1A0 being perpendicular to QP1. Hence A will be a point in QP such
+  that QA = QA0.
+
+  If B1 is the plan of another point, but such that A1B1 is parallel to
+  [alpha]', then the corresponding line AB will also be parallel to
+  [alpha]'. Hence, if through A a line AB be drawn parallel to [alpha]',
+  and B1B perpendicular to [alpha]', then their intersection gives the
+  point B. Thus of any point given in plan the real position in the
+  plane [alpha], when rabatted, can be found by this second method. This
+  is the one most generally given in books on geometrical drawing. The
+  first method explained is, however, in most cases preferable as it
+  gives the draughtsman a greater variety of constructions. It requires
+  a somewhat greater amount of theoretical knowledge.
+
+  If instead of our knowing the plan of a figure the latter is itself
+  given, then the process of finding the plan is the reverse of the
+  above and needs little explanation. We give an example.
+
+  S 16. _It is required to draw the plan and elevation of a polygon of
+  which the real shape and position in a given plane [alpha] are known._
+
+  We first rabatt the plane [alpha] (fig. 46) as before so that P1 comes
+  to P, hence OP1 to OP. Let the given polygon in [alpha] be the figure
+  ABCDE. We project, not the vertices, but the sides. To project the
+  line AB, we produce it to cut [alpha]' in F and OP in G, and draw GG1
+  perpendicular to [alpha]'; then G1 corresponds to G, therefore FG1 to
+  FG. In the same manner we might project all the other sides, at least
+  those which cut OF and OP in convenient points. It will be best,
+  however, first to produce all the sides to cut OP and [alpha]' and
+  then to draw all the projecting rays through A, B, C ... perpendicular
+  to [alpha]', and in the same direction the lines G, G1, &c. By drawing
+  FG we get the points A1, B1 on the projecting ray through A and B. We
+  then join B to the point M where BC produced meets the trace [alpha]'.
+  This gives C1. So we go on till we have found E1. The line A1 E1 must
+  then meet AE in [alpha]', and this gives a check. If one of the sides
+  cuts [alpha]' or OP beyond the drawing paper this method fails, but
+  then we may easily find the projection of some other line, say of a
+  diagonal, or directly the projection of a point, by the former
+  methods. The diagonals may also serve to check the drawing, for two
+  corresponding diagonals must meet in the trace [alpha]'.
+
+  [Illustration: FIG. 46.]
+
+  Having got the plan we easily find the elevation. The elevation of G
+  is above G1 in [alpha]", and that of F is at F2 in the axis. This
+  gives the elevation F2G2 of FG and in it we get A2B2 in the verticals
+  through A1 and B1. As a check we have OG = OG2. Similarly the
+  elevation of the other sides and vertices are found.
+
+  S 17. We proceed to give some applications of the above principles to
+  the representation of solids and of the solution of problems connected
+  with them.
+
+  _Of a pyramid are given its base, the length of the perpendicular from
+  the vertex to the base, and the point where this perpendicular cuts
+  the base; it is required first to develop the whole surface of the
+  pyramid into one plane, and second to determine its section by a plane
+  which cuts the plane of the base in a given line and makes a given
+  angle with it._
+
+  1. As the planes of projection are not given we can take them as we
+  like, and we select them in such a manner that the solution becomes as
+  simple as possible. We take the plane of the base as the horizontal
+  plane and the vertical plane perpendicular to the plane of the
+  section. Let then (fig. 47) ABCD be the base of the pyramid, V1 the
+  plan of the vertex, then the elevations of A, B, C, D will be in the
+  axis at A2, B2, C2, D2, and the vertex at some point V2 above V1 at a
+  known distance from the axis. The lines V1A, V1B, &c., will be the
+  plans and the lines V2A2, V2B2, &c., the elevations of the edges of
+  the pyramid, of which thus plan and elevation are known.
+
+  We develop the surface into the plane of the base by turning each
+  lateral face about its lower edge into the horizontal plane by the
+  method used in S 14. If one face has been turned down, say ABV to ABP,
+  then the point Q to which the vertex of the next face BCV comes can be
+  got more simply by finding on the line V1Q perpendicular to BC the
+  point Q such that BQ = BP, for these lines represent the same edge BV
+  of the pyramid. Next R is found by making CR = CQ, and so on till we
+  have got the last vertex--in this case S. The fact that AS must equal
+  AP gives a convenient check.
+
+  2. The plane [alpha] whose section we have to determine has its
+  horizontal trace given perpendicular to the axis, and its vertical
+  trace makes the given angle with the axis. This determines it. To find
+  the section of the pyramid by this plane there are two methods
+  applicable: we find the sections of the plane either with the faces or
+  with the edges of the pyramid. We use the latter.
+
+  As the plane [alpha] is perpendicular to the vertical plane, the trace
+  [alpha]" contains the projection of every figure in it; the points
+  E2, F2, G2, H2 where this trace cuts the elevations of the edges will
+  therefore be the elevations of the points where the edges cut [alpha].
+  From these we find the plans E1, F1, G1, H1, and by joining them the
+  plan of the section. If from E1, F1 lines be drawn perpendicular to
+  AB, these will determine the points E, F on the developed face in
+  which the plane [alpha] cuts it; hence also the line EF. Similarly on
+  the other faces. Of course BF must be the same length on BP and on BQ.
+  If the plane [alpha] be rabatted to the plan, we get the real shape of
+  the section as shown in the figure in EFGH. This is done easily by
+  making F0F = OF2, &c. If the figure representing the development of
+  the pyramid, or better a copy of it, is cut out, and if the lateral
+  faces be bent along the lines AB, BC, &c., we get a model of the
+  pyramid with the section marked on its faces. This may be placed on
+  its plan ABCD and the plane of elevation bent about the axis x. The
+  pyramid stands then in front of its elevations. If next the plane
+  [alpha] with a hole cut out representing the true section be bent
+  along the trace [alpha]' till its edge coincides with [alpha]", the
+  edges of the hole ought to coincide with the lines EF, FG, &c., on the
+  faces.
+
+  S 18. Polyhedra like the pyramid in S 17 are represented by the
+  projections of their edges and vertices. But solids bounded by curved
+  surfaces, or surfaces themselves, cannot be thus represented.
+
+  For a surface we may use, as in case of the plane, its traces--that
+  is, the curves in which it cuts the planes of projection. We may also
+  project points and curves on the surface. A ray cuts the surface
+  generally in more than one point; hence it will happen that some of
+  the rays touch the surface, if two of these points coincide. The
+  points of contact of these rays will form some curve on the surface,
+  and this will appear from the centre of projection as the boundary of
+  the surface or of part of the surface. The outlines of all surfaces of
+  solids which we see about us are formed by the points at which rays
+  through our eye touch the surface. The projections of these contours
+  are therefore best adapted to give an idea of the shape of a surface.
+
+  [Illustration: FIG. 47.]
+
+  Thus the tangents drawn from any finite centre to a sphere form a
+  right circular cone, and this will be cut by any plane in a conic. It
+  is often called the projection of a sphere, but it is better called
+  the contour-line of the sphere, as it is the boundary of the
+  projections of all points on the sphere.
+
+  If the centre is at infinity the tangent cone becomes a right circular
+  cylinder touching the sphere along a great circle, and if the
+  projection is, as in our case, orthographic, then the section of this
+  cone by a plane of projection will be a circle equal to the great
+  circle of the sphere. We get such a circle in the plan and another in
+  the elevation, their centres being plan and elevation of the centre of
+  the sphere.
+
+  Similarly the rays touching a cone of the second order will lie in two
+  planes which pass through the vertex of the cone, the contour-line of
+  the projection of the cone consists therefore of two lines meeting in
+  the projection of the vertex. These may, however, be invisible if no
+  real tangent rays can be drawn from the centre of projection; and this
+  happens when the ray projecting the centre of the vertex lies within
+  the cone. In this case the traces of the cone are of importance. Thus
+  in representing a cone of revolution with a vertical axis we get in
+  the plan a circular trace of the surface whose centre is the plan of
+  the vertex of the cone, and in the elevation the contour, consisting
+  of a pair of lines intersecting in the elevation of the vertex of the
+  cone. The circle in the plan and the pair of lines in the elevation do
+  not determine the surface, for an infinite number of surfaces might be
+  conceived which pass through the circular trace and touch two planes
+  through the contour lines in the vertical plane. The surface becomes
+  only completely defined if we write down to the figure that it shall
+  represent a cone. The same holds for all surfaces. Even a plane is
+  fully represented by its traces only under the silent understanding
+  that the traces are those of a plane.
+
+  S 19. Some of the simpler problems connected with the representation
+  of surfaces are the determination of plane sections and of the curves
+  of intersection of two such surfaces. The former is constantly used in
+  nearly all problems concerning surfaces. Its solution depends of
+  course on the nature of the surface.
+
+  To determine the curve of intersection of two surfaces, we take a
+  plane and determine its section with each of the two surfaces,
+  rabatting this plane if necessary. This gives two curves which lie in
+  the same plane and whose intersections will give us points on both
+  surfaces. It must here be remembered that two curves in space do not
+  necessarily intersect, hence that the points in which their
+  projections intersect are not necessarily the projections of points
+  common to the two curves. This will, however, be the case if the two
+  curves lie in a common plane. By taking then a number of plane
+  sections of the surfaces we can get as many points on their curve of
+  intersection as we like. These planes have, of course, to be selected
+  in such a way that the sections are curves as simple as the case
+  permits of, and such that they can be easily and accurately drawn.
+  Thus when possible the sections should be straight lines or circles.
+  This not only saves time in drawing but determines all points on the
+  sections, and therefore also the points where the two curves meet,
+  with equal accuracy.
+
+  S 20. We give a few examples how these sections have to be selected. A
+  cone is cut by every plane through the vertex in lines, and if it is a
+  cone of revolution by planes perpendicular to the axis in circles.
+
+  A cylinder is cut by every plane parallel to the axis in lines, and if
+  it is a cylinder of revolution by planes perpendicular to the axis in
+  circles.
+
+  A sphere is cut by every plane in a circle.
+
+  Hence in case of two cones situated anywhere in space we take sections
+  through both vertices. These will cut both cones in lines. Similarly
+  in case of two cylinders we may take sections parallel to the axis of
+  both. In case of a sphere and a cone of revolution with vertical axis,
+  horizontal sections will cut both surfaces in circles whose plans are
+  circles and whose elevations are lines, whilst vertical sections
+  through the vertex of the cone cut the latter in lines and the sphere
+  in circles. To avoid drawing the projections of these circles, which
+  would in general be ellipses, we rabatt the plane and then draw the
+  circles in their real shape. And so on in other cases.
+
+  Special attention should in all cases be paid to those points in which
+  the tangents to the projection of the curve of intersection are
+  parallel or perpendicular to the axis x, or where these projections
+  touch the contour of one of the surfaces.     (O. H.)
+
+
+IV. ANALYTICAL GEOMETRY
+
+1. In the name _geometry_ there is a lasting record that the science had
+its origin in the knowledge that two distances may be compared by
+measurement, and in the idea that measurement must be effectual in the
+dissociation of different directions as well as in the comparison of
+distances in the same direction. The distance from an observer's eye of
+an object seen would be specified as soon as it was ascertained that a
+rod, straight to the eye and of length taken as known, could be given
+the direction of the line of vision, and had to be moved along it a
+certain number of times through lengths equal to its own in order to
+reach the object from the eye. Moreover, if a field had for two of its
+boundaries lines straight to the eye, one running from south to north
+and the other from west to east, the position of a point in the field
+would be specified if the rod, when directed west, had to be shifted
+from the point one observed number of times westward to meet the former
+boundary, and also, when directed south, had to be shifted another
+observed number of times southward to meet the latter. Comparison by
+measurement, the beginning of geometry, involved counting, the basis of
+arithmetic; and the science of number was marked out from the first as
+of geometrical importance.
+
+But the arithmetic of the ancients was inadequate as a science of
+number. Though a length might be recognized as known when measurement
+certified that it was so many times a standard length, it was not every
+length which could be thus specified in terms of the same standard
+length, even by an arithmetic enriched with the notion of fractional
+number. The idea of possible incommensurability of lengths was
+introduced into Europe by Pythagoras; and the corresponding idea of
+irrationality of number was absent from a crude arithmetic, while there
+were great practical difficulties in the way of its introduction. Hence
+perhaps it arose that, till comparatively modern times, appeal to
+arithmetical aid in geometrical reasoning was in all possible ways
+restrained. Geometry figured rather as the helper of the more difficult
+science of arithmetic.
+
+2. It was reserved for algebra to remove the disabilities of arithmetic,
+and to restore the earliest ideas of the land-measurer to the position
+of controlling ideas in geometrical investigation. This unified science
+of pure number made comparatively little headway in the hands of the
+ancients, but began to receive due attention shortly after the revival
+of learning. It expresses whole classes of arithmetical facts in single
+statements, gives to arithmetical laws the form of equations involving
+symbols which may mean any known or sought numbers, and provides
+processes which enable us to analyse the information given by an
+equation and derive from that equation other equations, which express
+laws that are in effect consequences or causes of a law started from,
+but differ greatly from it in form. Above all, for present purposes, it
+deals not only with integral and fractional number, but with number
+regarded as capable of continuous growth, just as distance is capable of
+continuous growth. The difficulty of the arithmetical expression of
+irrational number, a difficulty considered by the modern school of
+analysts to have been at length surmounted (see FUNCTION), is not vital
+to it. It can call the ratio of the diagonal of a square to a side, for
+instance, or that of the circumference of a circle to a diameter, a
+number, and let a or x denote that number, just as properly as it may
+allow either letter to denote any rational number which may be greater
+or less than the ratio in question by a difference less than any minute
+one we choose to assign.
+
+Counting only, and not the counting of objects, is of the essence of
+arithmetic, and of algebra. But it is lawful to count objects, and in
+particular to count equal lengths by measure. The widened idea is that
+even when a or x is an irrational number we may speak of a or x unit
+lengths by measure. We may give concrete interpretation to an
+algebraical equation by allowing its terms all to mean numbers of times
+the same unit length, or the same unit area, or &c. and in any equation
+lawfully derived from the first by algebraical processes we may do the
+same. Descartes in his _Geometrie_ (1637) was the first to systematize
+the application of this principle to the inherent first notions of
+geometry; and the methods which he instituted have become the most
+potent methods of all in geometrical research. It is hardly too much to
+say that, when known facts as to a geometrical figure have once been
+expressed in algebraical terms, all strictly consequential facts as to
+the figure can be deduced by almost mechanical processes. Some may well
+be unexpected consequences; and in obtaining those of which there has
+been suggestion beforehand the often bewildering labour of constant
+attention to the figure is obviated. These are the methods of what is
+now called _analytical_, or sometimes _algebraical_, _geometry_.
+
+3. The modern use of the term "analytical" in geometry has obscured, but
+not made obsolete, an earlier use, one as old as Plato. There is nothing
+algebraical in this analysis, as distinguished from synthesis, of the
+Greeks, and of the expositors of pure geometry. It has reference to an
+order of ideas in demonstration, or, more frequently, in discovering
+means to effect the geometrical construction of a figure with an
+assigned special property. We have to suppose hypothetically that the
+construction has been performed, drawing a rough figure which exhibits
+it as nearly as is practicable. We then analyse or critically examine
+the figure, treated as correct, and ascertain other properties which it
+can only possess in association with the one in question. Presently one
+of these properties will often be found which is of such a character
+that the construction of a figure possessing it is simple. The means of
+effecting synthetically a construction such as was desired is thus
+brought to light by what Plato called _analysis_. Or again, being asked
+to prove a theorem A, we ascertain that it must be true if another
+theorem B is, that B must be if C is, and so on, thus eventually finding
+that the theorem A is the consequence, through a chain of
+intermediaries, of a theorem Z of which the establishment is easy. This
+geometrical analysis is not the subject of the present article; but in
+the reasoning from form to form of an equation or system of equations,
+with the object of basing the algebraical proof of a geometrical fact on
+other facts of a more obvious character, the same logic is utilized, and
+the name "analytical geometry" is thus in part explained.
+
+4. In algebra real positive number was alone at first dealt with, and in
+geometry actual signless distance. But in algebra it became of
+importance to say that every equation of the first degree has a root,
+and the notion of negative number was introduced. The negative unit had
+to be defined as what can be added to the positive unit and produce the
+sum zero. The corresponding notion was readily at hand in geometry,
+where it was clear that a unit distance can be measured to the left or
+down from the farther end of a unit distance already measured to the
+right or up from a point O, with the result of reaching O again. Thus,
+to give full interpretation in geometry to the algebraically negative,
+it was only necessary to associate distinctness of sign with
+oppositeness of direction. Later it was discovered that algebraical
+reasoning would be much facilitated, and that conclusions as to the real
+would retain all their soundness, if a pair of imaginary units
+[+-][root]-1 of what might be called number were allowed to be
+contemplated, the pair being defined, though not separately, by the two
+properties of having the real sum 0 and the real product 1. Only in
+these two real combinations do they enter in conclusions as to the real.
+An advantage gained was that every quadratic equation, and not some
+quadratics only, could be spoken of as having two roots. These
+admissions of new units into algebra were final, as it admitted of proof
+that all equations of degrees higher than two have the full numbers of
+roots possible for their respective degrees in any case, and that every
+root has a value included in the form a + b [root]-1, with a, b, real.
+The corresponding enrichment could be given to geometry, with
+corresponding advantages and the same absence of danger, and this was
+done. On a line of measurement of distance we contemplate as existing,
+not only an infinite continuum of points at real distances from an
+origin of measurement O, but a doubly infinite continuum of points, all
+but the singly infinite continuum of real ones imaginary, and imaginary
+in conjugate pairs, a conjugate pair being at imaginary distances from
+O, which have a real arithmetic and a real geometric mean. To geometry
+enriched with this conception all algebra has its application.
+
+5. Actual geometry is one, two or three-dimensional, i.e. lineal, plane
+or solid. In one-dimensional geometry positions and measurements in a
+single line only are admitted. Now descriptive constructions for points
+in a line are impossible without going out of the line. It has therefore
+been held that there is a sense in which no science of geometry strictly
+confined to one dimension exists. But an algebra of one variable can be
+applied to the study of distances along a line measured from a chosen
+point on it, so that the idea of construction as distinct from
+measurement is not essential to a one-dimensional geometry aided by
+algebra. In geometry of two dimensions, the flat of the land-measurer,
+the passage from one point O to any other point, can be effected by two
+successive marches, one east or west and one north or south, and, as
+will be seen, an algebra of two variables suffices for geometrical
+exploitation. In geometry of three dimensions, that of space, any point
+can be reached from a chosen one by three marches, one east or west, one
+north or south, and one up or down; and we shall see that an algebra of
+three variables is all that is necessary. With three dimensions actual
+geometry stops; but algebra can supply any number of variables. Four or
+more variables have been used in ways analogous to those in which one,
+two and three variables are used for the purposes of one, two and
+three-dimensional geometry, and the results have been expressed in
+quasi-geometrical language on the supposition that a higher space can be
+conceived of, though not realized, in which four independent directions
+exist, such that no succession of marches along three of them can effect
+the same displacement of a point as a march along the fourth; and
+similarly for higher numbers than four. Thus analytical, though not
+actual, geometries exist for four and more dimensions. They are in fact
+algebras furnished with nomenclature of a geometrical cast, suggested by
+convenient forms of expression which actual geometry has, in return for
+benefits received, conferred on algebras of one, two and three
+variables.
+
+We will confine ourselves to the dimensions of actual geometry, and will
+devote no space to the one-dimensional, except incidentally as existing
+within the two-dimensional. The analytical method will now be explained
+for the cases of two and three dimensions in succession. The form of it
+originated by Descartes, and thence known as Cartesian, will alone be
+considered in much detail.
+
+
+  I. _Plane Analytical Geometry._
+
+  [Illustration: FIG. 48.]
+
+  [Illustration: FIG. 49.]
+
+  6. _Coordinates._--It is assumed that the points, lines and figures
+  considered lie in one and the same plane, which plane therefore need
+  not be in any way referred to. In the plane a point O, and two lines
+  x'Ox, y'Oy, intersecting in O, are taken once for all, and regarded as
+  fixed. O is called the origin, and x'Ox, y'Oy the axes of x and y
+  respectively. Other positions in the plane are specified in relation
+  to this fixed origin and these fixed axes. From any point P we suppose
+  PM drawn parallel to the axis of y to meet the axis of x in M, and may
+  also suppose PN drawn parallel to the axis of x to meet the axis of y
+  in N, so that OMPN is a parallelogram. The position of P is determined
+  when we know OM ( = NP) and MP ( = ON). If OM is x times the unit of a
+  scale of measurement chosen at pleasure, and MP is y times the unit,
+  so that x and y have numerical values, we call x and y the (Cartesian)
+  coordinates of P. To distinguish them we often speak of y as the
+  ordinate, and of x as the abscissa.
+
+  It is necessary to attend to signs; x has one sign or the other
+  according as the point P is on one side or the other of the axis of y,
+  and y one sign or the other according as P is on one side or the other
+  of the axis of x. Using the letters N, E, S, W, as in a map, and
+  considering the plane as divided into four quadrants by the axes, the
+  signs are usually taken to be:
+
+    x   y   For quadrant
+
+    +   +      N  E
+    +   -      S  E
+    -   +      N  W
+    -   -      S  W
+
+  A point is referred to as the point (a, b), when its coordinates are x
+  = a, y = b. A point may be fixed, or it may be variable, i.e. be
+  regarded for the time being as free to move in the plane. The
+  coordinates (x, y) of a variable point are algebraic variables, and
+  are said to be "current coordinates."
+
+  The axes of x and y are usually (as in fig. 48) taken at right angles
+  to one another, and we then speak of them as rectangular axes, and of
+  x and y as "rectangular coordinates" of a point P; OMPN is then a
+  rectangle. Sometimes, however, it is convenient to use axes which are
+  oblique to one another, so that (as in fig. 49) the angle xOy between
+  their positive directions is some known angle [omega] distinct from a
+  right angle, and OMPN is always an oblique parallelogram with given
+  angles; and we then speak of x and y as "oblique coordinates." The
+  coordinates are as a rule taken to be rectangular in what follows.
+
+  7. _Equations and loci._ If (x, y) is the point P, and if we are given
+  that x = 0, we are told that, in fig. 48 or fig. 49, the point M lies
+  at O, whatever value y may have, i.e. we are told the one fact that P
+  lies on the axis of y. Conversely, if P lies anywhere on the axis of
+  y, we have always OM = 0, i.e. x = 0. Thus the equation x = 0 is one
+  satisfied by the coordinates (x, y) of every point in the axis of y,
+  and not by those of any other point. We say that x = 0 is the equation
+  of the axis of y, and that the axis of y is the locus represented by
+  the equation x = 0. Similarly y = 0 is the equation of the axis of x.
+  An equation x = a, where a is a constant, expresses that P lies on a
+  parallel to the axis of y through a point M on the axis of x such that
+  OM = a. Every line parallel to the axis of y has an equation of this
+  form. Similarly, every line parallel to the axis of x has an equation
+  of the form y = b, where b is some definite constant.
+
+  These are simple cases of the fact that a single equation in the
+  current coordinates of a variable point (x, y) imposes one limitation
+  on the freedom of that point to vary. The coordinates of a point taken
+  at random in the plane will, as a rule, not satisfy the equation, but
+  infinitely many points, and in most cases infinitely many real ones,
+  have coordinates which do satisfy it, and these points are exactly
+  those which lie upon some locus of one dimension, a straight line or
+  more frequently a curve, which is said to be represented by the
+  equation. Take, for instance, the equation y = mx, where m is a given
+  constant. It is satisfied by the coordinates of every point P, which
+  is such that, in fig. 48, the distance MP, with its proper sign, is m
+  times the distance OM, with its proper sign, i.e. by the coordinates
+  of every point in the straight line through O which we arrive at by
+  making a line, originally coincident with x'Ox, revolve about O in the
+  direction opposite to that of the hands of a watch through an angle of
+  which m is the tangent, and by those of no other points. That line is
+  the locus which it represents. Take, more generally, the equation y =
+  [phi](x), where [phi](x) is any given non-ambiguous function of x.
+  Choosing any point M on x'Ox in fig. 1, and giving to x the value of
+  the numerical measure of OM, the equation determines a single
+  corresponding y, and so determines a single point P on the line
+  through M parallel to y'Oy. This is one point whose coordinates
+  satisfy the equation. Now let M move from the extreme left to the
+  extreme right of the line x'Ox, regarded as extended both ways as far
+  as we like, i.e. let x take all real values from -[oo] to [oo]. With
+  every value goes a point P, as above, on the parallel to y'Oy through
+  the corresponding M; and we thus find that there is a path from the
+  extreme left to the extreme right of the figure, all points P along
+  which are distinguished from other points by the exceptional property
+  of satisfying the equation by their coordinates. This path is a locus;
+  and the equation y = [phi](x) represents it. More generally still,
+  take an equation f(x, y) = 0 which involves both x and y under a
+  functional form. Any particular value given to x in it produces from
+  it an equation for the determination of a value or values of y, which
+  go with that value of x in specifying a point or points (x, y), of
+  which the coordinates satisfy the equation f(x, y) = 0. Here again, as
+  x takes all values, the point or points describe a path or paths,
+  which constitute a locus represented by the equation. Except when y
+  enters to the first degree only in f(x, y), it is not to be expected
+  that all the values of y, determined as going with a chosen value of
+  x, will be necessarily real; indeed it is not uncommon for all to be
+  imaginary for some ranges of values of x. The locus may largely
+  consist of continua of imaginary points; but the real parts of it
+  constitute a real curve or real curves. Note that we have to allow x
+  to admit of all imaginary, as well as of all real, values, in order to
+  obtain all imaginary parts of the locus.
+
+  A locus or curve may be algebraically specified in another way; viz.
+  we may be given two equations x = f([theta]), y = F([theta]), which
+  express the coordinates of any point of it as two functions of the
+  same variable parameter [theta] to which all values are open. As
+  [theta] takes all values in turn, the point (x, y) traverses the
+  curve.
+
+  It is a good exercise to trace a number of curves, taken as defined by
+  the equations which represent them. This, in simple cases, can be done
+  approximately by plotting the values of y given by the equation of a
+  curve as going with a considerable number of values of x, and
+  connecting the various points (x, y) thus obtained. But methods exist
+  for diminishing the labour of this tentative process.
+
+  Another problem, which will be more attended to here, is that of
+  determining the equations of curves of known interest, taken as
+  defined by geometrical properties. It is not a matter for surprise
+  that the curves which have been most and longest studied geometrically
+  are among those represented by equations of the simplest character.
+
+  8. _The Straight Line._--This is the simplest type of locus. Also the
+  simplest type of equation in x and y is Ax + By + C = 0, one of the
+  first degree. Here the coefficients A, B, C are constants. They are,
+  like the current coordinates, x, y, numerical. But, in giving
+  interpretation to such an equation, we must of course refer to numbers
+  Ax, By, C of unit magnitudes of the same kind, of units of counting
+  for instance, or unit lengths or unit squares. It will now be seen
+  that every straight line has an equation of the first degree, and that
+  every equation of the first degree represents a straight line.
+
+  [Illustration: FIG. 50.]
+
+  It has been seen (S 7) that lines parallel to the axes have equations
+  of the first degree, free from one of the variables. Take now a
+  straight line ABC inclined to both axes. Let it make a given angle
+  [alpha] with the positive direction of the axis of x, i.e. in fig. 50
+  let this be the angle through which Ax must be revolved
+  counter-clockwise about A in order to be made coincident with the
+  line. Let C, of coordinates (h, k), be a fixed point on the line, and
+  P(x, y) any other point upon it. Draw the ordinates CD, PM of C and P,
+  and let the parallel to the axis of x through C meet PM, produced if
+  necessary, in R. The right-angled triangle CRP tells us that, with the
+  signs appropriate to their directions attached to CR and RP,
+
+    RP = CR tan [alpha], i.e. MP - DC = (OM - OD) tan [alpha],
+
+  and this gives that
+
+    y - k = tan [alpha] (x - h),
+
+  an equation of the first degree satisfied by x and y. No point not on
+  the line satisfies the same equation; for the line from C to any point
+  off the line would make with CR some angle [beta] different from
+  [alpha], and the point in question would satisfy an equation y - k =
+  tan [beta](x - h), which is inconsistent with the above equation.
+
+  The equation of the line may also be written y = mx + b, where m = tan
+  [alpha], and b = k - h tan [alpha]. Here b is the value obtained for y
+  from the equation when 0 is put for x, i.e. it is the numerical
+  measure, with proper sign, of OB, the intercept made by the line on
+  the axis of y, measured from the origin. For different straight lines,
+  m and b may have any constant values we like.
+
+  Now the general equation of the first degree Ax + By + C = 0 may be
+  written y = -(A/B)x - C/B, unless B = 0, in which case it represents a
+  line parallel to the axis of y; and -A/B, -C/B are values which can be
+  given to m and b, so that every equation of the first degree
+  represents a straight line. It is important to notice that the general
+  equation, which in appearance contains three constants A, B, C, in
+  effect depends on two only, the ratios of two of them to the third. In
+  virtue of this last remark, we see that two distinct conditions
+  suffice to determine a straight line. For instance, it is easy from
+  the above to see that
+
+    x    y
+    -- + -- = 1
+    a    b
+
+  is the equation of a straight line determined by the two conditions
+  that it makes intercepts OA, OB on the two axes, of which a and b are
+  the numerical measures with proper signs: note that in fig. 50 a is
+  negative. Again,
+
+             y2 - y1
+    y - y1 = ------- (x - x1),
+             x2 - x1
+
+  i.e.
+
+    (y1 - y2)x - (x1 - x2)y + x1y2 - x2y1 = 0,
+
+  represents the line determined by the data that it passes through two
+  given points (x1, y1) and (x2, y2). To prove this find m in the
+  equation y - y1 = m(x - x1) of a line through (x1, y1), from the
+  condition that (x2, y2) lies on the line.
+
+  In this paragraph the coordinates have been assumed rectangular. Had
+  they been oblique, the doctrine of similar triangles would have given
+  the same results, except that in the forms of equation y - k = m(x -
+  h), y = mx + b, we should not have had m = tan [alpha].
+
+  9. _The Circle._--It is easy to write down the equation of a given
+  circle. Let (h, k) be its given centre C, and [rho] the numerical
+  measure of its given radius. Take P (x, y) any point on its
+  circumference, and construct the triangle CRP, in fig. 50 as above.
+  The fact that this is right-angled tells us that
+
+    CR^2 + RP^2 = CP^2,
+
+  and this at once gives the equation
+
+    (x - h)^2 + (y - k)^2 = [rho]^2.
+
+  A point not upon the circumference of the particular circle is at some
+  distance from (h, k) different from [rho], and satisfies an equation
+  inconsistent with this one; which accordingly represents the
+  circumference, or, as we say, the circle.
+
+  The equation is of the form
+
+    x^2 + y^2 + 2Ax + 2By + C = 0.
+
+  Conversely every equation of this form represents a circle: we have
+  only to take -A, -B, A^2 + B^2 - C for h, k, [rho]^2 respectively, to
+  obtain its centre and radius. But this statement must appear too
+  unrestricted. Ought we not to require A^2 + B^2 - C to be positive?
+  Certainly, if by circle we are only to mean the visible round
+  circumference of the geometrical definition. Yet, analytically, we
+  contemplate altogether imaginary circles, for which [rho]^2 is
+  negative, and circles, for which [rho] = 0, with all their reality
+  condensed into their centres. Even when [rho]^2 is positive, so that a
+  visible round circumference exists, we do not regard this as
+  constituting the whole of the circle. Giving to x any value whatever
+  in (x - h)^2 + (y - k)^2 = [rho]^2, we obtain two values of y, real,
+  coincident or imaginary, each of which goes with the abscissa x as the
+  ordinate of a point, real or imaginary, on what is represented by the
+  equation of the circle.
+
+  The doctrine of the imaginary on a circle, and in geometry generally,
+  is of purely algebraical inception; but it has been in its entirety
+  accepted by modern pure geometers, and signal success has attended the
+  efforts of those who, like K.G.C. von Staudt, have striven to base its
+  conclusions on principles not at all algebraical in form, though of
+  course cognate to those adopted in introducing the imaginary into
+  algebra.
+
+  A circle with its centre at the origin has an equation x^2 + y^2 =
+  [rho]^2.
+
+  In oblique coordinates the general equation of a circle is x^2 + 2xy
+  cos [omega] + y^2 + 2Ax + 2By + C = 0.
+
+  10. The conic sections are the next simplest loci; and it will be seen
+  later that they are the loci represented by equations of the second
+  degree. Circles are particular cases of conic sections; and they have
+  just been seen to have for their equations a particular class of
+  equations of the second degree. Another particular class of such
+  equations is that included in the form (Ax + By + C)(A'x + B'y + C') =
+  0, which represents two straight lines, because the product on the
+  left vanishes if, and only if, one of the two factors does, i.e. if,
+  and only if, (x, y) lies on one or other of two straight lines. The
+  condition that ax^2 + 2hxy + by^2 + 2gx + 2fy + c = 0, which is often
+  written (a, b, c, f, g, h)(x, y, I)^2 = 0, takes this form is abc +
+  2fgh-af^2-bg^2 - ch^2 = 0. Note that the two lines may, in particular
+  cases, be parallel or coincident.
+
+  Any equation like F1(x, y) F2(x, y) ... F_n(x, y) = 0, of which the
+  left-hand side breaks up into factors, represents all the loci
+  separately represented by F1(x, y) = 0, F2(x, y) = 0, ... F_n(x, y) =
+  0. In particular an equation of degree n which is free from x
+  represents n straight lines parallel to the axis of x, and one of
+  degree n which is homogeneous in x and y, i.e. one which upon division
+  by x^n, becomes an equation in the ratio y/x, represents n straight
+  lines through the origin.
+
+  Curves represented by equations of the third degree are called cubic
+  curves. The general equation of this degree will be written (*)(x, y,
+  I)^3 = 0.
+
+  11. _Descriptive Geometry._--A geometrical proposition is either
+  descriptive or metrical: in the former case the statement of it is
+  independent of the idea of magnitude (length, inclination, &c.), and
+  in the latter it has reference to this idea. The method of coordinates
+  seems to be by its inception essentially metrical. Yet in dealing by
+  this method with descriptive propositions we are eminently free from
+  metrical considerations, because of our power to use general
+  equations, and to avoid all assumption that measurements implied are
+  any particular measurements.
+
+  [Illustration: FIG. 51.]
+
+  12. It is worth while to illustrate this by the instance of the
+  well-known theorem of the radical centre of three circles. The theorem
+  is that, given any three circles A, B, C (fig. 51), the common chords
+  [alpha][alpha]', [beta][beta]', [gamma][gamma]' of the three pairs of
+  circles meet in a point.
+
+  The geometrical proof is metrical throughout:--
+
+  Take O the point of intersection of [alpha][alpha]', [beta][beta]',
+  and joining this with [gamma]', suppose that [gamma]'O does not pass
+  through [gamma], but that it meets the circles A, B in two distinct
+  points [gamma]2, [gamma]1 respectively. We have then the known
+  metrical property of intersecting chords of a circle; viz. in circle
+  C, where [alpha][alpha]', [beta][beta]', are chords meeting at a point
+  O,
+
+    O[alpha].O[alpha]' = O[beta].O[beta]',
+
+  where, as well as in what immediately follows, O[alpha], &c. denote,
+  of course, _lengths_ or _distances_.
+
+  Similarly in circle A,
+
+    O[beta].O[beta]' = O[gamma]2.O[gamma]',
+
+  and in circle B,
+
+    O[alpha].O[alpha]' = O[gamma]1.O[gamma]'.
+
+  Consequently O[gamma]1.O[gamma]' = O[gamma]2.O[gamma]', that is,
+  O[gamma]1 = O[gamma]2, or the points [gamma]1 and [gamma]2 coincide;
+  that is, they each coincide with [gamma].
+
+  We contrast this with the analytical method:--
+
+  Here it only requires to be known that an equation Ax + By + C = 0
+  represents a line, and an equation x^2 + y^2 + Ax + By + C = 0
+  represents a circle. A, B, C have, in the two cases respectively,
+  metrical significations; but these we are not concerned with. Using S
+  to denote the function x^2 + y^2 + Ax + By + C, the equation of a
+  circle is S = o. Let the equation of any other circle be S', = x^2 +
+  y^2 + A'x + B'y + C' = 0; the equation S - S' = 0 is a linear equation
+  (S - S' is in fact = (A - A')x + (B - B')y + C - C), and it thus
+  represents a line; this equation is satisfied by the coordinates of
+  each of the points of intersection of the two circles (for at each of
+  these points S = 0 and S' = 0, therefore also S - S' = 0); hence the
+  equation S - S' = 0 is that of the line joining the two points of
+  intersection of the two circles, or say it is the equation of the
+  common chord of the two circles. Considering then a third circle S", =
+  x^2 + y^2 + A"x + B"y + C" = 0, the equations of the common chords are
+  S-S' = 0, S - S" = 0, S' - S" = 0 (each of these a linear equation);
+  at the intersection of the first and second of these lines S = S' and
+  S = S", therefore also S' = S", or the equation of the third line is
+  satisfied by the coordinates of the point in question; that is, the
+  three chords intersect in a point O, the coordinates of which are
+  determined by the equations S = S' = S".
+
+  It further appears that if the two circles S = 0, S' = 0 do not
+  intersect in any real points, they must be regarded as intersecting in
+  two imaginary points, such that the line joining them is the real line
+  represented by the equation S - S' = 0; or that two circles, whether
+  their intersections be real or imaginary, have always a real common
+  chord (or radical axis), and that for _any_ three circles the common
+  chords intersect in a point (of course real) which is the radical
+  centre. And by this very theorem, given two circles with imaginary
+  intersections, we can, by drawing circles which meet each of them in
+  real points, construct the radical axis of the first-mentioned two
+  circles.
+
+  13. The principle employed in showing that the equation of the common
+  chord of two circles is S - S' = 0 is one of very extensive
+  application, and some more illustrations of it may be given.
+
+  Suppose S = 0, S' = 0 are lines (that is, let S, S' now denote linear
+  functions Ax + By + C, A'x + B'y + C'), then S - kS' = 0 (k an
+  arbitrary constant) is the equation of any line passing through the
+  point of intersection of the two given lines. Such a line may be made
+  to pass through any given point, say the point (x0, y0); if S0, S'0
+  are what S, S' respectively become on writing for (x, y) the values
+  (x0, y0), then the value of k is k = S0 : S'0. The equation in fact is
+  SS'0 - S0S' = 0; and starting from this equation we at once verify it
+  _a posteriori_; the equation is a linear equation satisfied by the
+  values of (x, y) which make S = 0, S' = 0; and satisfied also by the
+  values (x0, y0); and it is thus the equation of the line in question.
+
+  If, as before, S = 0, S' = 0 represent circles, then (k being
+  arbitrary) S - kS' = 0 is the equation of any circle passing through
+  the two points of intersection of the two circles; and to make this
+  pass through a given point (x0, y0) we have again k = S0 : S'0. In the
+  particular case k = 1, the circle becomes the common chord (more
+  accurately it becomes the common chord together with the line
+  infinity; see S 23 below).
+
+  If S denote the general quadric function,
+
+    S = ax^2 +2hxy + by^2 + 2fy + 2gx + c,
+
+  then the equation S = 0 represents a conic; assuming this, then, if S'
+  = 0 represents another conic, the equation S - kS' = 0 represents
+  _any_ conic through the four points of intersection of the two conics.
+
+  [Illustration: FIG. 52.]
+
+  14. The object still being to illustrate the mode of working with
+  coordinates for descriptive purposes, we consider the theorem of the
+  polar of a point in regard to a circle. Given a circle and a point O
+  (fig. 52), we draw through O any two lines meeting the circle in the
+  points A, A' and B, B' respectively, and then taking Q as the
+  intersection of the lines AB' and A'B, the theorem is that the locus
+  of the point Q is a right line depending only upon O and the circle,
+  but independent of the particular lines OAA' and OBB'.
+
+  Taking O as the origin, and for the axes any two lines through O at
+  right angles to each other, the equation of the circle will be
+
+    x^2 + y^2 + 2Ax + 2By + C = 0;
+
+  and if the equation of the line OAA' is taken to be y = mx, then the
+  points A, A' are found as the intersections of the straight line with
+  the circle; or to determine x we have
+
+    x^2(1 + m^2) + 2x(A + Bm) + C = 0.
+
+  If(x1, y1) are the coordinates of A, and (x2, y2) of A', then the
+  roots of this equation are x1, x2, whence easily
+
+    1    1        A + Bm
+    -- + --  = -2 ------.
+    x1   x2         C
+
+  And similarly, if the equation of the line OBB' is taken to be y =
+  m'x1 and the coordinates of B, B' to be (x3, y3) and (x4, y4)
+  respectively, then
+
+    1    1         A + Bm'
+    -- + --  =  -2 -------.
+    x3   x4           C'
+
+  We have then by S 8
+
+    x(y1 - y4) - y(x1 - x4) + x1y4 - x4y1 = 0,
+
+    x(y2 - y3) - y(x2 - x3) + x2y3 - x3y2 = 0,
+
+  as the equations of the lines AB' and A'B respectively. Reducing by
+  means of the relations y1 - mx1 = 0, y2 - mx2 = 0, y3 - m'x3 = 0, y4 -
+  m'x4 = 0, the two equations become
+
+    x(mx1 - m'x4) - y(x1 - x4) + (m'- m)x1x4 = 0,
+
+    x(mx2 - m'x3) - y(x2 - x3) + (m'- m)x2x3 = 0,
+
+  and if we divide the first of these equations by x1x4, and the second
+  by x2x3 and then add, we obtain
+      _                               _      _                       _
+     |   / 1    1  \       / 1    1 \  |    |  1    1     / 1    1 \  |
+    x| m(  -- + --  ) - m'(  -- + -- ) | - y|  -- + -- - (  -- + -- ) |
+     |_  \ x3   x4 /       \ x1   x2/ _|    |_ x3   x4    \ x1   x2/ _|
+
+      + 2m' - 2m = 0,
+
+  or, what is the same thing,
+
+     / 1    1  \              / 1    1  \
+    (  -- + --  )(y - m'x) - (  -- + --  )(y - mx) + 2m' - 2m = 0,
+     \ x1   x2 /              \ x3   x4 /
+
+  which by what precedes is the equation of a line through the point Q.
+  Substituting herein for 1/x1 + 1/x2, 1/x3 + 1/x4 their foregoing
+  values, the equation becomes
+
+    -(A + Bm)(y - m'x) + (A + Bm')(y - mx) + C(m' - m) = 0;
+
+  that is,
+
+    (m - m')(Ax + By + C) = 0;
+
+  or finally it is Ax + By + C = 0, showing that the point Q lies in a
+  line the position of which is independent of the particular lines
+  OAA', OBB' used in the construction. It is proper to notice that there
+  is no correspondence to each other of the points A, A' and B, B'; the
+  grouping might as well have been A, A' and B', B; and it thence
+  appears that the line Ax + By + C = 0 just obtained is in fact the
+  line joining the point Q with the point R which is the intersection of
+  AB and A'B'.
+
+  15. In S 8 it has been seen that two conditions determine the equation
+  of a straight line, because in Ax + By + C = 0 one of the coefficients
+  may be divided out, leaving only two parameters to be determined.
+  Similarly five conditions instead of six determine an equation of the
+  second degree (a, b, c, f, g, h)(x, y, 1)^2 = 0, and nine instead of
+  ten determine a cubic (*)(x, y, 1)^3 = 0. It thus appears that a cubic
+  can be made to pass through 9 given points, and that the cubic so
+  passing through 9 given points is completely determined. There is,
+  however, a remarkable exception. Considering two given cubic curves S
+  = 0, S' = 0, these intersect in 9 points, and through these 9 points
+  we have the whole series of cubics S - kS' = 0, where k is an
+  arbitrary constant: k may be determined so that the cubic shall pass
+  through a given tenth point (k = S0 : S'0, if the coordinates are (x0,
+  y0), and S0, S'0 denote the corresponding values of S, S'). The
+  resulting curve SS'0 - S'S0 = 0 may be regarded as the cubic
+  determined by the conditions of passing through 8 of the 9 points and
+  through the given point (x0, y0); and from the equation it thence
+  appears that the curve passes through the remaining one of the 9
+  points. In other words, we thus have the theorem, any cubic curve
+  which passes through 8 of the 9 intersections of two given cubic
+  curves passes through the 9th intersection.
+
+  The applications of this theorem are very numerous; for instance, we
+  derive from it Pascal's theorem of the inscribed hexagon. Consider a
+  hexagon inscribed in a conic. The three alternate sides constitute a
+  cubic, and the other three alternate sides another cubic. The cubics
+  intersect in 9 points, being the 6 vertices of the hexagon, and the 3
+  Pascalian points, or intersections of the pairs of opposite sides of
+  the hexagon. Drawing a line through two of the Pascalian points, the
+  conic and this line constitute a cubic passing through 8 of the 9
+  points of intersection, and it therefore passes through the remaining
+  point of intersection--that is, the third Pascalian point; and since
+  obviously this does not lie on the conic, it must lie on the
+  line--that is, we have the theorem that the three Pascalian points (or
+  points of intersection of the pairs of opposite sides) lie on a line.
+
+  16. _Metrical Theory resumed. Projections and Perpendiculars._--It
+  is a metrical fact of fundamental importance, already used in S 8,
+  that, if a finite line PQ be projected on any other line OO' by
+  perpendiculars PP', QQ' to OO', the length of the projection P'Q' is
+  equal to that of PQ multiplied by the cosine of the acute angle
+  between the two lines. Also the algebraical sum of the projections of
+  the sides of any closed polygon upon any line is zero, because as a
+  point goes round the polygon, from any vertex A to A again, the point
+  which is its projection on the line passes from A' the projection of A
+  to A' again, i.e. traverses equal distances along the line in positive
+  and negative senses. If we consider the polygon as consisting of two
+  broken lines, each extending from the same initial to the same
+  terminal point, the sum of the projections of the lines which compose
+  the one is equal, in sign and magnitude, to the sum of the projections
+  of the lines composing the other. Observe that the projection on a
+  line of a length perpendicular to the line is zero.
+
+  Let us hence find the equation of a straight line such that the
+  perpendicular OD on it from the origin is of length [rho] taken as
+  positive, and is inclined to the axis of x at an angle xOD = [alpha],
+  measured counter-clockwise from Ox. Take any point P (x, y) on the
+  line, and construct OM and MP as in fig. 48. The sum of the
+  projections of OM and MP on OD is OD itself; and this gives the
+  equation of the line
+
+    x cos [alpha] + y sin [alpha] = [rho].
+
+  Observe that cos [alpha] and sin [alpha] here are the sin [alpha] and
+  -cos [alpha], or the -sin [alpha] and cos [alpha] of S 8 according to
+  circumstances.
+
+  We can write down an expression for the perpendicular distance from
+  this line of any point (x', y') which does not lie upon it. If the
+  parallel through (x', y') to the line meet OD in E, we have x' cos
+  [alpha] + y' sin [alpha] = OE, and the perpendicular distance required
+  is OD - OE, i.e. [rho] - x' cos [alpha] - y' sin [alpha]; it is the
+  perpendicular distance taken positively or negatively according as
+  (x', y') lies on the same side of the line as the origin or not.
+
+  The general equation Ax + By + C = 0 may be given the form x cos
+  [alpha] + y sin [alpha] - [rho] = 0 by dividing it by [root](A^2 +
+  B^3). Thus (Ax' + By' + C) / [root](A^2 + B^2) is in absolute value
+  the perpendicular distance of (x', y') from the line Ax + By + C = 0.
+  Remember, however, that there is an essential ambiguity of sign
+  attached to a square root. The expression found gives the distance
+  taken positively when (x', y') is on the origin side of the line, if
+  the sign of C is given to [root](A^2 + B^2).
+
+  17. _Transformation of Coordinates._--We often need to adopt new axes
+  of reference in place of old ones; and the above principle of
+  projections readily expresses the old coordinates of any point in
+  terms of the new.
+
+  [Illustration: FIG. 53.]
+
+  Suppose, for instance, that we want to take for new origin the point
+  O' of old coordinates OA = h, AO' = k, and for new axes of X and Y
+  lines through O' obtained by rotating parallels to the old axes of x
+  and y through an angle [theta] counter-clockwise. Construct (fig. 53)
+  the old and new coordinates of any point P. Expressing that the
+  projections, first on the old axis of x and secondly on the old axis
+  of y, of OP are equal to the sums of the projections, on those axes
+  respectively, of the parts of the broken line OO'M'P, we obtain:
+
+    x = h + X cos [theta] + Y cos ([theta] + 1/2[pi]) = h + X cos [theta] -
+      Y sin [theta],
+
+  and
+
+    y = k + X cos (1/2[pi] - [theta]) + Y cos [theta] = k + X sin [theta] +
+      Y cos [theta].
+
+  Be careful to observe that these formulae do not apply to every
+  conceivable change of reference from one set of rectangular axes to
+  another. It might have been required to take O'X, O'Y' for the
+  positive directions of the new axes, so that the change of directions
+  of the axes could not be effected by rotation. We must then write -Y
+  for Y in the above.
+
+  Were the new axes oblique, making angles [alpha], [beta] respectively
+  with the old axis of x, and so inclined at the angle [beta] - [alpha],
+  the same method would give the formulae
+
+    x = h + X cos [alpha] + Y cos [beta], y = k + X sin [alpha] + Y sin [beta].
+
+  18. _The Conic Sections._--The conics, as they are now called, were at
+  first defined as curves of intersection of planes and a cone; but
+  Apollonius substituted a definition free from reference to space of
+  three dimensions. This, in effect, is that a conic is the locus of a
+  point the distance of which from a given point, called the focus, has
+  a given ratio to its distance from a given line, called the directrix
+  (see CONIC SECTION). If e : 1 is the ratio, e is called the
+  eccentricity. The distances are considered signless.
+
+  Take (h, k) for the focus, and x cos [alpha] + y sin [alpha] - p = 0
+  for the directrix. The absolute values of [root] {(x - h)^2 + (y -
+  k)^2} and p - x cos [alpha] -y sin [alpha] are to have the ratio e :
+  1; and this gives
+
+    (x - h)^2 + (y - k)^2 = e^2(p - x cos [alpha] - y sin [alpha])^2
+
+  as the general equation, in rectangular coordinates, of a conic.
+
+  It is of the second degree, and is the general equation of that
+  degree. If, in fact, we multiply it by an unknown [lambda], we can, by
+  solving six simultaneous equations in the six unknowns [lambda], h, k,
+  e, p, [alpha], so choose values for these as to make the coefficients
+  in the equation equal to those in any equation of the second degree
+  which may be given. There is no failure of this statement in the
+  special case when the given equation represents two straight lines, as
+  in S 10, but there is speciality: if the two lines intersect, the
+  intersection and either bisector of the angle between them are a focus
+  and directrix; if they are united in one line, any point on the line
+  and a perpendicular to it through the point are: if they are parallel,
+  the case is a limiting one in which e and h^2 + k^2 have become
+  infinite while e^(-2)(h^2 + k^2) remains finite. In the case (S 9) of
+  an equation such as represents a circle there is another instance of
+  proceeding to a limit: e has to become 0, while ep remains finite:
+  moreover [alpha] is indeterminate. The centre of a circle is its
+  focus, and its directrix has gone to infinity, having no special
+  direction. This last fact illustrates the necessity, which is also
+  forced on plane geometry by three-dimensional considerations, of
+  treating all points at infinity in a plane as lying on a single
+  straight line.
+
+  Sometimes, in reducing an equation to the above focus and directrix
+  form, we find for h, k, e, p, tan [alpha], or some of them, only
+  imaginary values, as quadratic equations have to be solved; and we
+  have in fact to contemplate the existence of entirely imaginary
+  conics. For instance, no real values of x and y satisfy x^2 + 2y^2 + 3
+  = 0. Even when the locus represented is real, we obtain, as a rule,
+  four sets of values of h, k, e, p, of which two sets are imaginary; a
+  real conic has, besides two real foci and corresponding directrices,
+  two others that are imaginary.
+
+  In oblique as well as rectangular coordinates equations of the second
+  degree represent conics.
+
+  19. _The three Species of Conics._--A real conic, which does not
+  degenerate into straight lines, is called an ellipse, parabola or
+  hyperbola according as e <, = , or > 1. To trace the three forms it is best so to
+  choose the axes of reference as to simplify their equations.
+
+  In the case of a parabola, let 2c be the distance between the given
+  focus and directrix, and take axes referred to which these are the
+  point (c, 0) and the line x = - c. The equation becomes (x - c)^2 +
+  y^2 = (x + c)^2, i.e. y^2 = 4cx.
+
+  In the other cases, take a such that a(e ~ e^(-1)) is the distance of
+  focus from directrix, and so choose axes that these are (ae, 0) and x
+  = ae^(-1), thus getting the equation(x - ae)^2 + y^2 = e^2(x -
+  ae^(-1))^2, i.e. (1 - e^2)x^2 + y^2 = a^2(1 - e^2). When e < 1, i.e.
+  in the case of an ellipse, this may be written x^2/a^2 + y^2/b^2 = 1,
+  where b^2 = a^2(1 - e^2); and when e > 1, i.e. in the case of an
+  hyperbola, x^2/a^2 - y^2/b^2 = 1, where b^2 = a^2(e^2 - 1). The axes
+  thus chosen for the ellipse and hyperbola are called the principal
+  axes.
+
+  In figs. 54, 55, 56 in order, conics of the three species, thus
+  referred, are depicted.
+
+  [Illustration: FIG. 54]
+
+  [Illustration: FIG. 55]
+
+  [Illustration: FIG. 56.]
+
+  The oblique straight lines in fig. 56 are the _asymptotes_ x/a =
+  [+-]y/b of the hyperbola, lines to which the curve tends with
+  unlimited closeness as it goes to infinity. The hyperbola would have
+  an equation of the form xy = c if referred to its asymptotes as axes,
+  the coordinates being then oblique, unless a = b, in which case the
+  hyperbola is called rectangular. An ellipse has two imaginary
+  asymptotes. In particular a circle x^2 + y^2 = a^2, a particular
+  ellipse, has for asymptotes the imaginary lines x = [+-]y [root]-1.
+  These run from the centre to the so-called circular points at
+  infinity.
+
+  20. _Tangents and Curvature._--Let (x', y') and (x' + h, y' + k) be
+  two neighbouring points P, P' on a curve. The equation of the line on
+  which both lie is h(y - y') = k(x - x'). Now keep P fixed, and let P'
+  move towards coincidence with it along the curve. The connecting line
+  will tend towards a limiting position, to which it can never attain as
+  long as P and P' are distinct. The line which occupies this limiting
+  position is the tangent at P. Now if we subtract the equation of the
+  curve, with (x', y') for the coordinates in it, from the like equation
+  in (x' + h, y' + k), we obtain a relation in h and k, which will, as a
+  rule, be of the form 0 = Ah + Bk + terms of higher degrees in h and k,
+  where A, B and the other coefficients involve x' and y'. This gives
+  k/h = -A/B + terms which tend to vanish as h and k do, so that -A : B
+  is the limiting value tended to by k : h. Hence the equation of the
+  tangent is B(y - y') + A(x - x') = 0.
+
+  The _normal_ at (x', y') is the line through it at right angles to the
+  tangent, and its equation is A(y - y') - B(x - x') = 0.
+
+  In the case of the conic (a, b, c, f, g, h) (x, y, 1)^2 = 0 we find
+  that A/B = (ax' + hy' + g)/(hx' + by' + f).
+
+  We can obtain the coordinates of Q, the intersection of the normals
+  QP, QP' at (x', y') and (x' + h, y' + k), and then, using the limiting
+  value of k : h, deduce those of its limiting position as P' moves up
+  to P. This is the _centre of curvature_ of the curve at P (x', y'),
+  and is so called because it is the centre of the circle of closest
+  contact with the curve at that point. That it is so follows from the
+  facts that the closest circle is the limit tended to by the circle
+  which touches the curve at P and passes through P', and that the arc
+  from P to P' of this circle lies between the circles of centre Q and
+  radii QP, QP', which circles tend, not to different limits as P' moves
+  up to P, but to one. The distance from P to the centre of curvature is
+  the _radius of curvature_.
+
+  21. _Differential Plane Geometry._--The language and notation of the
+  differential calculus are very useful in the study of tangents and
+  curvature. Denoting by ([xi], [eta]) the current coordinates, we find,
+  as above, that the tangent at a point (x, y) of a curve is [eta] - y =
+  ([xi] - x)dy/dx, where dy/dx is found from the equation of the curve.
+  If this be f(x, y) = 0 the tangent is ([xi] - x) (dPf/dPx) + ([eta] -
+  y) (dPf/dPy) = 0. If [rho] and ([alpha], [beta]) are the radius and
+  centre of curvature at (x, y), we find that q([alpha] - x) = -p(1 +
+  p^2), q([beta] - y) = 1 + p^2, q^2[rho]^2 = (1 + p^2)^3, where p, q
+  denote dy/dx, d^2y/dx^2 respectively. (See INFINITESIMAL CALCULUS.)
+
+  In any given case we can, at all events in theory, eliminate x, y
+  between the above equations for [alpha] - x and [beta] - y, and the
+  equation of the curve. The resulting equation in ([alpha], [beta])
+  represents the locus of the centre of curvature. This is the _evolute_
+  of the curve.
+
+  22. _Polar Coordinates._--In plane geometry the distance of any point
+  P from a fixed origin (or pole) O, and the inclination xOP of OP to a
+  fixed line Ox, determine the point: r, the numerical measure of OP,
+  the _radius vector_, and [theta], the circular measure of xOP, the
+  _inclination_, are called polar coordinates of P. The formulae x = r
+  cos [theta], y = r sin [theta] connect Cartesian and polar
+  coordinates, and make transition from either system to the other easy.
+  In polar coordinates the equations of a circle through O, and of a
+  conic with O as focus, take the simple forms r = 2a cos
+  ([theta]-[alpha]), r {1 - e cos ([theta]-[alpha])} = l. The use of
+  polar coordinates is very convenient in discussing curves which have
+  properties of symmetry akin to that of a regular polygon, such curves
+  for instance as r = a cos m [theta], with m integral, and also the
+  curves called spirals, which have equations giving r as functions of
+  [theta] itself, and not merely of sin [theta] and cos [theta]. In the
+  geometry of motion under central forces the advantage of working with
+  polar coordinates is great.
+
+  23. _Trilinear and Areal Coordinates._--Consider a fixed triangle ABC,
+  and regard its sides as produced without limit. Denote, as in
+  trigonometry, by a, b, c the positive numbers of units of a chosen
+  scale contained in the lengths BC, CA, AB, by A, B, C the angles, and
+  by [Delta] the area, of the triangle. We might, as in S 6, take CA, CB
+  as axes of x and y, inclined at an angle C. Any point P (x, y) in the
+  plane is at perpendicular distances y sin C and x sin C from CA and
+  CB. Call these [beta] and [alpha] respectively. The signs of [beta]
+  and [alpha] are those of y and x, i.e. [beta] is positive or negative
+  according as P lies on the same side of CA as B does or the opposite,
+  and similarly for [alpha]. An equation in (x, y) of any degree may,
+  upon replacing in it x and y by [alpha] cosec C and [beta] cosec C, be
+  written as one of the same degree in ([alpha], [beta]). Now let
+  [gamma] be the perpendicular distance of P from the third side AB,
+  taken as positive or negative as P is on the C side of AB or not. The
+  geometry of the figure tells us that a[alpha] + b[beta] + c[gamma] =
+  2[Delta]. By means of this relation in [alpha], [beta], [gamma] we can
+  give an equation considered countless other forms, involving two or
+  all of [alpha], [beta], [gamma]. In particular we may make it
+  _homogeneous_ in [alpha], [beta], [gamma]: to do this we have only to
+  multiply the terms of every degree less than the highest present in
+  the equation by a power of (a[alpha] + b[beta] + c[gamma])/2[Delta]
+  just sufficient to raise them, in each case, to the highest degree.
+
+  We call ([alpha], [beta], [gamma]) _trilinear coordinates_, and an
+  equation in them the trilinear equation of the locus represented.
+  Trilinear equations are, as a rule, dealt with in their homogeneous
+  forms. An advantage thus gained is that we need not mean by ([alpha],
+  [beta], [gamma]) the actual measures of the perpendicular distances,
+  but any properly signed numbers which have the same ratio two and two
+  as these distances.
+
+  In place of [alpha], [beta], [gamma] it is lawful to use, as
+  coordinates specifying the position of a point in the plane of a
+  triangle of reference ABC, any given multiples of these. For instance,
+  we may use x = a[alpha]/2[Delta], y = b[beta]/2[Delta], z =
+  c[gamma]/2[Delta], the properly signed ratios of the triangular areas
+  PBC, PCA, PAB to the triangular area ABC. These are called the _areal_
+  coordinates of P. In areal coordinates the relation which enables us
+  to make any equation homogeneous takes the simple form x + y + z = 1;
+  and, as before, we need mean by x, y, z, in a homogeneous equation,
+  only signed numbers in the right ratios.
+
+  Straight lines and conics are represented in trilinear and in areal,
+  because in Cartesian, coordinates by equations of the first and second
+  degrees respectively, and these degrees are preserved when the
+  equations are made homogeneous. What must be said about points
+  infinitely far off in order to make universal the statement, to which
+  there is no exception as long as finite distances alone are
+  considered, that _every_ homogeneous equation of the first degree
+  represents a straight line? Let the point of areal coordinates (x',
+  y', z') move infinitely far off, and mean by x, y, z finite quantities
+  in the ratios which x', y', z' tend to assume as they become infinite.
+  The relation x' + y' + z' = 1 gives that the limiting state of things
+  tended to is expressed by x + y + z = 0. This particular equation of
+  the first degree is satisfied by no point at a finite distance; but we
+  see the propriety of saying that it has to be taken as satisfied by
+  all the points conceived of as actually at infinity. Accordingly the
+  special property of these points is expressed by saying that they lie
+  on a special straight line, of which the areal equation is x + y + z =
+  0. In trilinear coordinates this _line at infinity_ has for equation
+  a[alpha] + b[beta] + c[gamma] = 0.
+
+  On the one special line at infinity parallel lines are treated as
+  meeting. There are on it two special (imaginary) points, the circular
+  points at infinity of S 19, through which all circles pass in the same
+  sense. In fact if S = O be one circle, in areal coordinates, S + (x +
+  y + z)(lx + my + nz) = 0 may, by proper choice of l, m, n, be made any
+  other; since the added terms are once lx + my + nz, and have the
+  generality of any expression like a'x + b'y + c' in Cartesian
+  coordinates. Now these two circles intersect in the two points where
+  either meets x + y + z = 0 as well as in two points on the radical
+  axis lx + my + nz = 0.
+
+  24. Let us consider the perpendicular distance of a point ([alpha]',
+  [beta]', [gamma]') from a line l[alpha] + m[beta] + n[gamma]. We can
+  take rectangular axes of Cartesian coordinates (for clearness as to
+  equalities of angle it is best to choose an origin inside ABC), and
+  refer to them, by putting expressions p - x cos[theta] - y sin[theta],
+  &c., for [alpha] &c.; we can then apply S 16 to get the perpendicular
+  distance; and finally revert to the trilinear notation. The result is
+  to find that the required distance is
+
+    (l[alpha]' + m[beta]' + n[gamma]')/{l, m, n},
+
+  where {l, m, n}^2 = l^2 + m^2 + n^2 - 2mn cos A - 2nl cos B - 2lm cos C.
+
+  In areal coordinates the perpendicular distance from (x', y', z') to
+  lx + my + nz = 0 is 2[Delta](lx' + my' + nz')/{al, bm, cn}. In both
+  cases the coordinates are of course actual values.
+
+  Now let [xi], [eta], [zeta] be the perpendiculars on the line from the
+  vertices A, B, C, i.e. the points (1, 0, 0), (0, 1, 0), (0, 0, 1),
+  with signs in accord with a convention that oppositeness of sign
+  implies distinction between one side of the line and the other. Three
+  applications of the result above give
+
+    [xi]/l = 2[Delta]/{al, bm, cn} = [eta]/m = [zeta]/n;
+
+  and we thus have the important fact that [xi]x' + [eta]y' + [zeta]z'
+  is the perpendicular distance between a point of areal coordinates
+  (x'y'z') and a line on which the perpendiculars from A, B, C are [xi],
+  [eta], [zeta] respectively. We have also that [xi]x + [eta]y + [zeta]z
+  = 0 is the areal equation of the line on which the perpendiculars are
+  [xi], [eta], [zeta]; and, by equating the two expressions for the
+  perpendiculars from (x', y', z') on the line, that in all cases
+  {a[xi], b[eta], c[zeta]}^2 = 4[Delta]^2.
+
+  25. _Line-coordinates. Duality._--A quite different order of ideas
+  may be followed in applying analysis to geometry. The notion of a
+  straight line specified may precede that of a point, and points may be
+  dealt with as the intersections of lines. The specification of a line
+  may be by means of coordinates, and that of a point by an equation,
+  satisfied by the coordinates of lines which pass through it. Systems
+  of _line-coordinates_ will here be only briefly considered. Every such
+  system is allied to some system of point-coordinates; and space will
+  be saved by giving prominence to this fact, and not recommencing _ab
+  initio_.
+
+  Suppose that any particular system of point-coordinates, in which lx +
+  my + nz = 0 may represent any straight line, is before us: notice that
+  not only are trilinear and areal coordinates such systems, but
+  Cartesian coordinates also, since we may write x/z, y/z for the
+  Cartesian x, y, and multiply through by z. The line is exactly
+  assigned if l, m, n, or their mutual ratios, are known. Call (l, m, n)
+  the _coordinates_ of the line. Now keep x, y, z constant, and let the
+  coordinates of the line vary, but always so as to satisfy the
+  equation. This equation, which we now write xl + ym + zn = 0, is
+  satisfied by the coordinates of every line through a certain fixed
+  point, and by those of no other line; it is the equation of that point
+  in the line-coordinates l, m, n.
+
+  Line-coordinates are also called _tangential_ coordinates. A curve is
+  the envelope of lines which touch it, as well as the locus of points
+  which lie on it. A homogeneous equation of degree above the first in
+  l, m, n is a relation connecting the coordinates of every line which
+  touches some curve, and represents that curve, regarded as an
+  envelope. For instance, the condition that the line of coordinates (l,
+  m, n), i.e. the line of which the allied point-coordinate equation is
+  lx + my + nz = 0, may touch a conic (a, b, c, f, g, h) (x, y, z)^2 =
+  0, is readily found to be of the form (A, B, C, F, G, H) (l, m, n)^2 =
+  0, i.e. to be of the second degree in the line-coordinates. It is not
+  hard to show that the _general_ equation of the second degree in l, m,
+  n thus represents a conic; but the degenerate conics of
+  line-coordinates are not line-pairs, as in point-coordinates, but
+  point-pairs.
+
+  The degree of the point-coordinate equation of a curve is the _order_
+  of the curve, the number of points in which it cuts a straight line.
+  That of the line-coordinate equation is its _class_, the number of
+  tangents to it from a point. The order and class of a curve are
+  generally different when either exceeds two.
+
+  26. The system of line-coordinates allied to the areal system of
+  point-coordinates has special interest.
+
+  The l, m, n of this system are the perpendiculars [xi], [eta], [zeta]
+  of S 24; and x'[xi] + y'[eta] + z'[zeta] = 0 is the equation of the
+  point of areal coordinates (x', y', z'), i.e. is a relation which the
+  perpendiculars from the vertices of the triangle of reference on every
+  line through the point, but no other line, satisfy. Notice that a
+  non-homogeneous equation of the first degree in [xi], [eta], [zeta]
+  does not, as a homogeneous one does, represent a point, but a circle.
+  In fact x'[xi] + y'[eta] + z'[zeta] = R expresses the constancy of the
+  perpendicular distance of the fixed point x'[xi] + y'[eta] + z'[zeta]
+  = 0 from the variable line ([xi], [eta], [zeta]), i.e. the fact that
+  ([xi], [eta], [zeta]) touches a circle with the fixed point for
+  centre. The relation in any [xi], [eta], [zeta] which enables us to
+  make an equation homogeneous is not linear, as in point-coordinates,
+  but quadratic, viz. it is the relation {a[xi], b[eta], c[zeta]}^2 =
+  4[Delta]^2 of S 24. Accordingly the homogeneous equation of the above
+  circle is
+
+    4[Delta]^2(x'[xi] + y'[eta] + z'[zeta])^2 = R^2{a[xi], b[eta], c[zeta]}^2.
+
+  Every circle has an equation of this form in the present system of
+  line-coordinates. Notice that the equation of any circle is satisfied
+  by those coordinates of lines which satisfy both x'[xi] + y'[eta] +
+  z'[zeta] = 0, the equation of its centre, and {a[xi], b[eta],
+  c[zeta]}^2 = 0. This last equation, of which the left-hand side
+  satisfies the condition for breaking up into two factors, represents
+  the two imaginary circular points at infinity, through which all
+  circles and their asymptotes pass.
+
+  There is strict duality in descriptive geometry between
+  point-line-locus and line-point-envelope theorems. But in metrical
+  geometry duality is encumbered by the fact that there is in a plane
+  one special line only, associated with distance, while of special
+  points, associated with direction, there are two: moreover the line is
+  real, and the points both imaginary.
+
+
+  II. _Solid Analytical Geometry._
+
+  27. Any point in space may be specified by three coordinates. We
+  consider three fixed planes of reference, and generally, as in all
+  that follows, three which are at right angles two and two. They
+  intersect, two and two, in lines x'Ox, y'Oy, z'Oz, called the axes of
+  x, y, z respectively, and divide all space into eight parts called
+  octants. If from any point P in space we draw PN parallel to zOz' to
+  meet the plane xOy in N, and then from N draw NM parallel to yOy' to
+  meet x'Ox in M, the coordinates (x, y, z) of P are the numerical
+  measures of OM, MN, NP; in the case of rectangular coordinates these
+  are the perpendicular distances of P from the three planes of
+  reference. The sign of each coordinate is positive or negative as P
+  lies on one side or the other of the corresponding plane. In the
+  octant delineated the signs are taken all positive.
+
+  [Illustration: FIG. 57.]
+
+  [Illustration: FIG. 58.]
+
+  In fig. 57 the delineation is on a plane of the paper taken parallel
+  to the plane zOx, the points of a solid figure being projected on that
+  plane by parallels to some chosen line through O in the positive
+  octant. Sometimes it is clearer to delineate, as in fig. 58, by
+  projection parallel to that line in the octant which is equally
+  inclined to Ox, Oy, Oz upon a plane of the paper perpendicular to it.
+  It is possible by parallel projection to delineate equal scales along
+  Ox, Oy, Oz by scales having any ratios we like along lines in a plane
+  having any mutual inclinations we like.
+
+  [Illustration: FIG. 59.]
+
+  For the delineation of a surface of simple form it frequently suffices
+  to delineate the sections by the coordinate planes; and, in
+  particular, when the surface has symmetry about each coordinate plane,
+  to delineate the quarter-sections belonging to a single octant. Thus
+  fig. 59 conveniently represents an octant of the wave surface, which
+  cuts each coordinate plane in a circle and an ellipse. Or we may
+  delineate a series of contour lines, i.e. sections by planes parallel
+  to xOy, or some other chosen plane; of course other sections may be
+  indicated too for greater clearness. For the delineation of a curve a
+  good method is to represent, as above, a series of points P thereof,
+  each accompanied by its ordinate PN, which serves to refer it to the
+  plane of xy. The employment of stereographic projection is also
+  interesting.
+
+  28. In plane geometry, reckoning the line as a curve of the first
+  order, we have only the point and the curve. In solid geometry,
+  reckoning a line as a curve of the first order, and the plane as a
+  surface of the first order, we have the point, the curve and the
+  surface; but the increase of complexity is far greater than would
+  hence at first sight appear. In plane geometry a curve is considered
+  in connexion with lines (its tangents); but in solid geometry the
+  curve is considered in connexion with lines and planes (its tangents
+  and osculating planes), and the surface also in connexion with lines
+  and planes (its tangent lines and tangent planes); there are surfaces
+  arising out of the line--cones, skew surfaces, developables, doubly
+  and triply infinite systems of lines, and whole classes of theories
+  which have nothing analogous to them in plane geometry: it is thus a
+  very small part indeed of the subject which can be even referred to in
+  the present article.
+
+  In the case of a surface we have between the coordinates (x, y, z) a
+  single, or say a onefold relation, which can be represented by a
+  single relation [f](x, y, z) = 0; or we may consider the coordinates
+  expressed each of them as a given function of two variable parameters
+  p, q; the form z = [f](x, y) is a particular case of each of these
+  modes of representation; in other words, we have in the first mode
+  [f](x, y, z) = z - [f](x, y), and in the second mode x = p, y = q for
+  the expression of two of the coordinates in terms of the parameters.
+
+  In the case of a curve we have between the coordinates (x, y, z) a
+  twofold relation: two equations [f](x, y, z) = 0, [phi](x, y, z) = 0
+  give such a relation; i.e. the curve is here considered as the
+  intersection of two surfaces (but the curve is not always the complete
+  intersection of two surfaces, and there are hence difficulties); or,
+  again, the coordinates may be given each of them as a function of a
+  single variable parameter. The form y = [phi](x), z = [psi](x), where
+  two of the coordinates are given in terms of the third, is a
+  particular case of each of these modes of representation.
+
+  29. The remarks under plane geometry as to descriptive and metrical
+  propositions, and as to the non-metrical character of the method of
+  coordinates when used for the proof of a descriptive proposition,
+  apply also to solid geometry; and they might be illustrated in like
+  manner by the instance of the theorem of the radical centre of four
+  spheres. The proof is obtained from the consideration that S and S'
+  being each of them a function of the form x^2 + y^2 + z^2 + ax + by +
+  cz + d, the difference S-S' is a mere linear function of the
+  coordinates, and consequently that S-S' = 0 is the equation of the
+  plane containing the circle of intersection of the two spheres S = 0
+  and S' = 0.
+
+  [Illustration: FIG. 60.]
+
+  30. _Metrical Theory._--The foundation in solid geometry of the
+  metrical theory is in fact the before-mentioned theorem that if a
+  finite right line PQ be projected upon any other line OO' by lines
+  perpendicular to OO', then the length of the projection P'Q' is equal
+  to the length of PQ into the cosine of its inclination to P'Q'--or (in
+  the form in which it is now convenient to state the theorem) the
+  perpendicular distance P'Q' of two parallel planes is equal to the
+  inclined distance PQ into the cosine of the inclination. The principle
+  of S 16, that the algebraical sum of the projections of the sides of
+  any closed polygon on any line is zero, or that the two sets of sides
+  of the polygon which connect a vertex A and a vertex B have the same
+  sum of projections on the line, in sign and magnitude, as we pass from
+  A to B, is applicable when the sides do not all lie in one plane.
+
+  31. Consider the skew quadrilateral QMNP, the sides QM, MN, NP being
+  respectively parallel to the three rectangular axes Ox, Oy, Oz; let
+  the lengths of these sides be [xi], [eta], [zeta], and that of the
+  side QP be = [rho]; and let the cosines of the inclinations (or say
+  the cosine-inclinations) of [rho] to the three axes be [alpha],
+  [beta], [gamma]; then projecting successively on the three sides and
+  on QP we have
+
+    [xi], [eta], [zeta] = [rho][alpha], [rho][beta], [rho][gamma],
+
+  and
+
+    [rho] = [alpha][xi] + [beta][eta] + [gamma][zeta],
+
+  whence [rho]^2 = [xi]^2 + [eta]^2 + [zeta]^2, which is the relation
+  between a distance [rho] and its projections [xi], [eta], [zeta] upon
+  three rectangular axes. And from the same equations we obtain
+  [alpha]^2 + [beta]^2 + [gamma]^2 = 1, which is a relation connecting
+  the cosine-inclinations of a line to three rectangular axes.
+
+  Suppose we have through Q any other line QT, and let the
+  cosine-inclinations of this to the axes be [alpha]', [beta]',
+  [gamma]', and [delta] be its cosine-inclination to QP; also let [rho]
+  be the length of the projection of QP upon QT; then projecting on QT
+  we have
+
+    [rho] = [alpha]'[xi] + [beta]'[eta] + [gamma]'[zeta] = [rho][delta].
+
+  And in the last equation substituting for [xi], [eta], [zeta] their
+  values [rho][alpha], [rho][beta], [rho][gamma] we find
+
+    [delta] = [alpha][alpha]' + [beta][beta]' + [gamma][gamma]',
+
+  which is an expression for the mutual cosine-inclination of two lines,
+  the cosine-inclinations of which to the axes are [alpha], [beta],
+  [gamma] and [alpha]', [beta]', [gamma]' respectively. We have of
+  course [alpha]^2 + [beta]^2 + [gamma]^2 = 1 and [alpha]'^2 + [beta]'^2
+  + [gamma]'^2 = 1; and hence also
+
+    1 - [delta]^2 = ([alpha]^2 + [beta]^2 + [gamma]^2)([alpha]'^2 + [beta]'^2 + [gamma]'^2)
+      - ([alpha][alpha]' + [beta][beta]' + [gamma][gamma]')^2,
+
+    = ([beta][gamma]' - [beta]'[gamma])^2 + ([gamma][alpha]' - [gamma]'[alpha])^2 +
+      ([alpha][beta]' - [alpha]'[beta])^2;
+
+  so that the sine of the inclination can only be expressed as a square
+  root. These formulae are the foundation of spherical trigonometry.
+
+  32. _Straight Lines, Planes and Spheres._--The foregoing formulae give
+  at once the equations of these loci.
+
+  For first, taking Q to be a fixed point, coordinates (a, b, c), and
+  the cosine-inclinations ([alpha], [beta], [gamma]) to be constant,
+  then P will be a point in the line through Q in the direction thus
+  determined; or, taking (x, y, z) for its coordinates, these will be
+  the current coordinates of a point in the line. The values of [xi],
+  [eta], [zeta] then are x - a, y - b, z - c, and we thus have
+
+     x - a    y - b    z - c
+    ------- = ----- = ------- (= [rho]),
+    [alpha]  [beta]   [gamma]
+
+  which (omitting the last equation, = [rho]) are the equations of the
+  line through the point (a, b, c), the cosine-inclinations to the axes
+  being [alpha], [beta], [gamma], and these quantities being connected
+  by the relation [alpha]^2 + [beta]^2 + [gamma]^2 = 1. This equation
+  may be omitted, and then [alpha], [beta], [gamma], instead of being
+  equal, will only be proportional, to the cosine-inclinations.
+
+  Using the last equation, and writing
+
+    x, y, z = a + [alpha][rho], b + [beta][rho], c + [gamma][rho],
+
+  these are expressions for the current coordinates in terms of a
+  parameter [rho], which is in fact the distance from the fixed point
+  (a, b, c).
+
+  It is easy to see that, if the coordinates (x, y, z) are connected by
+  any two linear equations, these equations can always be brought into
+  the foregoing form, and hence that the two linear equations represent
+  a line.
+
+  Secondly, taking for greater simplicity the point Q to be coincident
+  with the origin, and [alpha]', [beta]', [gamma]', p to be constant,
+  then p is the perpendicular distance of a plane from the origin, and
+  [alpha]', [beta]', [gamma]' are the cosine-inclinations of this
+  distance to the axes ([alpha]'^2 + [beta]'^2 + [gamma]'^2 = 1). P is
+  any point in this plane, and taking its coordinates to be (x, y, z)
+  then ([xi], [eta], [zeta]) are = (x, y, z), and the foregoing equation
+  p = [alpha]'[xi] + [beta]'[eta] + [gamma]'[zeta] becomes
+
+    [alpha]'x + [beta]'y + [gamma]'z = p,
+
+  which is the equation of the plane in question.
+
+  If, more generally, Q is not coincident with the origin, then, taking
+  its coordinates to be (a, b, c), and writing p1 instead of p, the
+  equation is
+
+    [alpha]'(x - a) + [beta]'(y - b) + [gamma]'(z - c) = p1;
+
+  and we thence have p1 = p - (a[alpha]' + b[beta]' + c[gamma]'), which
+  is an expression for the perpendicular distance of the point (a, b, c)
+  from the plane in question.
+
+  It is obvious that any linear equation Ax + By + Cz + D = O between
+  the coordinates can always be brought into the foregoing form, and
+  hence that such an equation represents a plane.
+
+  Thirdly, supposing Q to be a fixed point, coordinates (a, b, c), and
+  the distance QP = [rho], to be constant, say this is = d, then, as
+  before, the values of [xi], [eta], [zeta] are x - a, y - b, z - c, and
+  the equation [xi]^2 + [eta]^2 + [zeta]^2 = [rho]^2 becomes
+
+    (x - a)^2 + (y - b)^2 + (z - c)^2 = d^2,
+
+  which is the equation of the sphere, coordinates of the centre = (a,
+  b, c), and radius = d.
+
+  A quadric equation wherein the terms of the second order are x^2 + y^2
+  + z^2, viz. an equation
+
+    x^2 + y^2 + z^2 + Ax + By + Cz + D = 0,
+
+  can always, it is clear, be brought into the foregoing form; and it
+  thus appears that this is the equation of a sphere, coordinates of the
+  centre -1/2A, -1/2B, -1/2C, and squared radius = 1/4(A^2 + B^2 + C^2)
+  - D.
+
+  33. _Cylinders, Cones, ruled Surfaces._--If the two equations of a
+  straight line involve a parameter to which any value may be given, we
+  have a singly infinite system of lines. They cover a surface, and the
+  equation of the surface is obtained by eliminating the parameter
+  between the two equations.
+
+  If the lines all pass through a given point, then the surface is a
+  cone; and, in particular, if the lines are all parallel to a given
+  line, then the surface is a cylinder.
+
+  Beginning with this last case, suppose the lines are parallel to the
+  line x = mz, y = nz, the equations of a line of the system are x = mz
+  + a, y = nz + b,--where a, b are supposed to be functions of the
+  variable parameter, or, what is the same thing, there is between them
+  a relation f(a, b) = 0: we have a = x - mz, b = y - nz, and the result
+  of the elimination of the parameter therefore is [f](x - mz, y - nz) =
+  0, which is thus the general equation of the cylinder the generating
+  lines whereof are parallel to the line x = mz, y = nz. The equation of
+  the section by the plane z = 0 is [f](x, y) = 0, and conversely if the
+  cylinder be determined by means of its curve of intersection with the
+  plane z = 0, then, taking the equation of this curve to be f(x, y) =
+  0, the equation of the cylinder is [f](x - mz, y - nz) = 0. Thus, if
+  the curve of intersection be the circle (x - [alpha])^2 + (y -
+  [beta])^2 = [gamma]^2, we have (x - mz - [alpha])^2 + (y - nz -
+  [beta])^2 = [gamma]^2 as the equation of an oblique cylinder on this
+  base, and thus also (x - [alpha])^2 + (y - [beta])^2 = [gamma]^2 as
+  the equation of the right cylinder.
+
+  If the lines all pass through a given point (a, b, c), then the
+  equations of a line are x - a = [alpha](z - c), y - b = [beta](z - c),
+  where [alpha], [beta] are functions of the variable parameter, or,
+  what is the same thing, there exists between them an equation
+  f([alpha], [beta]) = 0; the elimination of the parameter gives,
+  therefore, f[(x - a)/(x - c'), (y - b)/(z - c)] = 0; and this
+  equation, or, what is the same thing, any homogeneous equation f(x -
+  a, y - b, z - c) = 0, or, taking f to be a rational and integral
+  function of the order n, say (*)(x - a, y - b, z - c)^n = 0, is the
+  general equation of the cone having the point (a, b, c) for its
+  vertex. Taking the vertex to be at the origin, the equation is (*)(x,
+  y, z)^n = 0; and, in particular, (*)(x, y, z)^2 = 0 is the equation of
+  a cone of the second order, or quadricone, having the origin for its
+  vertex.
+
+  34. In the general case of a singly infinite system of lines, the
+  locus is a ruled surface (or _regulus_). Now, when a line is changing
+  its position in space, it may be looked upon as in a state of turning
+  about some point in itself, while that point is, as a rule, in a state
+  of moving out of the plane in which the turning takes place. If
+  instantaneously it is only in a state of turning, it is usual, though
+  not strictly accurate, to say that it intersects its consecutive
+  position. A regulus such that consecutive lines on it do not
+  intersect, in this sense, is called a skew surface, or _scroll_; one
+  on which they do is called a developable surface or _torse_.
+
+  Suppose, for instance, that the equations of a line (depending on the
+  variable parameter [theta]) are x/a + y/c = [theta] (1 + y/b), x/a -
+  z/c = 1/[theta] (1 - y/b); then, eliminating [theta] we have x^2/a^2 -
+  z^2/c^2 = 1 - y^2/b^2, or say, x^2/a^2 + z^2/b^2 - z^2/c^2 = 1, the
+  equation of a quadric surface, afterwards called the hyperboloid of
+  one sheet; this surface is consequently a scroll. It is to be remarked
+  that we have upon the surface a second singly infinite series of
+  lines; the equations of a line of this second system (depending on the
+  variable parameter [phi]) are
+
+    x    z          /    y \   x    z      1    /    y \
+    -- + -- = [phi]( 1 - -- ), -- - -- = ----- ( 1 + -- ).
+    a    c          \    b /   a    c    [phi]  \    b /
+
+  It is easily shown that any line of the one system intersects every
+  line of the other system.
+
+  Considering any curve (of double curvature) whatever, the tangent
+  lines of the curve form a singly infinite system of lines, each line
+  intersecting the consecutive line of the system,--that is, they form a
+  developable, or torse; the curve and torse are thus inseparably
+  connected together, forming a single geometrical figure. An osculating
+  plane of the curve (see S 38 below) is a tangent plane of the torse
+  all along a generating line.
+
+  35. _Transformation of Coordinates._--There is no difficulty in
+  changing the origin, and it is for brevity assumed that the origin
+  remains unaltered. We have, then, two sets of rectangular axes, Ox,
+  Oy, Oz, and Ox1, Oy1, Ozx1, the mutual cosine-inclinations being shown
+  by the diagram--
+
+        |    x    |    y   |    z    |
+    ----+---------+--------+---------+
+    x1  | [alpha] | [beta] | [gamma] |
+    ----+---------+--------+---------+
+    y1  | [alpha] | [beta]'| [gamma]'|
+    ----+---------+--------+---------+
+    z1  | [alpha]"| [beta]"| [gamma]"|
+    ----+---------+--------+---------+
+
+  that is, [alpha], [beta], [gamma] are the cosine-inclinations of Ox1
+  to Ox, Oy, Oz; [alpha]', [beta]', [gamma]' those of Oy1, &c.
+
+  And this diagram gives also the linear expressions of the coordinates
+  (x1, y1, z1) or (x, y, z) of either set in terms of those of the other
+  set; we thus have
+
+    x1 = [alpha] x + [beta] y + [gamma] z,
+     x = [alpha]x1 + [alpha]'y1 + [alpha]"z1,
+
+    y1 = [alpha]'x + [beta]'y + [gamma]'z,
+     y = [beta]x1 + [beta]'y1 + [beta]"z1,
+
+    z1 = [alpha]"x + [beta]"y + [gamma]"z,
+     z = [gamma]x1 + [gamma]'y1 + [gamma]"z1,
+
+  which are obtained by projection, as above explained. Each of these
+  equations is, in fact, nothing else than the before-mentioned equation
+  p = [alpha]'[xi] + [beta]'[eta] + [gamma]'[zeta], adapted to the
+  problem in hand.
+
+  But we have to consider the relations between the nine coefficients.
+  By what precedes, or by the consideration that we must have
+  identically x^2 + y^2 + z^2 = x1^2 + y1^2 + z1^2, it appears that
+  these satisfy the relations--
+
+    a^2 + [beta]^2 + [gamma]^2 = 1,
+    [alpha]^2 + [alpha]'^2 + [alpha]"^2 = 1,
+
+    [alpha]'^2 + [beta]'^2 + [gamma]'^2 = 1,
+    [beta]^2 + [beta]'^2 + [beta]"^2 = 1,
+
+    [alpha]"^2 + [beta]"^2 + [gamma]"^2 = 1,
+    [gamma]^2 + [gamma]'^2 + [gamma]"^2 = 1,
+
+    a'a" + [beta]'[beta]" + [gamma]'[gamma]" = 0,
+    [beta][gamma] +[beta]'[gamma]' + [beta]"[gamma]" = 0,
+
+    [alpha]"[alpha] + [beta]"[beta] + [gamma]"[gamma] = 0,
+    [gamma][alpha] + [gamma]'[alpha]' + [gamma]"[alpha]" = 0,
+
+    [alpha][alpha]' + [beta][beta]' + [gamma][gamma]' = 0,
+    [alpha][beta] +[alpha]'[beta]' + [alpha]"[beta]" = 0,
+
+  either set of six equations being implied in the other set.
+
+  It follows that the square of the determinant
+
+    |[alpha],  [beta],  [gamma] |
+    |                           |
+    |[alpha]', [beta]', [gamma]'|
+    |                           |
+    |[alpha]", [beta]", [gamma]"|
+
+  is = 1; and hence that the determinant itself is = [+-] 1. The
+  distinction of the two cases is an important one: if the determinant
+  is = + 1, then the axes Ox1, Oy1, Oz1 are such that they can by a
+  rotation about O be brought to coincide with Ox, Oy, Oz respectively;
+  if it is = -1, then they cannot. But in the latter case, by measuring
+  x1, y1, z1 in the opposite directions we change the signs of all the
+  coefficients and so make the determinant to be = + 1; hence the former
+  case need alone be considered, and it is accordingly assumed that the
+  determinant is = + 1. This being so, it is found that we have the
+  equality [alpha] = [beta]'[gamma]" - [beta]"[gamma]', and eight like
+  ones, obtained from this by cyclical interchanges of the letters
+  [alpha], [beta], [gamma], and of unaccented, singly and doubly
+  accented letters.
+
+  36. The nine cosine-inclinations above are, as has been seen,
+  connected by six equations. It ought then to be possible to express
+  them all in terms of three parameters. An elegant means of doing this
+  has been given by Rodrigues, who has shown that the tabular expression
+  of the formulae of transformation may be written
+
+        |               x                |               y                |               z                |
+    ----+--------------------------------+--------------------------------+--------------------------------+
+    x1  |1 + [lambda]^2 - [mu]^2 - [nu]^2|      2([lambda][mu] - [nu])    |     2([nu][lambda] + [mu])     |
+    ----+--------------------------------+--------------------------+-----+--------------------------------+
+    y1  |     2([lambda][mu] + [nu])     |1 - [lambda]^2 + [mu]^2 - [nu]^2|     2([mu][nu] + [lambda])     |
+    ----+--------------------------------+--------------------------+-----+--------------------------------+
+    z1  |     2([nu][lambda] - [mu])     |      2([mu][nu] + [lambda])    |1 - [lambda]^2 - [mu]^2 + [nu]^2|
+    ----+--------------------------------+--------------------------------+--------------------------------+
+       /(1 + [lambda]^2 + [mu]^2 + [nu]^2),
+
+  the meaning being that the coefficients in the transformation are
+  fractions, with numerators expressed as in the table, and the common
+  denominator.
+
+  37. _The Species of Quadric Surfaces_.--Surfaces represented by
+  equations of the second degree are called _quadric_ surfaces. Quadric
+  surfaces are either _proper_ or _special_. The special ones arise when
+  the coefficients in the general equation are limited to satisfy
+  certain special equations; they comprise (1) plane-pairs, including in
+  particular one plane twice repeated, and (2) cones, including in
+  particular cylinders; there is but one form of cone, but cylinders may
+  be elliptic, parabolic or hyperbolic.
+
+  A discussion of the general equation of the second degree shows that
+  the _proper_ quadric surfaces are of five kinds, represented
+  respectively, when referred to the most convenient axes of reference,
+  by equations of the five types (a and b positive):
+
+             x^2   y^2
+    (1)  z = --- + ---, elliptic paraboloid.
+             2a    2b
+
+             x^2   y^2
+    (2)  z = --- - ---, hyperbolic paraboloid.
+             2a    2b
+
+         x^2   y^2   z^2
+    (3)  --- + --- + --- = 1, ellipsoid.
+         a^2   b^2   c^2
+
+         x^2   y^2   z^2
+    (4)  --- + --- - --- = 1, hyperboloid of one sheet.
+         a^2   b^2   c^2
+
+         x^2   y^2   z^2
+    (5)  --- + --- - --- = -1, hyperboloid of two sheets.
+         a^2   b^2   c^2
+
+  It is at once seen that these are distinct surfaces; and the equations
+  also show very readily the general form and mode of generation of the
+  several surfaces.
+
+  [Illustration: FIG. 61.]
+
+  In the elliptic paraboloid (fig. 61) the sections by the planes of zx
+  and zy are the parabolas
+
+        x^2      y^2
+    z = ---, z = ---
+        2a       2b
+
+  having the common axes Oz; and the section by any plane z = [gamma]
+  parallel to that of xy is the ellipse
+
+              x^2   y^2
+    [gamma] = --- + ---;
+              2a    2b
+
+  so that the surface is generated by a variable ellipse moving parallel
+  to itself along the parabolas as directrices.
+
+  [Illustration: FIG. 62.]
+
+  [Illustration: FIG. 63.]
+
+  In the hyperbolic paraboloid (figs. 62 and 63) the sections by the
+  planes of zx, zy are the parabolas z = x^2/2a, z = - y^2/2b, having
+  the opposite axes Oz, Oz', and the section by a plane z = [gamma]
+  parallel to that of xy is the hyperbola [gamma] = x^2/2a - y^2/2b,
+  which has its transverse axis parallel to Ox or Oy according as
+  [gamma] is positive or negative. The surface is thus generated by a
+  variable hyperbola moving parallel to itself along the parabolas as
+  directrices. The form is best seen from fig. 63, which represents the
+  sections by planes parallel to the plane of xy, or say the contour
+  lines; the continuous lines are the sections above the plane of xy,
+  and the dotted lines the sections below this plane. The form is, in
+  fact, that of a saddle.
+
+  [Illustration: FIG. 64.]
+
+  In the ellipsoid (fig. 64) the sections by the planes of zx, zy, and
+  xy are each of them an ellipse, and the section by any parallel plane
+  is also an ellipse. The surface may be considered as generated by an
+  ellipse moving parallel to itself along two ellipses as directrices.
+
+  In the hyperboloid of one sheet (fig. 65), the sections by the planes
+  of zx, zy are the hyperbolas
+
+    x^2   z^2      y^2   z^2
+    --- - --- = 1, --- - --- = 1,
+    c^2   c^2      b^2   c^2
+
+  having a common conjugate axis zOz'; the section by the plane of x, y,
+  and that by any parallel plane, is an ellipse; and the surface may be
+  considered as generated by a variable ellipse moving parallel to
+  itself along the two hyperbolas as directrices. If we imagine two
+  equal and parallel circular disks, their points connected by strings
+  of equal lengths, so that these are the generators of a right circular
+  cylinder, and if we turn one of the disks about its centre through an
+  angle in its plane, the strings in their new positions will be one
+  system of generators of a hyperboloid of one sheet, for which a = b;
+  and if we turn it through the same angle in the opposite direction, we
+  get in like manner the generators of the other system; there will be
+  the same general configuration when a = | b. The hyperbolic paraboloid
+  is also covered by two systems of rectilinear generators as a method
+  like that used in S 34 establishes without difficulty. The figures
+  should be studied to see how they can lie.
+
+  [Illustration: FIG. 65.]
+
+  [Illustration: FIG. 66.]
+
+  In the hyperboloid of two sheets (fig. 66) the sections by the planes
+  of zx and zy are the hyperbolas
+
+    z^2   x^2      z^2   y^2
+    --- - --- = 1, --- - --- = 1,
+    c^2   a^2      c^2   b^2
+
+  having a common transverse axis along z'Oz; the section by any plane z
+  = [+-][gamma] parallel to that of xy is the ellipse
+
+    x^2   y^2   [gamma]^2
+    --- + --- = --------- - 1,
+    a^2   b^2      c^2
+
+  provided [gamma]^2 > c^2, and the surface, consisting of two distinct
+  portions or sheets, may be considered as generated by a variable
+  ellipse moving parallel to itself along the hyperbolas as directrices.
+
+  38. _Differential Geometry of Curves._--For convenience consider the
+  coordinates (x, y, z) of a point on a curve in space to be given as
+  functions of a variable parameter [theta], which may in particular be
+  one of themselves. Use the notation x', x" for dx/d[theta],
+  d^2x/d[theta]^2, and similarly as to y and z. Only a few formulae will
+  be given. Call the current coordinates ([xi], [eta], [zeta]).
+
+  The _tangent_ at (x, y, z) is the line tended to as a limit by the
+  connector of (x, y, z) and a neighbouring point of the curve when the
+  latter moves up to the former: its equations are
+
+    ([xi] - x)/x' = ([eta] - y)/y' = ([zeta] - z)/z'.
+
+  The _osculating plane_ at (x, y, z) is the plane tended to as a limit
+  by that through (x, y, z) and two neighbouring points of the curve as
+  these, remaining distinct, both move up to (x, y, z): its one equation
+  is
+
+    ([xi] - x)(y'z" - y"z') + ([eta] - y)(z'x" - z"x') + ([zeta] - z)
+      (x'y" - x"y') = 0.
+
+  The _normal plane_ is the plane through (x, y, z) at right angles to
+  the tangent line, i.e. the plane
+
+    x'([xi] - x) + y'([eta] - y) + z'([zeta] - z) = 0.
+
+  It cuts the osculating plane in a line called the _principal normal_.
+  Every line through (x, y, z) in the normal plane is a normal. The
+  normal perpendicular to the osculating plane is called the _binormal_.
+  A tangent, principal normal, and binormal are a convenient set of
+  rectangular axes to use as those of reference, when the nature of a
+  curve near a point on it is to be discussed.
+
+  Through (x, y, z) and three neighbouring points, all on the curve,
+  passes a single sphere; and as the three points all move up to (x, y,
+  z) continuing distinct, the sphere tends to a limiting size and
+  position. The limit tended to is the sphere of closest contact with
+  the curve at (x, y, z); its centre and radius are called the centre
+  and radius of _spherical curvature_. It cuts the osculating plane in a
+  circle, called the _circle of absolute curvature_; and the centre and
+  radius of this circle are the centre and radius of absolute curvature.
+  The centre of absolute curvature is the limiting position of the point
+  where the principal normal at (x, y, z) is cut by the normal plane at
+  a neighbouring point, as that point moves up to (x, y, z).
+
+  39. _Differential Geometry of Surfaces._--Let (x, y, z) be any chosen
+  point on a surface [f](x, y, z) = 0. As a second point of the surface
+  moves up to (x, y, z), its connector with (x, y, z) tends to a
+  limiting position, a tangent line to the surface at (x, y, z). All
+  these tangent lines at (x, y, z), obtained by approaching (x, y, z)
+  from different directions on a surface, lie in one plane
+
+    dP[f]              dP[f]               dP[f]
+    ----- ([xi] - x) + ----- ([eta] - y) + ----- ([zeta] - z) = 0.
+     dPx                dPy                 dPz
+
+  This plane is called the _tangent plane_ at (x, y, z). One line
+  through (x, y, z) is at right angles to the tangent plane. This is the
+  normal
+
+                /dP[f]                /dP[f]                   /dP[f]
+    ([xi] - x) / ----- = ([eta] - y) / ----- = ([zeta] - z) = / -----.
+              /   dPx               /   dPy                  /   dPz
+
+  The tangent plane is cut by the surface in a curve, real or imaginary,
+  with a node or double point at (x, y, z). Two of the tangent lines
+  touch this curve at the node. They are called the "chief tangents"
+  (_Haupt-tangenten_) at (x, y, z); they have closer contact with the
+  surface than any other tangents.
+
+  In the case of a quadric surface the curve of intersection of a
+  tangent and the surface is of the second order and has a node, it must
+  therefore consist of two straight lines. Consequently a quadric
+  surface is covered by two sets of straight lines, a pair through every
+  point on it; these are imaginary for the ellipsoid, hyperboloid of two
+  sheets, and elliptic paraboloid.
+
+  A surface of any order is covered by two singly infinite systems of
+  curves, a pair through every point, the tangents to which are all
+  chief tangents at their respective points of contact. These are called
+  _chief-tangent curves_; on a quadric surface they are the above
+  straight lines.
+
+  40. The tangents at a point of a surface which bisect the angles
+  between the chief tangents are called the _principal tangents_ at the
+  point. They are at right angles, and together with the normal
+  constitute a convenient set of rectangular axes to which to refer the
+  surface when its properties near the point are under discussion. At a
+  special point which is such that the chief tangents there run to the
+  circular points at infinity in the tangent plane, the principal
+  tangents are indeterminate; such a special point is called an umbilic
+  of the surface.
+
+  There are two singly infinite systems of curves on a surface, a pair
+  cutting one another at right angles through every point upon it, all
+  tangents to which are principal tangents of the surface at their
+  respective points of contact. These are called _lines of curvature_,
+  because of a property next to be mentioned.
+
+  As a point Q moves in an arbitrary direction on a surface from
+  coincidence with a chosen point P, the normal at it, as a rule, at
+  once fails to meet the normal at P; but, if it takes the direction of
+  a line of curvature through P, this is instantaneously not the case.
+  We have thus on the normal two centres of curvature, and the distances
+  of these from the point on the surface are the two _principal radii of
+  curvature_ of the surface at that point; these are also the radii of
+  curvature of the sections of the surface by planes through the normal
+  and the two principal tangents respectively; or say they are the radii
+  of curvature of the normal sections through the two principal tangents
+  respectively. Take at the point the axis of z in the direction of the
+  normal, and those of x and y in the directions of the principal
+  tangents respectively, then, if the radii of curvature be a, b (the
+  signs being such that the coordinates of the two centres of curvature
+  are z = a and z = b respectively), the surface has in the
+  neighbourhood of the point the form of the paraboloid
+
+        x^2   y^2
+    z = --- + ---,
+        2a    2b
+
+  and the chief-tangents are determined by the equation 0 = x^2/2a +
+  y^2/2b. The two centres of curvature may be on the same side of the
+  point or on opposite sides; in the former case a and b have the same
+  sign, the paraboloid is elliptic, and the chief-tangents are
+  imaginary; in the latter case a and b have opposite signs, the
+  paraboloid is hyperbolic, and the chief-tangents are real.
+
+  The normal sections of the surface and the paraboloid by the same
+  plane have the same radius of curvature; and it thence readily follows
+  that the radius of curvature of a normal section of the surface by a
+  plane inclined at an angle [theta] to that of zx is given by the
+  equation
+
+      1     cos^2 [theta]   sin^2 [theta]
+    ----- = ------------- + -------------.
+    [rho]        a               b
+
+  The section in question is that by a plane through the normal and a
+  line in the tangent plane inclined at an angle [theta] to the
+  principal tangent along the axis of x. To complete the theory,
+  consider the section by a plane having the same trace upon the tangent
+  plane, but inclined to the normal at an angle [phi]; then it is shown
+  without difficulty (Meunier's theorem) that the radius of curvature of
+  this inclined section of the surface is = [rho] cos [phi].
+
+  AUTHORITIES.--The above article is largely based on that by Arthur
+  Cayley in the 9th edition of this work. Of early and important recent
+  publications on analytical geometry, special mention is to be made of
+  R. Descartes, _Geometrie_ (Leyden, 1637); John Wallis, _Tractatus de
+  sectionibus conicis nova methodo expositis_ (1655, _Opera
+  mathematica_, i., Oxford, 1695); de l'Hospital, _Traite analytique des
+  sections coniques_ (Paris, 1720); Leonhard Euler, _Introductio in
+  analysin infinitorum_, ii. (Lausanne, 1748); Gaspard Monge,
+  "Application d'algebre a la geometrie" (_Journ. Ecole Polytech._,
+  1801); Julius Plucker, _Analytisch-geometrische Entwickelungen_, 3
+  Bde. (Essen, 1828-1831); _System der analytischen Geometrie_ (Berlin,
+  1835); G. Salmon, _A Treatise on Conic Sections_ (Dublin, 1848; 6th
+  ed., London, 1879); Ch. Briot and J. Bouquet, _Lecons de geometrie
+  analytique_ (Paris, 1851; 16th ed., 1897); M. Chasles, _Traite de
+  geometrie superieure_ (Paris, 1852); Wilhelm Fiedler, _Analytische
+  Geometrie der Kegelschnitte_ nach G. Salmon frei bearbeitet (Leipzig,
+  5te Aufl., 1887-1888); N.M. Ferrers, _An Elementary Treatise on
+  Trilinear Coordinates_ (London, 1861); Otto Hesse, _Vorlesungen aus
+  der analytischen Geometrie_ (Leipzig, 1865, 1881); W.A. Whitworth,
+  _Trilinear Coordinates and other Methods of Modern Analytical
+  Geometry_ (Cambridge, 1866); J. Booth, _A Treatise on Some New
+  Geometrical Methods_ (London, i., 1873; ii., 1877); A. Clebsch-F.
+  Lindemann, _Vorlesungen uber Geometrie_, Bd. i. (Leipzig, 1876, 2te
+  Aufl., 1891); R. Baltser, _Analytische Geometrie_ (Leipzig, 1882);
+  Charlotte A. Scott, _Modern Methods of Analytical Geometry_ (London,
+  1894); G. Salmon, _A Treatise on the Analytical Geometry of three
+  Dimensions_ (Dublin, 1862; 4th ed., 1882); Salmon-Fiedler,
+  _Analytische Geometrie des Raumes_ (Leipzig, 1863; 4te Aufl., 1898);
+  P. Frost, _Solid Geometry_ (London, 3rd ed., 1886; 1st ed., Frost and
+  J. Wolstenholme). See also E. Pascal, _Repertorio di matematiche
+  superiori, II. Geometria_ (Milan, 1900), and articles now appearing in
+  the _Encyklopadie der mathematischen Wissenschaften_, Bd. iii. 1, 2.
+       (E. B. El.)
+
+
+V. LINE GEOMETRY
+
+Line geometry is the name applied to those geometrical investigations in
+which the straight line replaces the point as element. Just as ordinary
+geometry deals primarily with points and systems of points, this theory
+deals in the first instance with straight lines and systems of straight
+lines. In two dimensions there is no necessity for a special line
+geometry, inasmuch as the straight line and the point are
+interchangeable by the principle of duality; but in three dimensions the
+straight line is its own reciprocal, and for the better discussion of
+systems of lines we require some new apparatus, e.g., a system of
+coordinates applicable to straight lines rather than to points. The
+essential features of the subject are most easily elucidated by
+analytical methods: we shall therefore begin with the notion of line
+coordinates, and in order to emphasize the merits of the system of
+coordinates ultimately adopted, we first notice a system without these
+advantages, but often useful in special investigations.
+
+  In ordinary Cartesian coordinates the two equations of a straight line
+  may be reduced to the form y = rx + s, z = tx + u, and r, s, t, u may
+  be regarded as the four coordinates of the line. These coordinates
+  lack symmetry: moreover, in changing from one base of reference to
+  another the transformation is not linear, so that the degree of an
+  equation is deprived of real significance. For purposes of the general
+  theory we employ homogeneous coordinates; if x1y1z1w1 and x2y2z2w2 are
+  two points on the line, it is easily verified that the six
+  determinants of the array
+
+    |x1y1z1w1|
+    |x2y2z2w2|
+
+  are in the same ratios for all point-pairs on the line, and further,
+  that when the point coordinates undergo a linear transformation so
+  also do these six determinants. We therefore adopt these six
+  determinants for the coordinates of the line, and express them by the
+  symbols l, [lambda], m, [mu], n, [nu] where l = x1w2 - x2w1, [lambda]
+  = y1z2 - y2z1, &c. There is the further advantage that if a1b1c1d1 and
+  a2b2c2d2 be two planes through the line, the six determinants
+
+    |a1b1c1d1|
+    |a2b2c2d2|
+
+  are in the same ratios as the foregoing, so that except as regards a
+  factor of proportionality we have [lambda] = b1c2 - b2c1, l = c1d2 -
+  c2d1, &c. The identical relation l[lambda] + m[mu] + n[nu] = o reduces
+  the number of independent constants in the six coordinates to four,
+  for we are only concerned with their mutual ratios; and the quadratic
+  character of this relation marks an essential difference between point
+  geometry and line geometry. The condition of intersection of two lines
+  is
+
+    l[lambda]' + l'[lambda] + m[mu]' + m'[mu] + n[nu]' + n'[nu] = 0
+
+  where the accented letters refer to the second line. If the
+  coordinates are Cartesian and l, m, n are direction cosines, the
+  quantity on the left is the mutual moment of the two lines.
+
+  Since a line depends on four constants, there are three distinct types
+  of configurations arising in line geometry--those containing a
+  triply-infinite, a doubly-infinite and a singly-infinite number of
+  lines; they are called Complexes, Congruences, and Ruled Surfaces or
+  Skews respectively. A _Complex_ is thus a system of lines satisfying
+  one condition--that is, the coordinates are connected by a single
+  relation; and the degree of the complex is the degree of this equation
+  supposing it to be algebraic. The lines of a complex of the nth degree
+  which pass through any point lie on a cone of the nth degree, those
+  which lie in any plane envelop a curve of the nth class and there are
+  n lines of the complex in any plane pencil; the last statement
+  combines the former two, for it shows that the cone is of the nth
+  degree and the curve is of the nth class. To find the lines common to
+  four complexes of degrees n1, n2, n3, n4, we have to solve five
+  equations, viz. the four complex equations together with the quadratic
+  equation connecting the line coordinates, therefore the number of
+  common lines is 2n1n2n3n4. As an example of complexes we have the
+  lines meeting a twisted curve of the nth degree, which form a complex
+  of the nth degree.
+
+  A _Congruence_ is the set of lines satisfying two conditions: thus a
+  finite number m of the lines pass through any point, and a finite
+  number n lie in any plane; these numbers are called the degree and
+  class respectively, and the congruence is symbolically written (m, n).
+
+  The simplest example of a congruence is the system of lines
+  constituted by all those that pass through m points and those that lie
+  in n planes; through any other point there pass m of these lines, and
+  in any other plane there lie n, therefore the congruence is of degree
+  m and class n. It has been shown by G.H. Halphen that the number of
+  lines common to two congruences is mm' + nn', which may be verified by
+  taking one of them to be of this simple type. The lines meeting two
+  fixed lines form the general (1, 1) congruence; and the chords of a
+  twisted cubic form the general type of a (1, 3) congruence; Halphen's
+  result shows that two twisted cubics have in general ten common
+  chords. As regards the analytical treatment, the difficulty is of the
+  same nature as that arising in the theory of curves in space, for a
+  congruence is not in general the complete intersection of two
+  complexes.
+
+  A _Ruled Surface_, _Regulus_ or _Skew_ is a configuration of lines
+  which satisfy three conditions, and therefore depend on only one
+  parameter. Such lines all lie on a surface, for we cannot draw one
+  through an arbitrary point; only one line passes through a point of
+  the surface; the simplest example, that of a quadric surface, is
+  really two skews on the same surface.
+
+  The degree of a ruled surface _qua_ line geometry is the number of its
+  generating lines contained in a linear complex. Now the number which
+  meets a given line is the degree of the surface _qua_ point geometry,
+  and as the lines meeting a given line form a particular case of linear
+  complex, it follows that the degree is the same from whichever point
+  of view we regard it. The lines common to three complexes of degrees,
+  n1n2n3, form a ruled surface of degree 2n1n2n3; but not every ruled
+  surface is the complete intersection of three complexes.
+
+
+    Linear complex.
+
+  In the case of a complex of the first degree (or linear complex) the
+  lines through a fixed point lie in a plane called the polar plane or
+  nul-plane of that point, and those lying in a fixed plane pass through
+  a point called the nul-point or pole of the plane. If the nul-plane of
+  A pass through B, then the nul-plane of B will pass through A; the
+  nul-planes of all points on one line l1 pass through another line l2.
+  The relation between l1 and l2 is reciprocal; any line of the complex
+  that meets one will also meet the other, and every line meeting both
+  belongs to the complex. They are called conjugate or polar lines with
+  respect to the complex. On these principles can be founded a theory of
+  reciprocation with respect to a linear complex.
+
+  This may be aptly illustrated by an elegant example due to A. Voss.
+  Since a twisted cubic can be made to satisfy twelve conditions, it
+  might be supposed that a finite number could be drawn to touch four
+  given lines, but this is not the case. For, suppose one such can be
+  drawn, then its reciprocal with respect to any linear complex
+  containing the four lines is a curve of the third class, i.e. another
+  twisted cubic, touching the same four lines, which are unaltered in
+  the process of reciprocation; as there is an infinite number of
+  complexes containing the four lines, there is an infinite number of
+  cubics touching the four lines, and the problem is poristic.
+
+  The following are some geometrical constructions relating to the
+  unique linear complex that can be drawn to contain five arbitrary
+  lines:
+
+  To construct the nul-plane of any point O, we observe that the two
+  lines which meet any four of the given five are conjugate lines of the
+  complex, and the line drawn through O to meet them is therefore a ray
+  of the complex; similarly, by choosing another four we can find
+  another ray through O: these rays lie in the nul-plane, and there is
+  clearly a result involved that the five lines so obtained all lie in
+  one plane. A reciprocal construction will enable us to find the
+  nul-point of any plane. Proceeding now to the metrical properties and
+  the statical and dynamical applications, we remark that there is just
+  one line such that the nul-plane of any point on it is perpendicular
+  to it. This is called the central axis; if d be the shortest distance,
+  [theta] the angle between it and a ray of the complex, then d tan
+  [theta] = p, where p is a constant called the pitch or parameter. Any
+  system of forces can be reduced to a force R along a certain line, and
+  a couple G perpendicular to that line; the lines of nul-moment for the
+  system form a linear complex of which the given line is the central
+  axis and the quotient G/R is the pitch. Any motion of a rigid body can
+  be reduced to a screw motion about a certain line, i.e. to an angular
+  velocity [omega] about that line combined with a linear velocity u
+  along the line. The plane drawn through any point perpendicular to the
+  direction of its motion is its nul-plane with respect to a linear
+  complex having this line for central axis, and the quotient u/[omega]
+  for pitch (cf. Sir R.S. Ball, _Theory of Screws_).
+
+  The following are some properties of a configuration of two linear
+  complexes:
+
+  The lines common to the two-complexes also belong to an infinite
+  number of linear complexes, of which two reduce to single straight
+  lines. These two lines are conjugate lines with respect to each of the
+  complexes, but they may coincide, and then some simple modifications
+  are required. The locus of the central axis of this system of
+  complexes is a surface of the third degree called the cylindroid,
+  which plays a leading part in the theory of screws as developed
+  synthetically by Ball. Since a linear complex has an invariant of the
+  second degree in its coefficients, it follows that two linear
+  complexes have a lineo-linear invariant. This invariant is
+  fundamental: if the complexes be both straight lines, its vanishing is
+  the condition of their intersection as given above; if only one of
+  them be a straight line, its vanishing is the condition that this line
+  should belong to the other complex. When it vanishes for any two
+  complexes they are said to be in _involution_ or _apolar_; the
+  nul-points P, Q of any plane then divide harmonically the points in
+  which the plane meets the common conjugate lines, and each complex is
+  its own reciprocal with respect to the other. As regards a
+  configuration of these linear complexes, the common lines from one
+  system of generators of a quadric, and the doubly infinite system of
+  complexes containing the common lines, include an infinite number of
+  straight lines which form the other system of generators of the same
+  quadric.
+
+
+    General line coordinates.
+
+  If the equation of a linear complex is Al + Bm + Cn + D[lambda] +
+  E[mu] + F[nu] = 0, then for a line not belonging to the complex we may
+  regard the expression on the left-hand side as a multiple of the
+  moment of the line with respect to the complex, the word moment being
+  used in the statical sense; and we infer that when the coordinates are
+  replaced by linear functions of themselves the new coordinates are
+  multiples of the moments of the line with respect to six fixed
+  complexes. The essential features of this coordinate system are the
+  same as those of the original one, viz. there are six coordinates
+  connected by a quadratic equation, but this relation has in general a
+  different form. By suitable choice of the six fundamental complexes,
+  as they may be called, this connecting relation may be brought into
+  other simple forms of which we mention two: (i.) When the six are
+  mutually in involution it can be reduced to x1^2 + x2^2 + x3^2 + x4^2
+  + x5^2 + x6^2 = 0; (ii.) When the first four are in involution and the
+  other two are the lines common to the first four it is x1^2 + x2^2 +
+  x3^2 + x4^2 - 2x5x6 = 0. These generalized coordinates might be
+  explained without reference to actual magnitude, just as homogeneous
+  point coordinates can be; the essential remark is that the equation of
+  any coordinate to zero represents a linear complex, a point of view
+  which includes our original system, for the equation of a coordinate
+  to zero represents all the lines meeting an edge of the fundamental
+  tetrahedron.
+
+  The system of coordinates referred to six complexes mutually in
+  involution was introduced by Felix Klein, and in many cases is more
+  useful than that derived directly from point coordinates; e.g. in the
+  discussion of quadratic complexes: by means of it Klein has developed
+  an analogy between line geometry and the geometry of spheres as
+  treated by G. Darboux and others. In fact, in that geometry a point is
+  represented by _five_ coordinates, connected by a relation of the same
+  type as the one just mentioned when the five fundamental spheres are
+  mutually at right angles and the equation of a sphere is of the first
+  degree. Extending this to four dimensions of space, we obtain an exact
+  analogue of line geometry, in which (i.) a point corresponds to a
+  line; (ii.) a linear complex to a hypersphere; (iii.) two linear
+  complexes in involution to two orthogonal hyperspheres; (iv.) a linear
+  complex and two conjugate lines to a hypersphere and two inverse
+  points. Many results may be obtained by this principle, and more still
+  are suggested by trying to extend the properties of circles to spheres
+  in three and four dimensions. Thus the elementary theorem, that, given
+  four lines, the circles circumscribed to the four triangles formed by
+  them are concurrent, may be extended to six hyperplanes in four
+  dimensions; and then we can derive a result in line geometry by
+  translating the inverse of this theorem. Again, just as there is an
+  infinite number of spheres touching a surface at a given point, two of
+  them having contact of a closer nature, so there is an infinite number
+  of linear complexes touching a non-linear complex at a given line, and
+  _three_ of these have contact of a closer nature (cf. Klein, _Math.
+  Ann._ v.).
+
+  Sophus Lie has pointed out a different analogy with sphere geometry.
+  Suppose, in fact, that the equation of a sphere of radius r is
+
+    x^2 + y^2 + z^2 + 2ax + 2by + 2cz + d = 0,
+
+  so that r^2 = a^2 + b^2 + c^2 - d; then introducing the quantity e to
+  make this equation homogeneous, we may regard the sphere as given by
+  the six coordinates a, b, c, d, e, r connected by the equation a^2 +
+  b^2 + c^2 - r^2 - de = 0, and it is easy to see that two spheres
+  touch, if the polar form 2aa1 + 2bb1 + 2cc1 - 2rr1 - de1 - d1e
+  vanishes. Comparing this with the equation x1^2 + x2^2 + x3^2 + x4^2 -
+  2x5x6 = 0 given above, it appears that this sphere geometry and line
+  geometry are identical, for we may write a = x1, b = x2, c = x3, r =
+  x4(/[delta] - 1), d = x5, e = 1/2x6; but it is to be noticed that a
+  sphere is really replaced by two lines whose coordinates only differ
+  in the sign of x4, so that they are polar lines with respect to the
+  complex x4 = 0. Two spheres which touch correspond to two lines which
+  intersect, or more accurately to two pairs of lines (p, p') and (q,
+  q'), of which the pairs (p, q) and (p', q') both intersect. By this
+  means the problem of describing a sphere to touch four given spheres
+  is reduced to that of drawing a pair of lines (t, t') (of which t
+  intersects one line of the four pairs (pp'), (qq'), (rr'), (ss'), and
+  t' intersects the remaining four). We may, however, ignore the
+  accented letters in translating theorems, for a configuration of lines
+  and its polar with respect to a linear complex have the same
+  projective properties. In Lie's transformation a linear complex
+  corresponds to the totality of spheres cutting a given sphere at a
+  given angle. A most remarkable result is that lines of curvature in
+  the sphere geometry become asymptotic lines in the line geometry.
+
+  Some of the principles of line geometry may be brought into clearer
+  light by admitting the ideas of space of four and five dimensions.
+
+  Thus, regarding the coordinates of a line as homogeneous coordinates
+  in five dimensions, we may say that line geometry is equivalent to
+  geometry on a quadric surface in five dimensions. A linear complex is
+  represented by a hyperplane section; and if two such complexes are in
+  involution, the corresponding hyperplanes are conjugate with respect
+  to the fundamental quadric. By projecting this quadric
+  stereographically into space of four dimensions we obtain Klein's
+  analogy. In the same way geometry in a linear complex is equivalent to
+  geometry on a quadric in four dimensions; when two lines intersect the
+  representative points are on the same generator of this quadric.
+  Stereographic projection, therefore, converts a curve in a linear
+  complex, i.e. one whose tangents all belong to the complex, into one
+  whose tangents intersect a fixed conic: when this conic is the
+  imaginary circle at infinity the curve is what Lie calls a minimal
+  curve. Curves in a linear complex have been extensively studied. The
+  osculating plane at any point of such a curve is the nul-plane of the
+  point with respect to the complex, and points of superosculation
+  always coincide in pairs at the points of contact of stationary
+  tangents. When a point of such a curve is given, the osculating plane
+  is determined, hence all the curves through a given point with the
+  same tangent have the same torsion.
+
+
+    Non-linear complexes.
+
+  The lines through a given point that belong to a complex of the nth
+  degree lie on a cone of the nth degree: if this cone has a double line
+  the point is said to be a singular point. Similarly, a plane is said
+  to be singular when the envelope of the lines in it has a double
+  tangent. It is very remarkable that the same surface is the locus of
+  the singular points and the envelope of the singular planes: this
+  surface is called the singular surface, and both its degree and class
+  are in general 2n(n - 1)^2, which is equal to four for the quadratic
+  complex.
+
+  The singular lines of a complex F = 0 are the lines common to F and
+  the complex
+
+    [delta]F    [delta]F       [delta]F    [delta]F    [delta]F    [delta]F
+    -------- --------------- + --------  ----------- + --------  ----------- = 0.
+    [delta]l [delta][lambda]   [delta]m  [delta][mu]   [delta]n  [delta][nu]
+
+  As already mentioned, at each line l of a complex there is an infinite
+  number of tangent linear complexes, and they all contain the lines
+  adjacent to l. If now l be a singular line, these complexes all reduce
+  to straight lines which form a plane pencil containing the line l.
+  Suppose the vertex of the pencil is A, its plane a, and one of its
+  lines [xi], then l' being a complex line near l, meets [xi], or more
+  accurately the mutual moment of l', and is of the second order of
+  small quantities. If P be a point on l, a line through P quite near l
+  in the plane a will meet [xi] and is therefore a line of the complex;
+  hence the complex-cones of all points on l touch a and the
+  complex-curves of all planes through l touch l at A. It follows that l
+  is a double line of the complex-cone of A, and a double tangent of the
+  complex-curve of a. Conversely, a double line of a cone or curve is a
+  singular line, and a singular line clearly touches the curves of all
+  planes through it in the same point. Suppose now that the consecutive
+  line l' is also a singular line, A' being the allied singular point,
+  a' the singular plane and [xi]' any line of the pencil (A', a') so
+  that [xi]' is a tangent line at l' to the complex: the mutual moments
+  of the pairs l', [xi] and l, [xi] are each of the second order; hence
+  the plane a' meets the lines l and [xi]' in two points very near A.
+  This being true for all singular planes, near a the point of contact
+  of a with its envelope is in A, i.e. the locus of singular points is
+  the same as the envelope of singular planes. Further, when a line
+  touches a complex it touches the singular surface, for it belongs to a
+  plane pencil like (Aa), and thus in Klein's analogy the analogue of a
+  focus of a hyper-surface being a bitangent line of the complex is also
+  a bitangent line of the singular surface. The theory of cosingular
+  complexes is thus brought into line with that of confocal surfaces in
+  four dimensions, and guided by these principles the existence of
+  cosingular quadratic complexes can easily be established, the analysis
+  required being almost the same as that invented for confocal cyclides
+  by Darboux and others. Of cosingular complexes of higher degree
+  nothing is known.
+
+  Following J. Plucker, we give an account of the lines of a quadratic
+  complex that meet a given line.
+
+  The cones whose vertices are on the given line all pass through eight
+  fixed points and envelop a surface of the fourth degree; the conics
+  whose planes contain the given line all lie on a surface of the fourth
+  class and touch eight fixed planes. It is easy to see by elementary
+  geometry that these two surfaces are identical. Further, the given
+  line contains four singular points A1, A2, A3, A4, and the planes into
+  which their cones degenerate are the eight common tangent planes
+  mentioned above; similarly, there are four singular planes, a1, a2,
+  a3, a4, through the line, and the eight points into which their conics
+  degenerate are the eight common points above. The locus of the pole of
+  the line with respect to all the conics in planes through it is a
+  straight line called the _polar line_ of the given one; and through
+  this line passes the polar plane of the given line with respect to
+  each of the cones. The name polar is applied in the ordinary
+  analytical sense; any line has an infinite number of polar complexes
+  with respect to the given complex, for the equation of the latter can
+  be written in an infinite number of ways; one of these polars is a
+  straight line, and is the polar line already introduced. The surface
+  on which lie all the conics through a line l is called the Plucker
+  surface of that line: from the known properties of (2, 2)
+  correspondences it can be shown that the Plucker surface of l cuts l1
+  in a range of the same cross ratio as that of the range in which the
+  Plucker surface of l1 cuts l. Applying this to the case in which l1 is
+  the polar of l, we find that the cross ratios of (A1, A2, A3, A4) and
+  (a1, a2, a3, a4) are equal. The identity of the locus of the A's with
+  the envelope of the a's follows at once; moreover, a line meets the
+  singular surface in four points having the same cross ratio as that of
+  the four tangent planes drawn through the line to touch the surface.
+  The Plucker surface has eight nodes, eight singular tangent planes,
+  and is a double line. The relation between a line and its polar line
+  is not a reciprocal one with respect to the complex; but W. Stahl has
+  pointed out that the relation is reciprocal as far as the singular
+  surface is concerned.
+
+
+    Quadratic complexes.
+
+  To facilitate the discussion of the general quadratic complex we
+  introduce Klein's canonical form. We have, in fact, to deal with two
+  quadratic equations in six variables; and by suitable linear
+  transformations these can be reduced to the form
+
+    a1x1^2 + a2x2^2 + a3x3^2 + a4x4^2 + a5x5^2 +  a6x6^2 = 0
+     x1^2  +  x2^2  +  x3^2  +  x4^2  +  x5^2  +   x6^2  = 0
+
+  subject to certain exceptions, which will be mentioned later.
+
+  Taking the first equation to be that of the complex, we remark that
+  both equations are unaltered by changing the sign of any coordinate;
+  the geometrical meaning of this is, that the quadratic complex is its
+  own reciprocal with respect to each of the six fundamental complexes,
+  for changing the sign of a coordinate is equivalent to taking the
+  polar of a line with respect to the corresponding fundamental complex.
+  It is easy to establish the existence of six systems of bitangent
+  linear complexes, for the complex l1x1 + l2x2 + l3x3 + l4x4 + l5x5 +
+  l6x6 = 0 is a bitangent when
+
+                  l2^2      l3^2      l4^2      l5^2      l6^2
+    l1 = 0, and ------- + ------- + ------- + ------- + ------- = 0
+                a2 - a1   a3 - a1   a4 - a1   a5 - a1   a6 - a1
+
+  and its lines of contact are conjugate lines with respect to the first
+  fundamental complex. We therefore infer the existence of six systems
+  of bitangent lines of the complex, of which the first is given by
+
+              x2^2      x3^2      x4^2      x5^2      x6^2
+    x1 = 0, ------- + ------- + ------- + ------- + ------- = 0.
+            a2 - a1   a3 - a1   a4 - a1   a5 - a1   a6 - a1
+
+  Each of these lines is a bitangent of the singular surface, which is
+  therefore completely determined as being the focal surface of the (2,
+  2) congruence above. It is thence easy to verify that the two
+  complexes [Sigma]ax^2 = 0 and [Sigma]bx^2 = 0 are cosingular if b_r =
+  a_r[lambda] + [mu]/a_r[nu] + [rho].
+
+  The singular surface of the general quadratic complex is the famous
+  quartic, with sixteen nodes and sixteen singular tangent planes, first
+  discovered by E.E. Kummer.
+
+  We cannot give a full account of its properties here, but we deduce at
+  once from the above that its bitangents break up into six (2, 2)
+  congruences, and the six linear complexes containing these are
+  mutually in involution. The nodes of the singular surface are points
+  whose complex cones are coincident planes, and the complex conic in a
+  singular tangent plane consists of two coincident points. This
+  configuration of sixteen points and planes has many interesting
+  properties; thus each plane contains six points which lie on a conic,
+  while through each point there pass six planes which touch a quadric
+  cone. In many respects the Kummer quartic plays a part in three
+  dimensions analogous to the general quartic curve in two; it further
+  gives a natural representation of certain relations between
+  hyperelliptic functions (cf. R.W.H.T. Hudson, _Kummer's Quartic_,
+  1905).
+
+
+    Classification of quadratic complexes.
+
+  As might be expected from the magnitude of a form in six variables,
+  the number of projectivally distinct varieties of quadratic complexes
+  is very great; and in fact Adolf Weiler, by whom the question was
+  first systematically studied on lines indicated by Klein, enumerated
+  no fewer than forty-nine different types. But the principle of the
+  classification is so important, and withal so simple, that we give a
+  brief sketch which indicates its essential features.
+
+  We have practically to study the intersection of two quadrics F and F'
+  in six variables, and to classify the different cases arising we make
+  use of the results of Karl Weierstrass on the equivalence conditions
+  of two pairs of quadratics. As far as at present required, they are as
+  follows: Suppose that the factorized form of the determinantal
+  equation Disct (F + [lambda]F') = 0 is
+
+    ([lambda] - [alpha])^(s1 + s2 + s3 ...)
+      ([lambda] - [beta])^(t1 + t2 + t3 + ...) ...
+
+  where the root [alpha] occurs s1 + s2 + s3 ... times in the
+  determinant, s2 + s3 ... times in every first minor, s3 + ... times in
+  every second minor, and so on; the meaning of each exponent is then
+  perfectly definite. Every factor of the type ([lambda] - [alpha])^s is
+  called an _elementartheil_ (elementary divisor) of the determinant,
+  and the condition of equivalence of two pairs of quadratics is simply
+  that their determinants have the same elementary divisors. We write
+  the pair of forms symbolically thus [(s1s2 ...), (t1t2 ...), ...],
+  letters in the inner brackets referring to the same factor. Returning
+  now to the two quadratics representing the complex, the sum of the
+  exponents will be six, and two complexes are put in the same class if
+  they have the same symbolical expression; i.e. the actual values of
+  the roots of the determinantal equation need not be the same for both,
+  but their manner of occurrence, as far as here indicated, must be
+  identical in the two. The enumeration of all possible cases is thus
+  reduced to a simple question in combinatorial analysis, and the actual
+  study of any particular case is much facilitated by a useful rule of
+  Klein's for writing down in a simple form two quadratics belonging to
+  a given class--one of which, of course, represents the equation
+  connecting line coordinates, and the other the equation of the
+  complex. The general complex is naturally [111111]; the complex of
+  tangents to a quadric is [(111), (111)] and that of lines meeting a
+  conic is [(222)]. Full information will be found in Weiler's memoir,
+  _Math. Ann._ vol. vii.
+
+  The detailed study of each variety of complex opens up a vast subject;
+  we only mention two special cases, the harmonic complex and the
+  tetrahedral complex.
+
+  The harmonic complex, first studied by Battaglini, is generated in an
+  infinite number of ways by the lines cutting two quadrics
+  harmonically. Taking the most general case, and referring the quadrics
+  to their common self-conjugate tetrahedron, we can find its equation
+  in a simple form, and verify that this complex really depends only on
+  seventeen constants, so that it is not the most general quadratic
+  complex. It belongs to the general type in so far as it is discussed
+  above, but the roots of the determinant are in involution. The
+  singular surface is the "tetrahedroid" discussed by Cayley. As a
+  particular case, from a metrical point of view, we have L.F. Painvin's
+  complex generated by the lines of intersection of perpendicular
+  tangent planes of a quadric, the singular surface now being Fresnel's
+  wave surface. The tetrahedral or Reye complex is the simplest and best
+  known of proper quadratic complexes. It is generated by the lines
+  which cut the faces of a tetrahedron in a constant cross ratio, and
+  therefore by those subtending the same cross ratio at the four
+  vertices. The singular surface is made up of the faces or the vertices
+  of the fundamental tetrahedron, and each edge of this tetrahedron is a
+  double line of the complex. The complex was first discussed by K.T.
+  Reye as the assemblage of lines joining corresponding points in a
+  homographic transformation of space, and this point of view leads to
+  many important and elegant properties. A (metrically) particular case
+  of great interest is the complex generated by the normals to a family
+  of confocal quadrics, and for many investigations it is convenient to
+  deal with this complex referred to the principal axes. For example,
+  Lie has developed the theory of curves in a Reye complex (i.e. curves
+  whose tangents belong to the complex) as solutions of a differential
+  equation of the form (b - c)xdydz + (c - a)ydzdx + (a - b)zdxdy = 0,
+  and we can simplify this equation by a logarithmic transformation.
+  Many theorems connecting complexes with differential equations have
+  been given by Lie and his school. A line complex, in fact, corresponds
+  to a Mongian equation having [oo]^3 line integrals.
+
+
+    Congruences.
+
+  As the coordinates of a line belonging to a congruence are functions
+  of two independent parameters, the theory of congruences is analogous
+  to that of surfaces, and we may regard it as a fundamental inquiry to
+  find the simplest form of surface into which a given congruence can be
+  transformed. Most of those whose properties have been extensively
+  discussed can be represented on a plane by a birational
+  transformation. But in addition to the difficulties of the theory of
+  algebraic surfaces, a subject still in its infancy, the theory of
+  congruences has other difficulties in that a congruence is seldom
+  completely represented, even by two equations.
+
+  A fundamental theorem is that the lines of a congruence are in general
+  bitangents of a surface; in fact, since the condition of intersection
+  of two consecutive straight lines is ld[lambda] + dmd[mu] + dnd[nu] =
+  0, a line l of the congruence meets two adjacent lines, say l1 and l2.
+  Suppose l, l1 lie in the plane pencil (A1a1) and l, l2 in the plane
+  pencil (A2a2), then the locus of the A's is the same as the envelope
+  of the a's, but a2 is the tangent plane at A1 and a1 at A2. This
+  surface is called the focal surface of the congruence, and to it all
+  the lines l are bitangent. The distinctive property of the points A is
+  that two of the congruence lines through them coincide, and in like
+  manner the planes a each contain two coincident lines. The focal
+  surface consists of two sheets, but one or both may degenerate into
+  curves; thus, for example, the normals to a surface are bitangents of
+  the surface of centres, and in the case of Dupin's cyclide this
+  surface degenerates into two conics.
+
+  In the discussion of congruences it soon becomes necessary to
+  introduce another number r, called the rank, which expresses the
+  number of plane pencils each of which contains an arbitrary line and
+  two lines of the congruence. The order of the focal surface is 2m(n -
+  1) - 2r, and its class is m(m - 1) - 2r. Our knowledge of congruences
+  is almost exclusively confined to those in which either m or n does
+  not exceed two. We give a brief account of those of the second order
+  without singular lines, those of order unity not being especially
+  interesting. A congruence generally has singular points through which
+  an infinite number of lines pass; a singular point is said to be of
+  order r when the lines through it lie on a cone of the rth degree. By
+  means of formulae connecting the number of singular points and their
+  orders with the class m of quadratic congruence Kummer proved that the
+  class cannot exceed seven. The focal surface is of degree four and
+  class 2m; this kind of quartic surface has been extensively studied by
+  Kummer, Cayley, Rohn and others. The varieties (2, 2), (2, 3), (2, 4),
+  (2, 5) all belong to at least one Reye complex; and so also does the
+  most important class of (2, 6) congruences which includes all the
+  above as special cases. The congruence (2, 2) belongs to a linear
+  complex and forty different Reye complexes; as above remarked, the
+  singular surface is Kummer's sixteen-nodal quartic, and the same
+  surface is focal for six different congruences of this variety. The
+  theory of (2, 2) congruences is completely analogous to that of the
+  surfaces called cyclides in three dimensions. Further particulars
+  regarding quadratic congruences will be found in Kummer's memoir of
+  1866, and the second volume of Sturm's treatise. The properties of
+  quadratic congruences having singular lines, i.e. degenerate focal
+  surfaces, are not so interesting as those of the above class; they
+  have been discussed by Kummer, Sturm and others.
+
+
+    Ruled surfaces.
+
+  Since a ruled surface contains only [infinity]^1 elements, this theory
+  is practically the same as that of curves. If a linear complex
+  contains more than n generators of a ruled surface of the nth degree,
+  it contains all the generators, hence for n = 2 there are three
+  linearly independent complexes, containing all the generators, and
+  this is a well-known property of quadric surfaces. In ruled cubics the
+  generators all meet two lines which may or may not coincide; these two
+  cases correspond to the two main classes of cubics discussed by Cayley
+  and Cremona. As regards ruled quartics, the generators must lie in one
+  and may lie in two linear complexes. The first class is equivalent to
+  a quartic in four dimensions and is always rational, but the latter
+  class has to be subdivided into the elliptic and the rational, just
+  like twisted quartic curves. A quintic skew may not lie in a linear
+  complex, and then it is unicursal, while of sextics we have two
+  classes not in a linear complex, viz. the elliptic variety, having
+  thirty-six places where a linear complex contains six consecutive
+  generators, and the rational, having six such places.
+
+  The general theory of skews in two linear complexes is identical with
+  that of curves on a quadric in three dimensions and is known. But for
+  skews lying in only one linear complex there are difficulties; the
+  curve now lies in four dimensions, and we represent it in three by
+  stereographic projection as a curve meeting a given plane in n points
+  on a conic. To find the maximum deficiency for a given degree would
+  probably be difficult, but as far as degree eight the space-curve
+  theory of Halphen and Nother can be translated into line geometry at
+  once. When the skew does not lie in a linear complex at all the theory
+  is more difficult still, and the general theory clearly cannot advance
+  until further progress is made in the study of twisted curves.
+
+  REFERENCES.--The earliest works of a general nature are Plucker, _Neue
+  Geometrie des Raumes_ (Leipzig, 1868); and Kummer, "Uber die
+  algebraischen Strahlensysteme," _Berlin Academy_ (1866). Systematic
+  development on purely synthetic lines will be found in the three
+  volumes of Sturm, _Liniengeometrie_ (Leipzig, 1892, 1893, 1896); vol.
+  i. deals with the linear and Reye complexes, vols. ii. and iii. with
+  quadratic congruences and complexes respectively. For a highly
+  suggestive review by Gino Loria see _Bulletin des sciences
+  mathematiques_ (1893, 1897). A shorter treatise, giving a very
+  interesting account of Klein's coordinates, is the work of Koenigs,
+  _La Geometrie reglee et ses applications_ (Paris, 1898). English
+  treatises are C.M. Jessop, _Treatise on the Line Complex_ (1903);
+  R.W.H.T. Hudson, _Kummer's Quartic_ (1905). Many references to memoirs
+  on line geometry will be found in Hagen, _Synopsis der hoheren
+  Mathematik_, ii. (Berlin, 1894); Loria, _Il passato ed il presente
+  delle principali teorie geometriche_ (Milan, 1897); a clear resume of
+  the principal results is contained in the very elegant volume of
+  Pascal, _Repertorio di mathematiche superiori_, ii. (Milan, 1900).
+  Another treatise dealing extensively with line geometry is Lie,
+  _Geometrie der Beruhrungstransformationen_ (Leipzig, 1896). Many
+  memoirs on the subject have appeared in the _Mathematische Annalen_; a
+  full list of these will be found in the index to the first fifty
+  volumes, p. 115. Perhaps the two memoirs which have left most
+  impression on the subsequent development of the subject are Klein,
+  "Zur Theorie der Liniencomplexe des ersten und zweiten Grades," _Math.
+  Ann._ ii.; and Lie, "Uber Complexe, insbesondere Linien- und
+  Kugelcomplexe," _Math. Ann._ v.     (J. H. Gr.)
+
+
+VI. NON-EUCLIDEAN GEOMETRY
+
+The various metrical geometries are concerned with the properties of the
+various types of congruence-groups, which are defined in the study of
+the _axioms_ of _geometry_ and of their immediate consequences. But this
+point of view of the subject is the outcome of recent research, and
+historically the subject has a different origin. Non-Euclidean geometry
+arose from the discussion, extending from the Greek period to the
+present day, of the various assumptions which are implicit in the
+traditional Euclidean system of geometry. In the course of these
+investigations it became evident that metrical geometries, each
+internally consistent but inconsistent in many respects with each other
+and with the Euclidean system, could be developed. A short historical
+sketch will explain this origin of the subject, and describe the famous
+and interesting progress of thought on the subject. But previously a
+description of the chief characteristic properties of elliptic and of
+hyperbolic geometries will be given, assuming the standpoint arrived at
+below under VII. _Axioms of Geometry_.
+
+First assume the equation to the absolute (cf. _loc. cit._) to be w^2 -
+x^2 - y^2 - z^2 = 0. The absolute is then real, and the geometry is
+hyberbolic.
+
+  The distance (d12) between the two points (x1, y1, z1, w1) and (x2,
+  y2, z2, w2) is given by
+
+    cosh (d12/[gamma]) = (w1w2 - x1x2 - y1y2 - z1z2)/[(w1^2 - x1^2 - y1^2 - Z1^2)
+      (w2^2 - x2^2 - y2^2 - z2^2)]1/2     (1)
+
+  The only points to which the metrical geometry applies are those
+  within the region enclosed by the quadric; the other points are
+  "improper ideal points." The angle ([theta]12) between two planes, l1x
+  + m1y + n1z + r1w = 0 and l2x + m2y + n2z + r2w = 0, is given by
+
+  cos [theta]12 = (l1l2 + m1m2 + n1n2 - r1r2)/{(l1^2 + m1^2 + n1^2 - r1^2)
+    (l2^2 + m2^2 + n2^2 - r2^2)}^1/2       (2)
+
+  These planes only have a real angle of inclination if they possess a
+  line of intersection within the actual space, i.e. if they intersect.
+  Planes which do not intersect possess a shortest distance along a line
+  which is perpendicular to both of them. If this shortest distance is
+  [delta]12, we have
+
+    cosh ([delta]12/[gamma]) = (l1l2 + m1m2 + n1n2 - r1r2)/(l1^2 + m1^2 + n1^2 - r1^2)
+      (l2^2 + m2^2 + n2^2 - r2^2)^1/2     (3)
+
+  [Illustration: FIG. 67.]
+
+  Thus in the case of the two planes one and only one of the two,
+  [theta]12 and [delta]12, is real. The same considerations hold for
+  coplanar straight lines (see VII. _Axioms of Geometry_). Let O (fig.
+  67) be the point (0, 0, 0, 1), OX the line y = 0, z = 0, OY the line z
+  = 0, x = 0, and OZ the line x = 0, y = 0. These are the coordinate
+  axes and are at right angles to each other. Let P be any point, and
+  let [rho] be the distance OP, [theta] the angle POZ, and [phi] the
+  angle between the planes ZOX and ZOP. Then the coordinates of P can be
+  taken to be
+
+    sinh ([rho]/[gamma]) sin [theta] cos [phi], sinh ([rho]/[gamma]) sin [theta]
+      sin [phi], sinh ([rho]/[gamma]) cos[theta], cosh ([rho]/[gamma]).
+
+  [Illustration: FIG. 68.]
+
+  If ABC is a triangle, and the sides and angles are named according to
+  the usual convention, we have
+
+    sinh (a/[gamma])/sin A = sinh (b/[gamma])/sin B = sinh (c/[gamma])/sin C, (4)
+
+  and also
+
+    cosh (a/[gamma]) = cosh (b/[gamma]) cosh (c/[gamma]) -
+      sinh (b/[gamma]) sinh (c/[gamma]) cos A,   (5)
+
+  with two similar equations. The sum of the three angles of a triangle
+  is always less than two right angles. The area of the triangle ABC is
+  [lambda]^2([pi] - A - B - C). If the base BC of a triangle is kept
+  fixed and the vertex A moves in the fixed plane ABC so that the area
+  ABC is constant, then the locus of A is a line of equal distance from
+  BC. This locus is not a straight line. The whole theory of similarity
+  is inapplicable; two triangles are either congruent, or their angles
+  are not equal two by two. Thus the elements of a triangle are
+  determined when its three angles are given. By keeping A and B and the
+  line BC fixed, but by making C move off to infinity along BC, the
+  lines BC and AC become parallel, and the sides a and b become
+  infinite. Hence from equation (5) above, it follows that two parallel
+  lines (cf. Section VII. _Axioms of Geometry_) must be considered as
+  making a zero angle with each other. Also if B be a right angle, from
+  the equation (5), remembering that, in the limit,
+
+    cosh (a/[gamma])/cosh (b/[gamma]) = cosh (a/[gamma])/sinh (b/[gamma]) = 1,
+
+  we have cos A = tanh (c/2[gamma]) .... (6).
+
+  The angle A is called by N.I. Lobatchewsky the "angle of parallelism."
+
+  The whole theory of lines and planes at right angles to each other is
+  simply the theory of conjugate elements with respect to the absolute,
+  where ideal lines and planes are introduced.
+
+  Thus if l and l' be any two conjugate lines with respect to the
+  absolute (of which one of the two must be improper, say l'), then any
+  plane through l' and containing proper points is perpendicular to l.
+  Also if p is any plane containing proper points, and P is its pole,
+  which is necessarily improper, then the lines through P are the
+  normals to P. The equation of the sphere, centre (x1, y1, z1, w1) and
+  radius [rho], is
+
+    (w1^2- x1^2- y1^2- z1^2)(w^2 - x^2 - y^2 - z^2) cosh^2([rho]/[gamma]) = (w1w -
+      x1x - y1y -z1z)^2   (7).
+
+  The equation of the surface of equal distance ([sigma]) from the plane
+  lx + my + nz + rw = 0 is
+
+    (l^2 + m^2 + n^2 - r^2)(w^2 - x^2 - y^2 - z^2) sinh^2([sigma]/[gamma]) = (rw +
+      lx + my + nz)^2    (8).
+
+  A surface of equal distance is a sphere whose centre is improper; and
+  both types of surface are included in the family
+
+    k^2(w^2 - x^2 - y^2 - z^2) = (ax + by + cz + dw)^2   (9).
+
+  But this family also includes a third type of surfaces, which can be
+  looked on either as the limits of spheres whose centres have
+  approached the absolute, or as the limits of surfaces of equal
+  distance whose central planes have approached a position tangential to
+  the absolute. These surfaces are called limit-surfaces. Thus (9)
+  denotes a limit-surface, if d^2 - a^2 - b^2 - c^2 = 0. Two
+  limit-surfaces only differ in position. Thus the two limit-surfaces
+  which touch the plane YOZ at O, but have their concavities turned in
+  opposite directions, have as their equations
+
+    w^2 - x^2 - y^2 - z^2 = (w [+-] x)^2.
+
+  The geodesic geometry of a sphere is elliptic, that of a surface of
+  equal distance is hyperbolic, and that of a limit-surface is parabolic
+  (i.e. _Euclidean_). The equation of the surface (cylinder) of equal
+  distance ([delta]) from the line OX is
+
+    (w^2 - x^2) tanh^2([delta]/[gamma]) - y^2 - z^2 = 0.
+
+  This is not a ruled surface. Hence in this geometry it is not possible
+  for two straight lines to be at a constant distance from each other.
+
+  Secondly, let the equation of the absolute be x^2 + y^2 + z^2 + w^2 =
+  0. The absolute is now imaginary and the geometry is elliptic.
+
+  The distance (d12) between the two points (x1, y1, z1, w1) and (x2,
+  y2, z2, w2) is given by
+
+    cos (d12/[gamma]) = [+-](x1x2 + y1y2 + z1z2 + w1w2)
+      / {(x1^2 + y1^2 + z1^2 + w1^2) {(x2^2 + y2^2 + z2^2 + w2^2)}^1/2   (10).
+
+  Thus there are two distances between the points, and if one is d12,
+  the other is [pi][gamma]-d12. Every straight line returns into itself,
+  forming a closed series. Thus there are two segments between any two
+  points, together forming the whole line which contains them; one
+  distance is associated with one segment, and the other distance with
+  the other segment. The complete length of every straight line is
+  [pi][gamma].
+
+  The angle between the two planes l1x + m1y + n1z + r + 1w = 0 and l2x
+  + m2y + n2z + r2w = 0 is
+
+    cos [theta]12 = (l1l2 + m1m2 + n1n2 + r1r2)/ {(l1^2 + m1^2 + n1^2 +r1^2)
+      (l2^2 + m2^2 + n2^2 + r2^2)}^1/2 (11).
+
+  The polar plane with respect to the absolute of the point (x1, y1, z1,
+  w1) is the real plane x1x + y1y + z1z + w1w = 0, and the pole of the
+  plane l1x + m1y + n1z + r1w = 0 is the point (l1, m1, n1, r1). Thus
+  (from equations 10 and 11) it follows that the angle between the polar
+  planes of the points (x1, ...) and (x2, ...) is d12/[gamma], and that
+  the distance between the poles of the planes (l1, ...) and (l2, ...)
+  is [gamma][theta]12. Thus there is complete reciprocity between points
+  and planes in respect to all properties. This complete reign of the
+  principle of duality is one of the great beauties of this geometry.
+  The theory of lines and planes at right angles is simply the theory of
+  conjugate elements with respect to the absolute. A tetrahedron
+  self-conjugate with respect to the absolute has all its intersecting
+  elements (edges and planes) at right angles. If l and l' are two
+  conjugate lines, the planes through one are the planes perpendicular
+  to the other. If P is the pole of the plane p, the lines through P are
+  the normals to the plane p. The distance from P to p is 1/2[pi][gamma].
+  Thus every sphere is also a surface of equal distance from the polar
+  of its centre, and conversely. A plane does not divide space; for the
+  line joining any two points P and Q only cuts the plane once, in L
+  say, then it is always possible to go from P to Q by the segment of
+  the line PQ which does not contain L. But P and Q may be said to be
+  separated by a plane p, if the point in which PQ cuts p lies on the
+  shortest segment between P and Q. With this sense of "separation," it
+  is possible[2] to find three points P, Q, R such that P and Q are
+  separated by the plane p, but P and R are not separated by p, nor are
+  Q and R.
+
+  Let A, B, C be any three non-collinear points, then four triangles are
+  defined by these points. Thus if a, b, c and A, B, C are the elements
+  of any one triangle, then the four triangles have as their elements:
+
+    (1)      a,                  b,                  c,             A,           B,           C.
+
+    (2)      a,            [pi][gamma] - b,   [pi][gamma] - c,      A,       [pi] - B,    [pi] - C.
+
+    (3) [pi][gamma] - a,          b,          [pi][gamma] - c,   [pi] - A,       B,       [pi] - C.
+
+    (4) [pi][gamma] - a,   [pi][gamma] - b,          c,          [pi] - A,   [pi] - B,        C.
+
+  The formulae connecting the elements are
+
+    sin A/sin (a/[gamma]) = sin B/sin (b/[gamma]) = sin C/sin (c/[gamma]),
+         (12)
+
+  and
+
+    cos (a/[gamma]) = cos (b/[gamma]) cos (c/[gamma]) + sin (b/[gamma])
+      sin (c/[gamma]) cos A,   (13)
+
+  with two similar equations.
+
+  Two cases arise, namely (I.) according as one of the four triangles
+  has as its sides the shortest segments between the angular points, or
+  (II.) according as this is not the case. When case I. holds there is
+  said to be a "principal triangle."[3] If all the figures considered
+  lie within a sphere of radius 1/4[pi][gamma] only case I. can hold, and
+  the principal triangle is the triangle wholly within this sphere, also
+  the peculiarities in respect to the separation of points by a plane
+  cannot then arise. The sum of the three angles of a triangle ABC is
+  always greater than two right angles, and the area of the triangle is
+  [gamma]^2(A + B + C--[pi]). Thus as in hyperbolic geometry the theory
+  of similarity does not hold, and the elements of a triangle are
+  determined when its three angles are given. The coordinates of a point
+  can be written in the form
+
+    sin ([rho]/[gamma]) sin [Phi] cos [phi], sin ([rho]/[gamma]) sin [Phi]
+      sin [phi], sin ([rho]/[gamma]) cos [Phi], cos ([rho]/[gamma]),
+
+  where [rho], [Phi] and [phi] have the same meanings as in the
+  corresponding formulae in hyperbolic geometry. Again, suppose a watch
+  is laid on the plane OXY, face upwards with its centre at O, and the
+  line 12 to 6 (as marked on dial) along the line YOY. Let the watch be
+  continually pushed along the plane along the line OX, that is, in the
+  direction 9 to 3. Then the line XOX being of finite length, the watch
+  will return to O, but at its first return it will be found to be face
+  downwards on the other side of the plane, with the line 12 to 6
+  reversed in direction along the line YOY. This peculiarity was first
+  pointed out by Felix Klein. The theory of parallels as it exists in
+  hyperbolic space has no application in elliptic geometry. But another
+  property of Euclidean parallel lines holds in elliptic geometry, and
+  by the use of it parallel lines are defined. For the equation of the
+  surface (cylinder) of equal distance ([delta]) from the line XOX is
+
+    (x^2 + w^2) tan^2([delta]/[gamma]) - (y^2 + z^2) = 0.
+
+  This is also the surface of equal distance, 1/2[pi][gamma]-[delta],
+  from the line conjugate to XOX. Now from the form of the above
+  equation this is a ruled surface, and through every point of it two
+  generators pass. But these generators are lines of equal distance from
+  XOX. Thus throughout every point of space two lines can be drawn which
+  are lines of equal distance from a given line l. This property was
+  discovered by W.K. Clifford. The two lines are called Clifford's right
+  and left parallels to l through the point. This property of
+  parallelism is reciprocal, so that if m is a left parallel to l, then
+  l is a left parallel to m. Note also that two parallel lines l and m
+  are not coplanar. Many of those properties of Euclidean parallels,
+  which do not hold for Lobatchewsky's parallels in hyperbolic geometry,
+  do hold for Clifford's parallels in elliptic geometry. The geodesic
+  geometry of spheres is elliptic, the geodesic geometry of surfaces of
+  equal distance from lines (cylinders) is Euclidean, and surfaces of
+  revolution can be found[4] of which the geodesic geometry is
+  hyperbolic. But it is to be noticed that the connectivity of these
+  surfaces is different to that of a Euclidean plane. For instance there
+  are only [&infin]^2 congruence transformations of the cylindrical
+  surfaces of equal distance into themselves, instead of the [&infin]^3
+  for the ordinary plane. It would obviously be possible to state
+  "axioms" which these geodesics satisfy, and thus to define
+  independently, and not as loci, quasi-spaces of these peculiar types.
+  The existence of such Euclidean quasi-geometries was first pointed out
+  by Clifford.[5]
+
+In both elliptic and hyperbolic geometry the spherical geometry, i.e.
+the relations between the angles formed by lines and planes passing
+through the same point, is the same as the "spherical trigonometry" in
+Euclidean geometry. The constant [gamma], which appears in the formulae
+both of hyperbolic and elliptic geometry, does not by its variation
+produce different types of geometry. There is only one type of elliptic
+geometry and one type of hyperbolic geometry; and the magnitude of the
+constant [gamma] in each case simply depends upon the magnitude of the
+arbitrary unit of length in comparison with the natural unit of length
+which each particular instance of either geometry presents. The
+existence of a natural unit of length is a peculiarity common both to
+hyperbolic and elliptic geometries, and differentiates them from
+Euclidean geometry. It is the reason for the failure of the theory of
+similarity in them. If [gamma] is very large, that is, if the natural
+unit is very large compared to the arbitrary unit, and if the lengths
+involved in the figures considered are not large compared to the
+arbitrary unit, then both the elliptic and hyperbolic geometries
+approximate to the Euclidean. For from formulae (4) and (5) and also
+from (12) and (13) we find, after retaining only the lowest powers of
+small quantities, as the formulae for any triangle ABC,
+
+  a/ sin A = b/ sin B = c/ sin C,
+
+and
+
+  a^2 = b^2 + c^2 - 2bc cos A,
+
+with two similar equations. Thus the geometries of small figures are in
+both types Euclidean.
+
+
+  Theory of parallels before Gauss.
+
+_History._--"In pulcherrimo Geometriae corpore," wrote Sir Henry Savile
+in 1621, "duo sunt naevi, duae labes nec quod sciam plures, in quibus
+eluendis et emaculendis cum veterum tum recentiorum ... vigilavit
+industria." These two blemishes are the theory of parallels and the
+theory of proportion. The "industry of the moderns," in both respects,
+has given rise to important branches of mathematics, while at the same
+time showing that Euclid is in these respects more free from blemish
+than had been previously credible. It was from endeavours to improve the
+theory of parallels that non-Euclidean geometry arose; and though it has
+now acquired a far wider scope, its historical origin remains
+instructive and interesting. Euclid's "axiom of parallels" appears as
+Postulate V. to the first book of his _Elements_, and is stated thus,
+"And that, if a straight line falling on two straight lines make the
+angles, internal and on the same side, less than two right angles, the
+two straight lines, being produced indefinitely, meet on the side on
+which are the angles less than two right angles." The original Greek is
+[Greek: kai ean eis duo eutheias eutheia empiptousa tas entos kai epi ta
+auta mere gonias duo orthon elassonas poie, ekballomenas tas duo
+eutheias ep' apeiron sympiptein, eph' ha mere eisin hai ton duo orthon
+elassones].
+
+To Euclid's successors this axiom had signally failed to appear
+self-evident, and had failed equally to appear indemonstrable. Without
+the use of the postulate its converse is proved in Euclid's 28th
+proposition, and it was hoped that by further efforts the postulate
+itself could be also proved. The first step consisted in the discovery
+of equivalent axioms. Christoph Clavius in 1574 deduced the axiom from
+the assumption that a line whose points are all equidistant from a
+straight line is itself straight. John Wallis in 1663 showed that the
+postulate follows from the possibility of similar triangles on different
+scales. Girolamo Saccheri (1733) showed that it is sufficient to have a
+single triangle, the sum of whose angles is two right angles. Other
+equivalent forms may be obtained, but none shows any essential
+superiority to Euclid's. Indeed plausibility, which is chiefly aimed at,
+becomes a positive demerit where it conceals a real assumption.
+
+
+  Saccheri.
+
+A new method, which, though it failed to lead to the desired goal,
+proved in the end immensely fruitful, was invented by Saccheri, in a
+work entitled _Euclides ab omni naevo vindicatus_ (Milan, 1733). If the
+postulate of parallels is involved in Euclid's other assumptions,
+contradictions must emerge when it is denied while the others are
+maintained. This led Saccheri to attempt a _reductio ad absurdum_, in
+which he mistakenly believed himself to have succeeded. What is
+interesting, however, is not his fallacious conclusion, but the
+non-Euclidean results which he obtains in the process. Saccheri
+distinguishes three hypotheses (corresponding to what are now known as
+Euclidean or parabolic, elliptic and hyperbolic geometry), and proves
+that some one of the three must be universally true. His three
+hypotheses are thus obtained: equal perpendiculars AC, BD are drawn from
+a straight line AB, and CD are joined. It is shown that the angles ACD,
+BDC are equal. The first hypothesis is that these are both right angles;
+the second, that they are both obtuse; and the third, that they are both
+acute. Many of the results afterwards obtained by Lobatchewsky and
+Bolyai are here developed. Saccheri fails to be the founder of
+non-Euclidean geometry only because he does not perceive the possible
+truth of his non-Euclidean hypotheses.
+
+
+  Lambert.
+
+Some advance is made by Johann Heinrich Lambert in his _Theorie der
+Parallellinien_ (written 1766; posthumously published 1786). Though he
+still believed in the necessary truth of Euclidean geometry, he
+confessed that, in all his attempted proofs, something remained
+undemonstrated. He deals with the same three hypotheses as Saccheri,
+showing that the second holds on a sphere, while the third would hold on
+a sphere of purely imaginary radius. The second hypothesis he succeeds
+in condemning, since, like all who preceded Bernhard Riemann, he is
+unable to conceive of the straight line as finite and closed. But the
+third hypothesis, which is the same as Lobatchewsky's, is not even
+professedly refuted.[6]
+
+
+  Three periods of non-Euclidean geometry.
+
+Non-Euclidean geometry proper begins with Karl Friedrich Gauss. The
+advance which he made was rather philosophical than mathematical: it was
+he (probably) who first recognized that the postulate of parallels is
+possibly false, and should be empirically tested by measuring the angles
+of large triangles. The history of non-Euclidean geometry has been aptly
+divided by Felix Klein into three very distinct periods. The
+first--which contains only Gauss, Lobatchewsky and Bolyai--is
+characterized by its synthetic method and by its close relation to
+Euclid. The attempt at indirect proof of the disputed postulate would
+seem to have been the source of these three men's discoveries; but when
+the postulate had been denied, they found that the results, so far from
+showing contradictions, were just as self-consistent as Euclid. They
+inferred that the postulate, if true at all, can only be proved by
+observations and measurements. Only one kind of non-Euclidean space is
+known to them, namely, that which is now called hyperbolic. The second
+period is analytical, and is characterized by a close relation to the
+theory of surfaces. It begins with Riemann's inaugural dissertation,
+which regards space as a particular case of a _manifold_; but the
+characteristic standpoint of the period is chiefly emphasized by Eugenio
+Beltrami. The conception of measure of curvature is extended by Riemann
+from surfaces to spaces, and a new kind of space, finite but unbounded
+(corresponding to the second hypothesis of Saccheri and Lambert), is
+shown to be possible. As opposed to the second period, which is purely
+metrical, the third period is essentially projective in its method. It
+begins with Arthur Cayley, who showed that metrical properties are
+projective properties relative to a certain fundamental quadric, and
+that different geometries arise according as this quadric is real,
+imaginary or degenerate. Klein, to whom the development of Cayley's work
+is due, showed further that there are two forms of Riemann's space,
+called by him the elliptic and the spherical. Finally, it has been shown
+by Sophus Lie, that if figures are to be freely movable throughout all
+space in [oo]^6 ways, no other three-dimensional spaces than the above
+four are possible.
+
+
+  Gauss.
+
+Gauss published nothing on the theory of parallels, and it was not
+generally known until after his death that he had interested himself in
+that theory from a very early date. In 1799 he announces that Euclidean
+geometry would follow from the assumption that a triangle can be drawn
+greater than any given triangle. Though unwilling to assume this, we
+find him in 1804 still hoping to prove the postulate of parallels. In
+1830 he announces his conviction that geometry is not an a priori
+science; in the following year he explains that non-Euclidean geometry
+is free from contradictions, and that, in this system, the angles of a
+triangle diminish without limit when all the sides are increased. He
+also gives for the circumference of a circle of radius r the formula
+[pi]k(e^(r/k) - e^(r-/k)), where k is a constant depending upon the
+nature of the space. In 1832, in reply to the receipt of Bolyai's
+_Appendix_, he gives an elegant proof that the amount by which the sum
+of the angles of a triangle falls short of two right angles is
+proportional to the area of the triangle. From these and a few other
+remarks it appears that Gauss possessed the foundations of hyperbolic
+geometry, which he was probably the first to regard as perhaps true. It
+is not known with certainty whether he influenced Lobatchewsky and
+Bolyai, but the evidence we possess is against such a view.[7]
+
+
+  Lobatchewsky.
+
+The first to publish a non-Euclidean geometry was Nicholas Lobatchewsky,
+professor of mathematics in the new university of Kazan.[8] In the place
+of the disputed postulate he puts the following: "All straight lines
+which, in a plane, radiate from a given point, can, with respect to any
+other straight line in the same plane, be divided into two classes, the
+_intersecting_ and the _non-intersecting_. The _boundary line_ of the
+one and the other class is called _parallel to the given line_." It
+follows that there are two parallels to the given line through any
+point, each meeting the line at infinity, like a Euclidean parallel.
+(Hence a line has two distinct points at infinity, and not one only as
+in ordinary geometry.) The two parallels to a line through a point make
+equal acute angles with the perpendicular to the line through the point.
+If p be the length of the perpendicular, either of these angles is
+denoted by [Pi](p). The determination of [Pi](p) is the chief problem
+(cf. equation (6) above); it appears finally that, with a suitable
+choice of the unit of length,
+
+  tan 1/2 [Pi](p) = e^(-p).
+
+Before obtaining this result it is shown that spherical trigonometry is
+unchanged, and that the normals to a circle or a sphere still pass
+through its centre. When the radius of the circle or sphere becomes
+infinite all these normals become parallel, but the circle or sphere
+does not become a straight line or plane. It becomes what Lobatchewsky
+calls a limit-line or limit-surface. The geometry on such a surface is
+shown to be Euclidean, limit-lines replacing Euclidean straight lines.
+(It is, in fact, a surface of zero measure of curvature.) By the help of
+these propositions Lobatchewsky obtains the above value of [Pi](p), and
+thence the solution of triangles. He points out that his formulae result
+from those of spherical trigonometry by substituting ia, ib, ic, for the
+sides a, b, c.
+
+
+  Bolyai.
+
+John Bolyai, a Hungarian, obtained results closely corresponding to
+those of Lobatchewsky. These he published in an appendix to a work by
+his father, entitled _Appendix Scientiam spatii absolute veram exhibens:
+a veritate aut falsitate Axiomatis XI. Euclidei (a priori haud unquam
+decidenda) independentem: adjecta ad casum falsitatis, quadratura
+circuli geometrica_.[9] This work was published in 1831, but its
+conception dates from 1823. It reveals a profounder appreciation of the
+importance of the new ideas, but otherwise differs little from
+Lobatchewsky's. Both men point out that Euclidean geometry as a limiting
+case of their own more general system, that the geometry of very small
+spaces is always approximately Euclidean, that no a priori grounds exist
+for a decision, and that observation can only give an approximate
+answer. Bolyai gives also, as his title indicates, a geometrical
+construction, in hyperbolic space, for the quadrature of the circle, and
+shows that the area of the greatest possible triangle, which has all its
+sides parallel and all its angles zero, is [pi][iota]^2, where i is what
+we should now call the space-constant.
+
+
+  Riemann.
+
+The works of Lobatchewsky and Bolyai, though known and valued by Gauss,
+remained obscure and ineffective until, in 1866, they were translated
+into French by J. Houel. But at this time Riemann's dissertation, _Uber
+die Hypothesen, welche der Geometrie zu Grunde liegen_,[10] was already
+about to be published. In this work Riemann, without any knowledge of
+his predecessors in the same field, inaugurated a far more profound
+discussion, based on a far more general standpoint; and by its
+publication in 1867 the attention of mathematicians and philosophers was
+at last secured. (The dissertation dates from 1854, but owing to changes
+which Riemann wished to make in it, it remained unpublished until after
+his death.)
+
+
+  Definition of a manifold.
+
+Riemann's work contains two fundamental conceptions, that of a manifold
+and that of the _measure of curvature_ of a continuous manifold
+possessed of what he calls flatness in the smallest parts. By means of
+these conceptions space is made to appear at the end of a gradual series
+of more and more specialized conceptions. Conceptions of magnitude, he
+explains, are only possible where we have a general conception capable
+of determination in various ways. The manifold consists of all these
+various determinations, each of which is an element of the manifold. The
+passage from one element to another may be discrete or continuous; the
+manifold is called discrete or continuous accordingly. Where it is
+discrete two portions of it can be compared, as to magnitude, by
+counting; where continuous, by measurement. But measurement demands
+superposition, and consequently some magnitude independent of its place
+in the manifold. In passing, in a continuous manifold, from one element
+to another in a determinate way, we pass through a series of
+intermediate terms, which form a one-dimensional manifold. If this whole
+manifold be similarly caused to pass over into another, each of its
+elements passes through a one-dimensional manifold, and thus on the
+whole a two-dimensional manifold is generated. In this way we can
+proceed to n dimensions. Conversely, a manifold of n dimensions can be
+analysed into one of one dimension and one of (n - 1) dimensions. By
+repetitions of this process the position of an element may be at last
+determined by n magnitudes. We may here stop to observe that the above
+conception of a manifold is akin to that due to Hermann Grassmann in the
+first edition (1847) of his _Ausdehnungslehre_.[11]
+
+
+  Measure of curvature.
+
+Both concepts have been elaborated and superseded by the modern
+procedure in respect to the axioms of geometry, and by the conception of
+abstract geometry involved therein. Riemann proceeds to specialize the
+manifold by considerations as to measurement. If measurement is to be
+possible, some magnitude, we saw, must be independent of position; let
+us consider manifolds in which lengths of lines are such magnitudes, so
+that every line is measurable by every other. The coordinates of a point
+being x1, x2, ... x_n, let us confine ourselves to lines along which the
+ratios dx1 : dx2 : ... : dx_n alter continuously. Let us also assume
+that the element of length, ds, is unchanged (to the first order) when
+all its points undergo the same infinitesimal motion. Then if all the
+increments dx be altered in the same ratio, ds is also altered in this
+ratio. Hence ds is a homogeneous function of the first degree of the
+increments dx. Moreover, ds must be unchanged when all the dx change
+sign. The simplest possible case is, therefore, that in which ds is the
+square root of a quadratic function of the dx. This case includes space,
+and is alone considered in what follows. It is called the case of
+flatness in the smallest parts. Its further discussion depends upon the
+measure of curvature, the second of Riemann's fundamental conceptions.
+This conception, derived from the theory of surfaces, is applied as
+follows. Any one of the shortest lines which issue from a given point
+(say the origin) is completely determined by the initial ratios of the
+dx. Two such lines, defined by dx and [delta]x say, determine a pencil,
+or one-dimensional series, of shortest lines, any one of which is
+defined by [lambda]dx + [mu][delta]x, where the parameter [lambda] :
+[mu] may have any value. This pencil generates a two-dimensional series
+of points, which may be regarded as a surface, and for which we may
+apply Gauss's formula for the measure of curvature at any point. Thus at
+every point of our manifold there is a measure of curvature
+corresponding to every such pencil; but all these can be found when
+n.[/(n-1)]/2 of them are known. If figures are to be freely movable, it
+is necessary and sufficient that the measure of curvature should be the
+same for all points and all directions at each point. Where this is the
+case, if [alpha] be the measure of curvature, the linear element can be
+put into the form
+
+  ds = [root]([Sigma]dx^2)/(1 + 1/4[alpha][Sigma]x^2).
+
+If [alpha] be positive, space is finite, though still unbounded, and
+every straight line is closed--a possibility first recognized by
+Riemann. It is pointed out that, since the possible values of a form a
+continuous series, observations cannot prove that our space is strictly
+Euclidean. It is also regarded as possible that, in the infinitesimal,
+the measure of curvature of our space should be variable.
+
+There are four points in which this profound and epoch-making work is
+open to criticism or development--(1) the idea of a manifold requires
+more precise determination; (2) the introduction of coordinates is
+entirely unexplained and the requisite presuppositions are unanalysed;
+(3) the assumption that ds is the square root of a quadratic function of
+dx1, dx2, ... is arbitrary; (4) the idea of superposition, or
+congruence, is not adequately analysed. The modern solution of these
+difficulties is properly considered in connexion with the general
+subject of the axioms of geometry.
+
+
+  Helmholtz.
+
+The publication of Riemann's dissertation was closely followed by two
+works of Hermann von Helmholtz,[12] again undertaken in ignorance of the
+work of predecessors. In these a proof is attempted that ds must be a
+rational integral quadratic function of the increments of the
+coordinates. This proof has since been shown by Lie to stand in need of
+correction (see VII. _Axioms of Geometry_). Helmholtz's remaining works
+on the subject[13] are of almost exclusively philosophical interest. We
+shall return to them later.
+
+
+  Beltrami.
+
+The only other writer of importance in the second period is Eugenio
+Beltrami, by whom Riemann's work was brought into connexion with that of
+Lobatchewsky and Bolyai. As he gave, by an elegant method, a convenient
+Euclidean interpretation of hyperbolic plane geometry, his results will
+be stated at some length[14]. The _Saggio_ shows that Lobatchewsky's
+plane geometry holds in Euclidean geometry on surfaces of constant
+negative curvature, straight lines being replaced by geodesics. Such
+surfaces are capable of a conformal representation on a plane, by which
+geodesics are represented by straight lines. Hence if we take, as
+coordinates on the surface, the Cartesian coordinates of corresponding
+points on the plane, the geodesics must have linear equations.
+
+  Hence it follows that
+
+    ds^2 = R^2w^(-4){([alpha]^2 - v^2)du^2 + 2uvdudv + ([alpha]^2 - u^2)dv^2}
+
+  where w^2 = [alpha]^2 - u^2 - v^2, and (-1)/R^2 is the measure of
+  curvature of our surface (note that k = [gamma] as used above). The
+  angle between two geodesics u = const., v = const. is [theta], where
+
+    cos [theta] = uv/[root]{([alpha]^2 - u^2)([alpha]^2 - v^2)}, sin [theta] =
+      aw/[root]{(a^2 - u^2)(a^2 - v^2)}.
+
+  Thus u = 0 is orthogonal to all geodesies v = const., and vice versa.
+  In order that sin [theta] may be real, w^2 must be positive; thus
+  geodesics have no real intersection when the corresponding straight
+  lines intersect outside the circle u^2 + v^2 = [alpha]^2. When they
+  intersect on this circle, [theta] = 0. Thus Lobatchewsky's parallels
+  are represented by straight lines intersecting on the circle. Again,
+  transforming to polar coordinates u = r cos [mu], v = r sin [mu], and
+  calling [rho] the geodesic distance of u, v from the origin, we have,
+  for a geodesic through the origin,
+
+    d[rho] = Radr/(a^2 - r^2), [rho] = 1/2R log(a + r)/(a - r), r = a tan h
+      ([rho]/R).
+
+  Thus points on the surface corresponding to points in the plane on the
+  limiting circle r = a, are all at an infinite distance from the
+  origin. Again, considering r constant, the arc of a geodesic circle
+  subtending an angle [mu] at the origin is
+
+    [sigma] = Rr[mu]/[root](a^2 - r^2) = [mu]R sin h ([rho]/R),
+
+  whence the circumference of a circle of radius [rho] is 2[pi]R sin h
+  ([rho]/R). Again, if [alpha] be the angle between any two geodesics
+
+    V - v = m(U - u), V - v = n(U - u),
+
+  then tan [alpha] = a(n - m)w/{(1 + mn)a^2 - (v - mu) (v - nu)}.
+
+  Thus [alpha] is imaginary when u, v is outside the limiting circle,
+  and is zero when, and only when, u, v is on the limiting circle. All
+  these results agree with those of Lobatchewsky and Bolyai. The maximum
+  triangle, whose angles are all zero, is represented in the auxiliary
+  plane by a triangle inscribed in the limiting circle. The angle of
+  parallelism is also easily obtained. The perpendicular to v = 0 at a
+  distance [delta] from the origin is u = a tan h ([delta]/R), and the
+  parallel to this through the origin is u = v sin h ([delta]/R). Hence
+  [Pi] ([delta]), the angle which this parallel makes with v = 0, is
+  given by
+
+    tan [Pi]([delta]) . sin h ([delta]/R) = 1, or tan 1/2[Pi]([delta]) =
+      e^(-[delta]/R)
+
+  which is Lobatchewsky's formula. We also obtain easily for the area of
+  a triangle the formula R^2([pi] - A - B - C).
+
+  Beltrami's treatment connects two curves which, in the earlier
+  treatment, had no connexion. These are limit-lines and curves of
+  constant distance from a straight line. Both may be regarded as
+  circles, the first having an infinite, the second an imaginary radius.
+  The equation to a circle of radius [rho] and centre u0v0 is
+
+    (a^2 - uu0 - vv0)^2 = cos h^2 ([rho]/R)w0^2w^2 = C^2w^2     (say).
+
+  This equation remains real when [rho] is a pure imaginary, and remains
+  finite when w0 = 0, provided [rho] becomes infinite in such a way that
+  w0 cos h ([rho]/R) remains finite. In the latter case the equation
+  represents a limit-line. In the former case, by giving different
+  values to C, we obtain concentric circles with the imaginary centre
+  u0v0. One of these, obtained by putting C = 0, is the straight line
+  a^2 - uu0 - vv0 = 0. Hence the others are each throughout at a
+  constant distance from this line. (It may be shown that all motions in
+  a hyperbolic plane consist, in a general sense, of rotations; but
+  three types must be distinguished according as the centre is real,
+  imaginary or at infinity. All points describe, accordingly, one of the
+  three types of circles.)
+
+  The above Euclidean interpretation fails for three or more dimensions.
+  In the _Teoria fondamentale_, accordingly, where n dimensions are
+  considered, Beltrami treats hyperbolic space in a purely analytical
+  spirit. The paper shows that Lobatchewsky's space of any number of
+  dimensions has, in Riemann's sense, a constant negative measure of
+  curvature. Beltrami starts with the formula (analogous to that of the
+  _Saggio_)
+
+    ds^2 = R^2x^(-2)(dx^2 + dx1^2 + dx2^2 + ... + dx_n^2)
+
+  where x^2 + x1^2 + x2^2 + ... + x_n^2 = a^2.
+
+  He shows that geodesics are represented by linear equations between
+  x1, x2, ..., x_n, and that the geodesic distance [rho] between two
+  points x and x' is given by
+
+          [rho]                    a^2 - x1x'1 - x2x'2 - ... - x_n x'_n
+     cosh ----- = ---------------------------------------------------------------------------
+            R     {(a^2 - x1^2 - x2^2 - ... - x_n^2)(a^2 - x'1^2 - x'2^2 - ... - x'_n^2)}^1/2
+
+  (a formula practically identical with Cayley's, though obtained by a
+  very different method). In order to show that the measure of curvature
+  is constant, we make the substitutions
+
+    x1 = r[lambda]1, x2 = r[lambda]2 ... x_n = r[lambda]_n, where
+      [Sigma][lambda]^2 = 1.
+
+  Hence
+                  _________
+    ds^2 = (Radr/(a^2 - r^2)])^2 + R^2r^2d[Delta]^2/(a^2 - r^2).
+
+  where
+
+    d[Delta]^2 = [Sigma]d[lambda]^2.
+
+  Also calling [rho] the geodesic distance from the origin, we have
+
+         [rho]           a               [rho]           r
+    cosh ----- = -----------------, sinh ----- = -----------------.
+           R     [root](a^2 - r^2)         R     [root](a^2 - r^2)
+
+  Hence
+
+    ds^2 = d[rho]^2 + (R sin h ([rho]/R))^2d[Delta]^2.
+
+  Putting
+
+    z1 = [rho][lambda]1, z2 = [rho][lambda]2, ... z_n = [rho][lambda]_n,
+
+  we obtain
+                                 _                       _
+                            1   |  /  R        [rho]\^2   |
+    ds^2 = [Sigma]dz^2 + ------ | ( ----- sinh ----- ) - 1| [Sigma](z_i dz_k - z_k dz_i)^2.
+                        [rho]^2 |_ \[rho]        R  /    _|
+
+  Hence when [rho] is small, we have approximately
+
+                          1
+    ds^2 = [Sigma]dz^2 + ----[Sigma](z_i dz_k - z_k dz_i)^2    (1).
+                         3R^2
+
+  Considering a surface element through the origin, we may choose our
+  axes so that, for this element,
+
+    z3 = Z4 = ... = z_n = 0.
+
+  Thus
+
+                            1
+    ds^2 = dz1^2 + dz2^2 + ----(z1dz2 - z2dz1)^2    (2).
+                           3R^2
+
+  Now the area of the triangle whose vertices are (0, 0), (z1, z2),
+  (dz1, dz2) is 1/2(z1, dz2 - z2dz1). Hence the quotient when the terms
+  of the fourth order in (2) are divided by the square of this triangle
+  is 4/3R^2; hence, returning to general axes, the same is the quotient
+  when the terms of the fourth order in (1) are divided by the square of
+  the triangle whose vertices are (0, 0, ... 0), (z1, z2, z3, ... z_n),
+  (dz1, dz2, dz3 ... dz_n). But -3/4 of this quotient is defined by
+  Riemann as the measure of curvature.[15] Hence the measure of
+  curvature is -1/R^2, i.e. is constant and negative. The properties of
+  parallels, triangles, &c., are as in the _Saggio_. It is also shown
+  that the analogues of limit surfaces have zero curvature; and that
+  spheres of radius [rho] have constant positive curvature 1/R^2 sinh^2
+  ([rho]/R), so that spherical geometry may be regarded as contained in
+  the pseudo-spherical (as Beltrami calls Lobatchewsky's system).
+
+
+  Transition to the projective method.
+
+The _Saggio_, as we saw, gives a Euclidean interpretation confined to
+two dimensions. But a consideration of the auxiliary plane suggests a
+different interpretation, which may be extended to any number of
+dimensions. If, instead of referring to the pseudosphere, we merely
+_define_ distance and angle, in the Euclidean plane, as those functions
+of the coordinates which gave us distance and angle on the pseudosphere,
+we find that the geometry of our plane has become Lobatchewsky's. All
+the points of the limiting circle are now at infinity, and points beyond
+it are imaginary. If we give our circle an imaginary radius the geometry
+on the plane becomes elliptic. Replacing the circle by a sphere, we
+obtain an analogous representation for three dimensions. Instead of a
+circle or sphere we may take any conic or quadric. With this definition,
+if the fundamental quadric be [Sigma]_(xx) = 0, and if [Sigma]_(xx)' be
+the polar form of [Sigma]_(xx), the distance [rho] between x and x' is
+given by the projective formula
+
+  cos([rho]/k) = [Sigma]_xx'/{[Sigma]_(xx).[Sigma]_x'x'}^1/2.
+
+That this formula is projective is rendered evident by observing that
+e^(-2i[rho]/k) is the anharmonic ratio of the range consisting of the
+two points and the intersections of the line joining them with the
+fundamental quadric. With this we are brought to the third or projective
+period. The method of this period is due to Cayley; its application to
+previous non-Euclidean geometry is due to Klein. The projective method
+contains a generalization of discoveries already made by Laguerre[16] in
+1853 as regards Euclidean geometry. The arbitrariness of this procedure
+of deriving metrical geometry from the properties of conics is removed
+by Lie's theory of congruence. We then arrive at the stage of thought
+which finds its expression in the modern treatment of the axioms of
+geometry.
+
+
+  The two kinds of elliptic space.
+
+The projective method leads to a discrimination, first made by
+Klein,[17] of two varieties of Riemann's space; Klein calls these
+elliptic and spherical. They are also called the polar and antipodal
+forms of elliptic space. The latter names will here be used. The
+difference is strictly analogous to that between the diameters and the
+points of a sphere. In the polar form two straight lines in a plane
+always intersect in one and only one point; in the antipodal form they
+intersect always in two points, which are antipodes. According to the
+definition of geometry adopted in section VII. (_Axioms of Geometry_),
+the antipodal form is not to be termed "geometry," since any pair of
+coplanar straight lines intersect each other in two points. It may be
+called a "quasi-geometry." Similarly in the antipodal form two diameters
+always determine a plane, but two points on a sphere do not determine a
+great circle when they are antipodes, and two great circles always
+intersect in two points. Again, a plane does not form a boundary among
+lines through a point: we can pass from any one such line to any other
+without passing through the plane. But a great circle does divide the
+surface of a sphere. So, in the polar form, a complete straight line
+does not divide a plane, and a plane does not divide space, and does
+not, like a Euclidean plane, have two sides.[18] But, in the antipodal
+form, a plane is, in these respects, like a Euclidean plane.
+
+It is explained in section VII. in what sense the metrical geometry of
+the material world can be considered to be determinate and not a matter
+of arbitrary choice. The scientific question as to the best available
+evidence concerning the nature of this geometry is one beset with
+difficulties of a peculiar kind. We are obstructed by the fact that all
+existing physical science assumes the Euclidean hypothesis. This
+hypothesis has been involved in all actual measurements of large
+distances, and in all the laws of astronomy and physics. The principle
+of simplicity would therefore lead us, in general, where an observation
+conflicted with one or more of those laws, to ascribe this anomaly, not
+to the falsity of Euclidean geometry, but to the falsity of the laws in
+question. This applies especially to astronomy. On the earth our means
+of measurement are many and direct, and so long as no great accuracy is
+sought they involve few scientific laws. Thus we acquire, from such
+direct measurements, a very high degree of probability that the
+space-constant, if not infinite, is yet large as compared with
+terrestrial distances. But astronomical distances and triangles can only
+be measured by means of the received laws of astronomy and optics, all
+of which have been established by assuming the truth of the Euclidean
+hypothesis. It therefore remains possible (until a detailed proof of the
+contrary is forthcoming) that a large but finite space-constant, with
+different laws of astronomy and optics, would have equally explained the
+phenomena. We cannot, therefore, accept the measurements of stellar
+parallaxes, &c., as conclusive evidence that the space-constant is large
+as compared with stellar distances. For the present, on grounds of
+simplicity, we may rightly adopt this view; but it must remain possible
+that, in view of some hitherto undiscovered discrepancy, a slight
+correction of the sort suggested might prove the simplest alternative.
+But conversely, a finite parallax for very distant stars, or a negative
+parallax for any star, could not be accepted as conclusive evidence that
+our geometry is non-Euclidean, unless it were shown--and this seems
+scarcely possible--that no modification of astronomy or optics could
+account for the phenomenon. Thus although we may admit a probability
+that the space-constant is large in comparison with stellar distances, a
+conclusive proof or disproof seems scarcely possible.
+
+Finally, it is of interest to note that, though it is theoretically
+possible to prove, by scientific methods, that our geometry is
+non-Euclidean, it is wholly impossible to prove by such methods that it
+is accurately Euclidean. For the unavoidable errors of observation must
+always leave a slight margin in our measurements. A triangle might be
+found whose angles were certainly greater, or certainly less, than two
+right angles; but to prove them _exactly_ equal to two right angles must
+always be beyond our powers. If, therefore, any man cherishes a hope of
+proving the exact truth of Euclid, such a hope must be based, not upon
+scientific, but upon philosophical considerations.
+
+  BIBLIOGRAPHY.--The bibliography appended to section VII. should be
+  consulted in this connexion. Also, in addition to the citations
+  already made, the following works may be mentioned.
+
+  For Lobatchewsky's writings, cf. _Urkunden zur Geschichte der
+  nichteuklidischen Geometrie_, i., _Nikolaj Iwanowitsch Lobatschefsky_,
+  by F. Engel and P. Stackel (Leipzig, 1898). For John Bolyai's
+  _Appendix_, cf. _Absolute Geometrie nach Johann Bolyai_, by J.
+  Frischauf (Leipzig, 1872), and also the new edition of his father's
+  large work, _Tentamen_ ..., published by the Mathematical Society of
+  Budapest; the second volume contains the appendix. Cf. also J.
+  Frischauf, _Elemente der absoluten Geometrie_ (Leipzig, 1876); M.L.
+  Gerard, _Sur la geometrie non-Euclidienne_ (thesis for doctorate)
+  (Paris, 1892); de Tilly, _Essai sur les principes fondamentales de la
+  geometrie et de la mecanique_ (Bordeaux, 1879); Sir R.S. Ball, "On the
+  Theory of Content," _Trans. Roy. Irish Acad._ vol. xxix. (1889); F.
+  Lindemann, "Mechanik bei projectiver Maasbestimmung," _Math. Annal._
+  vol. vii.; W.K. Clifford, "Preliminary Sketch of Biquaternions,"
+  _Proc. of Lond. Math. Soc._ (1873), and _Coll. Works_; A. Buchheim,
+  "On the Theory of Screws in Elliptic Space," _Proc. Lond. Math. Soc._
+  vols. xv., xvi., xvii.; H. Cox, "On the Application of Quaternions and
+  Grassmann's Algebra to different Kinds of Uniform Space," _Trans.
+  Camb. Phil. Soc._ (1882); M. Dehn, "Die Legendarischen Satze uber die
+  Winkelsumme im Dreieck," Math. Ann. vol. 53 (1900), and "Uber den
+  Rauminhalt," _Math. Annal._ vol. 55 (1902).
+
+  For expositions of the whole subject, cf. F. Klein, _Nicht-Euklidische
+  Geometrie_ (Gottingen, 1893); R. Bonola, _La Geometria non-Euclidea_
+  (Bologna, 1906); P. Barbarin, _La Geometrie non-Euclidienne_ (Paris,
+  1902); W. Killing, _Die nicht-Euklidischen Raumformen in analytischer
+  Behandlung_ (Leipzig, 1885). The last-named work also deals with
+  geometry of more than three dimensions; in this connexion cf. also G.
+  Veronese, _Fondamenti di geometria a piu dimensioni ed a piu specie_
+  _di unita rettilinee_ ... (Padua, 1891, German translation, Leipzig,
+  1894); G. Fontene, _L'Hyperespace a (n-1) dimensions_ (Paris, 1892);
+  and A.N. Whitehead, _loc. cit._ Cf. also E. Study, "Uber
+  nicht-Euklidische und Liniengeometrie," _Jahr. d. Deutsch. Math. Ver._
+  vol. xv. (1906); W. Burnside, "On the Kinematics of non-Euclidean
+  Space," _Proc. Lond. Math. Soc._ vol. xxvi. (1894). A bibliography on
+  the subject up to 1878 has been published by G.B. Halsted, _Amer.
+  Journ. of Math._ vols. i. and ii.; and one up to 1900 by R. Bonola,
+  _Index operum ad geometriam absolutam spectantium_ ... (1902, and
+  Leipzig, 1903).     (B. A. W. R.; A. N. W.)
+
+
+VII. AXIOMS OF GEOMETRY
+
+  Theories of space.
+
+Until the discovery of the non-Euclidean geometries (Lobatchewsky, 1826
+and 1829; J. Bolyai, 1832; B. Riemann, 1854), geometry was universally
+considered as being exclusively the science of existent space. (See
+section VI. _Non-Euclidean Geometry_.) In respect to the science, as
+thus conceived, two controversies may be noticed. First, there is the
+controversy respecting the absolute and relational theories of space.
+According to the absolute theory, which is the traditional view (held
+explicitly by Newton), space has an existence, in some sense whatever it
+may be, independent of the bodies which it contains. The bodies occupy
+space, and it is not intrinsically unmeaning to say that any definite
+body occupies _this_ part of space, and not _that_ part of space,
+without reference to other bodies occupying space. According to the
+relational theory of space, of which the chief exponent was
+Leibnitz,[19] space is nothing but a certain assemblage of the relations
+between the various particular bodies in space. The idea of space with
+no bodies in it is absurd. Accordingly there can be no meaning in saying
+that a body is _here_ and not _there_, apart from a reference to the
+other bodies in the universe. Thus, on this theory, absolute motion is
+intrinsically unmeaning. It is admitted on all hands that in practice
+only relative motion is directly measurable. Newton, however, maintains
+in the _Principia_ (scholium to the 8th definition) that it is
+indirectly measurable by means of the effects of "centrifugal force" as
+it occurs in the phenomena of rotation. This irrelevance of absolute
+motion (if there be such a thing) to science has led to the general
+adoption of the relational theory by modern men of science. But no
+decisive argument for either view has at present been elaborated.[20]
+Kant's view of space as being a form of perception at first sight
+appears to cut across this controversy. But he, saturated as he was with
+the spirit of the Newtonian physics, must (at least in both editions of
+the _Critique_) be classed with the upholders of the absolute theory.
+The form of perception has a type of existence proper to itself
+independently of the particular bodies which it contains. For example he
+writes:[21] "Space does not represent any quality of objects by
+themselves, or objects in their relation to one another, i.e. space does
+not represent any determination which is inherent in the objects
+themselves, and would remain, even if all subjective conditions of
+intuition were removed."
+
+
+  Axioms.
+
+The second controversy is that between the view that the axioms
+applicable to space are known only from experience, and the view that in
+some sense these axioms are given _a priori_. Both these views, thus
+broadly stated, are capable of various subtle modifications, and a
+discussion of them would merge into a general treatise on epistemology.
+The cruder forms of the _a priori_ view have been made quite untenable
+by the modern mathematical discoveries. Geometers now profess ignorance
+in many respects of the exact axioms which apply to existent space, and
+it seems unlikely that a profound study of the question should thus
+obliterate _a priori_ intuitions.
+
+Another question irrelevant to this article, but with some relevance to
+the above controversy, is that of the derivation of our perception of
+existent space from our various types of sensation. This is a question
+for psychology.[22]
+
+_Definition of Abstract Geometry._--Existent space is the subject matter
+of only one of the applications of the modern science of abstract
+geometry, viewed as a branch of pure mathematics. Geometry has been
+defined[23] as "the study of series of two or more dimensions." It has
+also been defined[24] as "the science of cross classification." These
+definitions are founded upon the actual practice of mathematicians in
+respect to their use of the term "Geometry." Either of them brings out
+the fact that geometry is not a science with a determinate subject
+matter. It is concerned with any subject matter to which the formal
+axioms may apply. Geometry is not peculiar in this respect. All branches
+of pure mathematics deal merely with types of relations. Thus the
+fundamental ideas of geometry (e.g. those of _points_ and of _straight
+lines_) are not ideas of determinate entities, but of any entities for
+which the axioms are true. And a set of formal geometrical axioms cannot
+in themselves be true or false, since they are not determinate
+propositions, in that they do not refer to a determinate subject matter.
+The axioms are propositional functions.[25] When a set of axioms is
+given, we can ask (1) whether they are consistent, (2) whether their
+"existence theorem" is proved, (3) whether they are independent. Axioms
+are consistent when the contradictory of any axiom cannot be deduced
+from the remaining axioms. Their existence theorem is the proof that
+they are true when the fundamental ideas are considered as denoting some
+determinate subject matter, so that the axioms are developed into
+determinate propositions. It follows from the logical law of
+contradiction that the proof of the existence theorem proves also the
+consistency of the axioms. This is the only method of proof of
+consistency. The axioms of a set are independent of each other when no
+axiom can be deduced from the remaining axioms of the set. The
+independence of a given axiom is proved by establishing the consistency
+of the remaining axioms of the set, together with the contradictory of
+the given axiom. The enumeration of the axioms is simply the enumeration
+of the hypotheses[26] (with respect to the undetermined subject matter)
+of which some at least occur in each of the subsequent propositions.
+
+Any science is called a "geometry" if it investigates the theory of the
+classification of a set of entities (the points) into classes (the
+straight lines), such that (1) there is one and only one class which
+contains any given pair of the entities, and (2) every such class
+contains more than two members. In the two geometries, important from
+their relevance to existent space, axioms which secure an order of the
+points on any line also occur. These geometries will be called
+"Projective Geometry" and "Descriptive Geometry." In projective geometry
+any two straight lines in a plane intersect, and the straight lines are
+closed series which return into themselves, like the circumference of a
+circle. In descriptive geometry two straight lines in a plane do not
+necessarily intersect, and a straight line is an open series without
+beginning or end. Ordinary Euclidean geometry is a descriptive geometry;
+it becomes a projective geometry when the so-called "points at infinity"
+are added.
+
+
+_Projective Geometry._
+
+Projective geometry may be developed from two undefined fundamental
+ideas, namely, that of a "point" and that of a "straight line." These
+undetermined ideas take different specific meanings for the various
+specific subject matters to which projective geometry can be applied.
+The number of the axioms is always to some extent arbitrary, being
+dependent upon the verbal forms of statement which are adopted. They
+will be presented[27] here as twelve in number, eight being "axioms of
+classification," and four being "axioms of order."
+
+_Axioms of Classification._--The eight axioms of classification are as
+follows:
+
+1. Points form a class of entities with at least two members.
+
+2. Any straight line is a class of points containing at least three
+members.
+
+3. Any two distinct points lie in one and only one straight line.
+
+4. There is at least one straight line which does not contain all the
+points.
+
+5. If A, B, C are non-collinear points, and A' is on the straight line
+BC, and B' is on the straight line CA, then the straight lines AA' and
+BB' possess a point in common.
+
+  _Definition._--If A, B, C are any three non-collinear points, the
+  _plane_ ABC is the class of points lying on the straight lines joining
+  A with the various points on the straight line BC.
+
+6. There is at least one plane which does not contain all the points.
+
+7. There exists a plane [alpha], and a point A not incident in [alpha],
+such that any point lies in some straight line which contains both A and
+a point in [alpha].
+
+  _Definition._--Harm. (ABCD) symbolizes the following conjoint
+  statements: (1) that the points A, B, C, D are collinear, and (2) that
+  a quadrilateral can be found with one pair of opposite sides
+  intersecting at A, with the other pair intersecting at C, and with its
+  diagonals passing through B and D respectively. Then B and D are said
+  to be "harmonic conjugates" with respect to A and C.
+
+8. Harm. (ABCD) implies that B and D are distinct points.
+
+In the above axioms 4 secures at least two dimensions, axiom 5 is the
+fundamental axiom of the plane, axiom 6 secures at least three
+dimensions, and axiom 7 secures at most three dimensions. From axioms
+1-5 it can be proved that any two distinct points in a straight line
+determine that line, that any three non-collinear points in a plane
+determine that plane, that the straight line containing any two points
+in a plane lies wholly in that plane, and that any two straight lines in
+a plane intersect. From axioms 1-6 Desargue's well-known theorem on
+triangles in perspective can be proved.
+
+  The enunciation of this theorem is as follows: If ABC and A'B'C' are
+  two coplanar triangles such that the lines AA', BB', CC' are
+  concurrent, then the three points of intersection of BC and B'C' of CA
+  and C'A', and of AB and A'B' are collinear; and conversely if the
+  three points of intersection are collinear, the three lines are
+  concurrent. The proof which can be applied is the usual projective
+  proof by which a third triangle A"B"C" is constructed not coplanar
+  with the other two, but in perspective with each of them.
+
+  It has been proved[28] that Desargues's theorem cannot be deduced from
+  axioms 1-5, that is, if the geometry be confined to two dimensions.
+  All the proofs proceed by the method of producing a specification of
+  "points" and "straight lines" which satisfies axioms 1-5, and such
+  that Desargues's theorem does not hold.
+
+  It follows from axioms 1-5 that Harm. (ABCD) implies Harm. (ADCB) and
+  Harm. (CBAD), and that, if A, B, C be any three distinct collinear
+  points, there exists at least one point D such that Harm. (ABCD). But
+  it requires Desargues's theorem, and hence axiom 6, to prove that
+  Harm. (ABCD) and Harm. (ABCD') imply the identity of D and D'.
+
+The necessity for axiom 8 has been proved by G. Fano,[29] who has
+produced a three dimensional geometry of fifteen points, i.e. a method
+of cross classification of fifteen entities, in which each straight line
+contains three points, and each plane contains seven straight lines. In
+this geometry axiom 8 does not hold. Also from axioms 1-6 and 8 it
+follows that Harm. (ABCD) implies Harm. (BCDA).
+
+  _Definitions._--When two plane figures can be derived from one another
+  by a single projection, they are said to be in _perspective_. When two
+  plane figures can be derived one from the other by a finite series of
+  perspective relations between intermediate figures, they are said to
+  be _projectively_ related. Any property of a plane figure which
+  necessarily also belongs to any projectively related figure, is called
+  a _projective_ property.
+
+  The following theorem, known from its importance as "the fundamental
+  theorem of projective geometry," cannot be proved[30] from axioms 1-8.
+  The enunciation is: "A projective correspondence between the points on
+  two straight lines is completely determined when the correspondents of
+  three distinct points on one line are determined on the other." This
+  theorem is equivalent[31] (assuming axioms 1-8) to another theorem,
+  known as Pappus's Theorem, namely: "If l and l' are two distinct
+  coplanar lines, and A, B, C are three distinct points on l, and A',
+  B', C' are three distinct points on l', then the three points of
+  intersection of AA' and B'C, of A'B and CC', of BB' and C'A, are
+  collinear." This theorem is obviously Pascal's well-known theorem
+  respecting a hexagon inscribed in a conic, for the special case when
+  the conic has degenerated into the two lines l and l'. Another theorem
+  also equivalent (assuming axioms 1-8) to the fundamental theorem is
+  the following:[32] If the three collinear pairs of points, A and A', B
+  and B', C and C', are such that the three pairs of opposite sides of a
+  complete quadrangle pass respectively through them, i.e. one pair
+  through A and A' respectively, and so on, and if also the three sides
+  of the quadrangle which pass through A, B, and C, are concurrent in
+  one of the corners of the quadrangle, then another quadrangle can be
+  found with the same relation to the three pairs of points, except that
+  its three sides which pass through A, B, and C, are not concurrent.
+
+  Thus, if we choose to take any one of these three theorems as an
+  axiom, all the theorems of projective geometry which do not require
+  ordinal or metrical ideas for their enunciation can be proved. Also a
+  conic can be defined as the locus of the points found by the usual
+  construction, based upon Pascal's theorem, for points on the conic
+  through five given points. But it is unnecessary to assume here any
+  one of the suggested axioms; for the fundamental theorem can be
+  deduced from the axioms of order together with axioms 1-8.
+
+_Axioms of Order._--It is possible to define (cf. Pieri, _loc. cit._)
+the property upon which the order of points on a straight line depends.
+But to secure that this property does in fact range the points in a
+serial order, some axioms are required. A straight line is to be a
+closed series; thus, when the points are in order, it requires two
+points on the line to divide it into two distinct complementary
+segments, which do not overlap, and together form the whole line.
+Accordingly the problem of the definition of order reduces itself to the
+definition of these two segments formed by any two points on the line;
+and the axioms are stated relatively to these segments.
+
+  _Definition._--If A, B, C are three collinear points, the points on
+  the _segment_ ABC are defined to be those points such as X, for which
+  there exist two points Y and Y' with the property that Harm. (AYCY')
+  and Harm. (BYXY') both hold. The _supplementary segment_ ABC is
+  defined to be the rest of the points on the line. This definition is
+  elucidated by noticing that with our ordinary geometrical ideas, if B
+  and X are any two points between A and C, then the two pairs of
+  points, A and C, B and X, define an involution with real double
+  points, namely, the Y and Y' of the above definition. The property of
+  belonging to a segment ABC is projective, since the harmonic relation
+  is projective.
+
+The first three axioms of order (cf. Pieri, _loc. cit._) are:
+
+9. If A, B, C are three distinct collinear points, the supplementary
+segment ABC is contained within the segment BCA.
+
+10. If A, B, C are three distinct collinear points, the common part of
+the segments BCA and CAB is contained in the supplementary segment ABC.
+
+11. If A, B, C are three distinct collinear points, and D lies In the
+segment ABC, then the segment ADC is contained within the segment ABC.
+
+From these axioms all the usual properties of a closed order follow. It
+will be noticed that, if A, B, C are any three collinear points, C is
+necessarily traversed in passing from A to B by one route along the
+line, and is not traversed in passing from A to B along the other route.
+Thus there is no meaning, as referred to closed straight lines, in the
+simple statement that C lies between A and B. But there may be a
+relation of separation between two pairs of collinear points, such as A
+and C, and B and D. The couple B and D is said to separate A and C, if
+the four points are collinear and D lies in the segment complementary to
+the segment ABC. The property of the separation of pairs of points by
+pairs of points is projective. Also it can be proved that Harm. (ABCD)
+implies that B and D separate A and C.
+
+  _Definitions._--A series of entities arranged in a serial order, open
+  or closed, is said to be _compact_, if the series contains no
+  immediately consecutive entities, so that in traversing the series
+  from any one entity to any other entity it is necessary to pass
+  through entities distinct from either. It was the merit of R. Dedekind
+  and of G. Cantor explicitly to formulate another fundamental property
+  of series. The Dedekind property[33] as applied to an open series can
+  be defined thus: An open series possesses the Dedekind property, if,
+  however, it be divided into two mutually exclusive classes u and v,
+  which (1) contain between them the whole series, and (2) are such that
+  every member of u precedes in the serial order every member of v,
+  there is always a member of the series, belonging to one of the two, u
+  or v, which precedes every member of v (other than itself if it belong
+  to v), and also succeeds every member of u (other than itself if it
+  belong to u). Accordingly in an open series with the Dedekind property
+  there is always a member of the series marking the junction of two
+  classes such as u and v. An open series is _continuous_ if it is
+  compact and possesses the Dedekind property. A closed series can
+  always be transformed into an open series by taking any arbitrary
+  member as the first term and by taking one of the two ways round as
+  the ascending order of the series. Thus the definitions of compactness
+  and of the Dedekind property can be at once transferred to a closed
+  series.
+
+12. The last axiom of order is that there exists at least one straight
+line for which the point order possesses the Dedekind property.
+
+It follows from axioms 1-12 by projection that the Dedekind property is
+true for all lines. Again the _harmonic system_ ABC, where A, B, C are
+collinear points, is defined[34] thus: take the harmonic conjugates A',
+B', C' of each point with respect to the other two, again take the
+harmonic conjugates of each of the six points A, B, C, A', B', C' with
+respect to each pair of the remaining five, and proceed in this way by
+an unending series of steps. The set of points thus obtained is called
+the harmonic system ABC. It can be proved that a harmonic system is
+compact, and that every segment of the line containing it possesses
+members of it. Furthermore, it is easy to prove that the fundamental
+theorem holds for harmonic systems, in the sense that, if A, B, C are
+three points on a line l, and A', B', C' are three points on a line l',
+and if by any two distinct series of projections A, B, C are projected
+into A', B', C', then any point of the harmonic system ABC corresponds
+to the same point of the harmonic system A'B'C' according to both the
+projective relations which are thus established between l and l'. It now
+follows immediately that the fundamental theorem must hold for all the
+points on the lines l and l', since (as has been pointed out) harmonic
+systems are "everywhere dense" on their containing lines. Thus the
+fundamental theorem follows from the axioms of order.
+
+A system of numerical coordinates can now be introduced, possessing the
+property that linear equations represent planes and straight lines. The
+outline of the argument by which this remarkable problem (in that
+"distance" is as yet undefined) is solved, will now be given. It is
+first proved that the points on any line can in a certain way be
+definitely associated with all the positive and negative real numbers,
+so as to form with them a one-one correspondence. The arbitrary elements
+in the establishment of this relation are the points on the line
+associated with 0, 1 and [oo].
+
+This association[35] is most easily effected by considering a class of
+projective relations of the line with itself, called by F. Schur (_loc.
+cit._) _prospectivities_.
+
+  Let l (fig. 69) be the given line, m and n any two lines intersecting
+  at U on l, S and S' two points on n. Then a projective relation
+  between l and itself is formed by projecting l from S on to m, and
+  then by projecting m from S' back on to l. All such projective
+  relations, however m, n, S and S' be varied, are called
+  "prospectivities," and U is the double point of the prospectivity. If
+  a point O on l is related to A by a prospectivity, then all
+  prospectivities, which (1) have the same double point U, and (2)
+  relate O to A, give the same correspondent (Q, in figure) to any point
+  P on the line l; in fact they are all the same prospectivity, however
+  m, n, S, and S' may have been varied subject to these conditions. Such
+  a prospectivity will be denoted by (OAU^2).
+
+  [Illustration: FIG. 69.]
+
+  The sum of two prospectivities, written (OAU^2) + (OBU^2), is defined
+  to be that transformation of the line l into itself which is obtained
+  by first applying the prospectivity (OAU^2) and then applying the
+  prospectivity (OBU^2). Such a transformation, when the two summands
+  have the same double point, is itself a prospectivity with that double
+  point.
+
+  [Illustration: FIG. 70]
+
+  With this definition of addition it can be proved that prospectivities
+  with the same double point satisfy all the axioms of magnitude.
+  Accordingly they can be associated in a one-one correspondence with
+  the positive and negative real numbers. Let E (fig. 70) be any point
+  on l, distinct from O and U. Then the prospectivity (OEU^2) is
+  associated with unity, the prospectivity (OOU^2) is associated with
+  zero, and (OUU^2) with [infinity]. The prospectivities of the type
+  (OPU^2), where P is any point on the segment OEU, correspond to the
+  positive numbers; also if P' is the harmonic conjugate of P with
+  respect to O and U, the prospectivity (OP'U^2) is associated with the
+  corresponding negative number. (The subjoined figure explains this
+  relation of the positive and negative prospectivities.) Then any point
+  P on l is associated with the same number as is the prospectivity
+  (OPU^2).
+
+  [Illustration: FIG. 71.]
+
+  It can be proved that the order of the numbers in algebraic order of
+  magnitude agrees with the order on the line of the associated points.
+  Let the numbers, assigned according to the preceding specification, be
+  said to be associated with the points according to the
+  "numeration-system (OEU)." The introduction of a coordinate system for
+  a plane is now managed as follows: Take any triangle OUV in the plane,
+  and on the lines OU and OV establish the numeration systems (OE1U) and
+  (OE2V), where E1 and E2 are arbitrarily chosen. Then (cf. fig. 71) if
+  M and N are associated with the numbers x and y according to these
+  systems, the coordinates of P are x and y. It then follows that the
+  equation of a straight line is of the form ax + by + c = 0. Both
+  coordinates of any point on the line UV are infinite. This can be
+  avoided by introducing homogeneous coordinates X, Y, Z, where x = X/Z,
+  and y = Y/Z, and Z = 0 is the equation of UV.
+
+  [Illustration: FIG. 72.]
+
+  The procedure for three dimensions is similar. Let OUVW (fig. 72) be
+  any tetrahedron, and associate points on OU, OV, OW with numbers
+  according to the numeration systems (OE1U), (OE2V), and (OE3W). Let
+  the planes VWP, WUP, UVP cut OU, OV, OW in L, M, N respectively; and
+  let x, y, z be the numbers associated with L, M, N respectively. Then
+  P is the point (x, y, z). Also homogeneous coordinates can be
+  introduced as before, thus avoiding the infinities on the plane UVW.
+
+  The cross ratio of a range of four collinear points can now be defined
+  as a number characteristic of that range. Let the coordinates of any
+  point P_r of the range P1 P2 P3 P4 be
+
+    [lambda]_r a + [mu]_r + a'  [lambda]_r b + [mu]_r b'
+    -------------------------,  ------------------------,
+       [lambda]_r + [mu]_r         [lambda]_r + [mu]_r
+
+      [lambda]_r c + [mu]_r c'
+      ------------------------, (r = 1, 2, 3, 4)
+        [lambda]_r + [mu]_r
+
+  and let ([lambda]_r [mu]_s) be written for [lambda]_r [mu]_s
+  -[lambda]_s [mu]_r. Then the cross ratio {P1 P2 P3 P4} is defined to
+  be the number ([lambda]1[mu]2) ([lambda]3[mu]4) / ([lambda]1[mu]4)
+  ([lambda]3[mu]2). The equality of the cross ratios of the ranges (P1
+  P2 P3 P4) and (Q1 Q2 Q3 Q4) is proved to be the necessary and
+  sufficient condition for their mutual projectivity. The cross ratios
+  of all harmonic ranges are then easily seen to be all equal to -1, by
+  comparing with the range (OE1UE'1) on the axis of x.
+
+  Thus all the ordinary propositions of geometry in which distance and
+  angular measure do not enter otherwise than in cross ratios can now be
+  enunciated and proved. Accordingly the greater part of the analytical
+  theory of conics and quadrics belongs to geometry at this stage The
+  theory of distance will be considered after the principles of
+  descriptive geometry have been developed.
+
+
+_Descriptive Geometry._
+
+Descriptive geometry is essentially the science of multiple order for
+open series. The first satisfactory system of axioms was given by M.
+Pasch.[36] An improved version is due to G. Peano.[37] Both these
+authors treat the idea of the class of points constituting the segment
+lying _between_ two points as an undefined fundamental idea. Thus in
+fact there are in this system two fundamental ideas, namely, of points
+and of segments. It is then easy enough to define the prolongations of
+the segments, so as to form the complete straight lines. D.
+Hilbert's[38] formulation of the axioms is in this respect practically
+based on the same fundamental ideas. His work is justly famous for some
+of the mathematical investigations contained in it, but his exposition
+of the axioms is distinctly inferior to that of Peano. Descriptive
+geometry can also be considered[39] as the science of a class of
+relations, each relation being a two-termed serial relation, as
+considered in the logic of relations, ranging the points between which
+it holds into a linear open order. Thus the relations are the straight
+lines, and the terms between which they hold are the points. But a
+combination of these two points of view yields[40] the simplest
+statement of all. Descriptive geometry is then conceived as the
+investigation of an undefined fundamental relation between three terms
+(points); and when the relation holds between three points A, B, C, the
+points are said to be "in the [linear] order ABC."
+
+O. Veblen's axioms and definitions, slightly modified, are as follows:--
+
+1. If the points A, B, C are in the order ABC, they are in the order
+CBA.
+
+2. If the points A, B, C are in the order ABC, they are not in the order
+BCA.
+
+3. If the points A, B, C are in the order ABC, A is distinct from C.
+
+4. If A and B are any two distinct points, there exists a point C such
+that A, B, C are in the order ABC.
+
+  _Definition._--The _line_ AB (A =| B) consists of A and B, and of all
+  points X in one of the possible orders, ABX, AXB, XAB. The points X in
+  the order AXB constitute the _segment_ AB.
+
+5. If points C and D (C =| D) lie on the line AB, then A lies on the
+line CD.
+
+6. There exist three distinct points A, B, C not in any of the orders
+ABC, BCA, CAB.
+
+7. If three distinct points A, B, C (fig. 73) do not lie on the same
+line, and D and E are two distinct points in the orders BCD and CEA,
+then a point F exists in the order AFB, and such that D, E, F are
+collinear.
+
+[Illustration: FIG. 73.]
+
+  _Definition._--If A, B, C are three non-collinear points, the _plane_
+  ABC is the class of points which lie on any one of the lines joining
+  any two of the points belonging to the _boundary_ of the triangle ABC,
+  the boundary being formed by the segments BC, CA and AB. The
+  _interior_ of the triangle ABC is formed by the points in segments
+  such as PQ, where P and Q are points respectively on two of the
+  segments BC, CA, AB.
+
+8. There exists a plane ABC, which does not contain all the points.
+
+  _Definition._--If A, B, C, D are four non-coplanar points, the space
+  ABCD is the class of points which lie on any of the lines containing
+  two points on the surface of the tetrahedron ABCD, the _surface_ being
+  formed by the interiors of the triangles ABC, BCD, DCA, DAB.
+
+9. There exists a space ABCD which contains all the points.
+
+10. The Dedekind property holds for the order of the points on any
+straight line.
+
+It follows from axioms 1-9 that the points on any straight line are
+arranged in an open serial order. Also all the ordinary theorems
+respecting a point dividing a straight line into two parts, a straight
+line dividing a plane into two parts, and a plane dividing space into
+two parts, follow.
+
+  Again, in any plane [alpha] consider a line l and a point A (fig. 74).
+
+  [Illustration: FIG. 74.]
+
+  Let any point B divide l into two half-lines l1 and l2. Then it can be
+  proved that the set of half-lines, emanating from A and intersecting
+  l1 (such as m), are bounded by two half-lines, of which ABC is one.
+  Let r be the other. Then it can be proved that r does not intersect
+  l1. Similarly for the half-line, such as n, intersecting l2. Let s be
+  its bounding half-line. Then two cases are possible. (1) The
+  half-lines r and s are collinear, and together form one complete line.
+  In this case, there is one and only one line (viz. r + s) through A
+  and lying in [alpha] which does not intersect l. This is the Euclidean
+  case, and the assumption that this case holds is the _Euclidean
+  parallel axiom_. But (2) the half-lines r and s may not be collinear.
+  In this case there will be an infinite number of lines, such as k for
+  instance, containing A and lying in [alpha], which do not intersect l.
+  Then the lines through A in [alpha] are divided into two classes by
+  reference to l, namely, the _secant_ lines which intersect l, and the
+  _non-secant_ lines which do not intersect l. The two boundary
+  non-secant lines, of which r and s are respectively halves, may be
+  called the two parallels to l through A.
+
+  The perception of the possibility of case 2 constituted the
+  starting-point from which Lobatchewsky constructed the first explicit
+  coherent theory of non-Euclidean geometry, and thus created a
+  revolution in the philosophy of the subject. For many centuries the
+  speculations of mathematicians on the foundations of geometry were
+  almost confined to hopeless attempts to prove the "parallel axiom"
+  without the introduction of some equivalent axiom.[41]
+
+_Associated Projective and Descriptive Spaces._--A region of a
+projective space, such that one, and only one, of the two supplementary
+segments between any pair of points within it lies entirely within it,
+satisfies the above axioms (1-10) of descriptive geometry, where the
+points of the region are the descriptive points, and the portions of
+straight lines within the region are the descriptive lines. If the
+excluded part of the original projective space is a single plane, the
+Euclidean parallel axiom also holds, otherwise it does not hold for the
+descriptive space of the limited region. Again, conversely, starting
+from an original descriptive space an associated projective space can be
+constructed by means of the concept of _ideal points_.[42] These are
+also called _projective points_, where it is understood that the simple
+points are the points of the original descriptive space. An _ideal
+point_ is the class of straight lines which is composed of two coplanar
+lines a and b, together with the lines of intersection of all pairs of
+intersecting planes which respectively contain a and b, together with
+the lines of intersection with the plane ab of all planes containing any
+one of the lines (other than a or b) already specified as belonging to
+the ideal point. It is evident that, if the two original lines a and b
+intersect, the corresponding ideal point is nothing else than the whole
+class of lines which are concurrent at the point ab. But the essence of
+the definition is that an ideal point has an existence when the lines a
+and b do not intersect, so long as they are coplanar. An ideal point is
+termed _proper_, if the lines composing it intersect; otherwise it is
+_improper_.
+
+A theorem essential to the whole theory is the following: if any two of
+the three lines a, b, c are coplanar, but the three lines are not all
+coplanar, and similarly for the lines a, b, d, then c and d are
+coplanar. It follows that any two lines belonging to an ideal point can
+be used as the pair of guiding lines in the definition. An ideal point
+is said to be _coherent_ with a plane, if any of the lines composing it
+lie in the plane. An _ideal line_ is the class of ideal points each of
+which is coherent with two given planes. If the planes intersect, the
+ideal line is termed _proper_, otherwise it is _improper_. It can be
+proved that any two planes, with which any two of the ideal points are
+both coherent, will serve as the guiding planes used in the definition.
+The ideal planes are defined as in projective geometry, and all the
+other definitions (for segments, order, &c.) of projective geometry are
+applied to the ideal elements. If an ideal plane contains some proper
+ideal points, it is called _proper_, otherwise it is _improper_. Every
+ideal plane contains some improper ideal points.
+
+It can now be proved that all the axioms of projective geometry hold of
+the ideal elements as thus obtained; and also that the order of the
+ideal points as obtained by the projective method agrees with the order
+of the proper ideal points as obtained from that of the associated
+points of the descriptive geometry. Thus a projective space has been
+constructed out of the ideal elements, and the proper ideal elements
+correspond element by element with the associated descriptive elements.
+Thus the proper ideal elements form a region in the projective space
+within which the descriptive axioms hold. Accordingly, by substituting
+ideal elements, a descriptive space can always be considered as a region
+within a projective space. This is the justification for the ordinary
+use of the "points at infinity" in the ordinary Euclidean geometry; the
+reasoning has been transferred from the original descriptive space to
+the associated projective space of ideal elements; and with the
+Euclidean parallel axiom the improper ideal elements reduce to the ideal
+points on a single improper ideal plane, namely, the plane at
+infinity.[43]
+
+_Congruence and Measurement._--The property of physical space which is
+expressed by the term "measurability" has now to be considered. This
+property has often been considered as essential to the very idea of
+space. For example, Kant writes,[44] "Space is represented as an
+infinite given _quantity_." This quantitative aspect of space arises
+from the measurability of distances, of angles, of surfaces and of
+volumes. These four types of quantity depend upon the two first among
+them as fundamental. The measurability of space is essentially connected
+with the idea of _congruence_, of which the simplest examples are to be
+found in the proofs of equality by the method of superposition, as used
+in elementary plane geometry. The mere concepts of "part" and of "whole"
+must of necessity be inadequate as the foundation of measurement, since
+we require the comparison as to quantity of regions of space which have
+no portions in common. The idea of congruence, as exemplified by the
+method of superposition in geometrical reasoning, appears to be founded
+upon that of the "rigid body," which moves from one position to another
+with its internal spatial relations unchanged. But unless there is a
+previous concept of the metrical relations between the parts of the
+body, there can be no basis from which to deduce that they are
+unchanged.
+
+It would therefore appear as if the idea of the congruence, or metrical
+equality, of two portions of space (as empirically suggested by the
+motion of rigid bodies) must be considered as a fundamental idea
+incapable of definition in terms of those geometrical concepts which
+have already been enumerated. This was in effect the point of view of
+Pasch.[45] It has, however, been proved by Sophus Lie[46] that
+congruence is capable of definition without recourse to a new
+fundamental idea. This he does by means of his theory of finite
+continuous groups (see GROUPS, THEORY OF), of which the definition is
+possible in terms of our established geometrical ideas, remembering that
+coordinates have already been introduced. The displacement of a rigid
+body is simply a mode of defining to the senses a one-one transformation
+of all space into itself. For at any point of space a particle may be
+conceived to be placed, and to be rigidly connected with the rigid body;
+and thus there is a definite correspondence of any point of space with
+the new point occupied by the associated particle after displacement.
+Again two successive displacements of a rigid body from position A to
+position B, and from position B to position C, are the same in effect as
+one displacement from A to C. But this is the characteristic "group"
+property. Thus the transformations of space into itself defined by
+displacements of rigid bodies form a group.
+
+Call this group of transformations a congruence-group. Now according to
+Lie a congruence-group is defined by the following characteristics:--
+
+1. A congruence-group is a finite continuous group of one-one
+transformations, containing the identical transformation.
+
+2. It is a sub-group of the general projective group, i.e. of the group
+of which any transformation converts planes into planes, and straight
+lines into straight lines.
+
+3. An infinitesimal transformation can always be found satisfying the
+condition that, at least throughout a certain enclosed region, any
+definite line and any definite point on the line are latent, i.e.
+correspond to themselves.
+
+4. No infinitesimal transformation of the group exists, such that, at
+least in the region for which (3) holds, a straight line, a point on it,
+and a plane through it, shall all be latent.
+
+The property enunciated by conditions (3) and (4), taken together, is
+named by Lie "Free mobility in the infinitesimal." Lie proves the
+following theorems for a projective space:--
+
+  1. If the above four conditions are only satisfied by a group
+  throughout part of projective space, this part either ([alpha]) must
+  be the region enclosed by a real closed quadric, or ([beta]) must be
+  the whole of the projective space with the exception of a single
+  plane. In case ([alpha]) the corresponding congruence group is the
+  continuous group for which the enclosing quadric is latent; and in
+  case ([beta]) an imaginary conic (with a real equation) lying in the
+  latent plane is also latent, and the congruence group is the
+  continuous group for which the plane and conic are latent.
+
+  2. If the above four conditions are satisfied by a group throughout
+  the whole of projective space, the congruence group is the continuous
+  group for which some imaginary quadric (with a real equation) is
+  latent.
+
+  By a proper choice of non-homogeneous co-ordinates the equation of any
+  quadrics of the types considered, either in theorem 1 ([alpha]), or in
+  theorem 2, can be written in the form 1 +c(x^2 + y^2 + z^2) = 0, where
+  c is negative for a real closed quadric, and positive for an imaginary
+  quadric. Then the general infinitesimal transformation is defined by
+  the three equations:
+
+    dx/dt = u - [omega]3y + [omega]2z + cx(ux + vy + wz), \
+    dy/dt = v - [omega]1z + [omega]3x + cy(ux + vy + wz),  > (A)
+    dz/dt = w - [omega]2x + [omega]1y + cz(ux + vy + wz). /
+
+  In the ease considered in theorem 1 ([beta]), with the proper choice
+  of co-ordinates the three equations defining the general infinitesimal
+  transformation are:
+
+    dx/dt = u - [omega]3y + [omega]2z, \
+    dy/dt = v - [omega]1z + [omega]3x,  > (B)
+    dz/dt = w - [omega]2x + [omega]1y. /
+
+  In this case the latent plane is the plane for which at least one of
+  x, y, z are infinite, that is, the plane 0.x + 0.y + 0.z + a = 0; and
+  the latent conic is the conic in which the cone x^2 + y^2 + z^2 = 0
+  intersects the latent plane.
+
+It follows from theorems 1 and 2 that there is not one unique
+congruence-group, but an indefinite number of them. There is one
+congruence-group corresponding to each closed real quadric, one to each
+imaginary quadric with a real equation, and one to each imaginary conic
+in a real plane and with a real equation. The quadric thus associated
+with each congruence-group is called the _absolute_ for that group, and
+in the degenerate case of 1 ([beta]) the absolute is the latent plane
+together with the latent imaginary conic. If the absolute is real, the
+congruence-group is _hyperbolic_; if imaginary, it is _elliptic_; if the
+absolute is a plane and imaginary conic, the group is parabolic.
+Metrical geometry is simply the theory of the properties of some
+particular congruence-group selected for study.
+
+  The definition of distance is connected with the corresponding
+  congruence-group by two considerations in respect to a range of five
+  points (A1, A2, P1, P2, P3), of which A1 and A2 are on the absolute.
+
+  Let {A1P1A2P2} stand for the cross ratio (as defined above) of the
+  range (A1P1A2P2), with a similar notation for the other ranges. Then
+
+  (1)   log{A1P1A2P2} + log{A1P2A2P3} = log{A1P1A2P3},
+
+  and
+
+  (2), if the points A1, A2, P1, P2 are transformed into A'1, A'2, P'1,
+  P'2 by any transformation of the congruence-group, ([alpha])
+  {A1P(1}A2P2 = {A'1P'1A'2P'2}, since the transformation is projective,
+  and ([beta]) A'1, A'2 are on the absolute since A1 and A2 are on it.
+  Thus if we define the distance P1P2 to be 1/2k log {A1P1A2P2}, where
+  A1 and A2 are the points in which the line P1P2 cuts the absolute, and
+  k is some constant, the two characteristic properties of distance,
+  namely, (1) the addition of consecutive lengths on a straight line,
+  and (2) the invariability of distances during a transformation of the
+  congruence-group, are satisfied. This is the well-known Cayley-Klein
+  projective definition[47] of distance, which was elaborated in view of
+  the addition property alone, previously to Lie's discovery of the
+  theory of congruence-groups. For a hyperbolic group when P1 and P2 are
+  in the region enclosed by the absolute, log {A1P1A2P2} is real, and
+  therefore k must be real. For an elliptic group A1 and A2 are
+  conjugate imaginaries, and log {A1P1A2P2} is a pure imaginary, and k
+  is chosen to be [kappa]/[iota], where [kappa] is real and [iota] =
+  [root]-.
+
+  Similarly the angle between two planes, p1 and p2, is defined to be
+  (1/2[iota]) log (t1p1t2p2), where t1 and t2 are tangent planes to the
+  absolute through the line p1p2. The planes t1 and t2 are imaginary for
+  an elliptic group, and also for an hyperbolic group when the planes p1
+  and p2 intersect at points within the region enclosed by the absolute.
+  The development of the consequences of these metrical definitions is
+  the subject of non-Euclidean geometry.
+
+  The definitions for the parabolic case can be arrived at as limits of
+  those obtained in either of the other two cases by making k ultimately
+  to vanish. It is also obvious that, if P1 and P2 be the points (x1,
+  y1, z1) and (x2, y2, z2), it follows from equations (B) above that
+  {(x1 - x2)^2 + (y1 - y2)^2 + (z1 - z2)^2}^1/2 is unaltered by a
+  congruence transformation and also satisfies the addition property for
+  collinear distances. Also the previous definition of an angle can be
+  adapted to this case, by making t1 and t2 to be the tangent planes
+  through the line p1p2 to the imaginary conic. Similarly if p1 and p2
+  are intersecting lines, the same definition of an angle holds, where
+  t1 and t2 are now the lines from the point p1p2 to the two points
+  where the plane p1p2 cuts the imaginary conic. These points are in
+  fact the "circular points at infinity" on the plane. The development
+  of the consequences of these definitions for the parabolic case gives
+  the ordinary Euclidean metrical geometry.
+
+Thus the only metrical geometry for the whole of projective space is of
+the elliptic type. But the actual measure-relations (though not their
+general properties) differ according to the elliptic congruence-group
+selected for study. In a descriptive space a congruence-group should
+possess the four characteristics of such a group throughout the whole of
+the space. Then form the associated ideal projective space. The
+associated congruence-group for this ideal space must satisfy the four
+conditions throughout the region of the proper ideal points. Thus the
+boundary of this region is the absolute. Accordingly there can be no
+metrical geometry for the whole of a descriptive space unless its
+boundary (in the associated ideal space) is a closed quadric or a plane.
+If the boundary is a closed quadric, there is one possible
+congruence-group of the hyperbolic type. If the boundary is a plane (the
+plane at infinity), the possible congruence-groups are parabolic; and
+there is a congruence-group corresponding to each imaginary conic in
+this plane, together with a Euclidean metrical geometry corresponding to
+each such group. Owing to these alternative possibilities, it would
+appear to be more accurate to say that systems of quantities can be
+found in a space, rather than that space is a quantity.
+
+Lie has also deduced[48] the same results with respect to
+congruence-groups from another set of defining properties, which
+explicitly assume the existence of a quantitative relation (the
+distance) between any two points, which is invariant for any
+transformation of the congruence-group.[49]
+
+The above results, in respect to congruence and metrical geometry,
+considered in relation to existent space, have led to the doctrine[50]
+that it is intrinsically unmeaning to ask which system of metrical
+geometry is true of the physical world. Any one of these systems can be
+applied, and in an indefinite number of ways. The only question before
+us is one of convenience in respect to simplicity of statement of the
+physical laws. This point of view seems to neglect the consideration
+that science is to be relevant to the definite perceiving minds of men;
+and that (neglecting the ambiguity introduced by the invariable slight
+inexactness of observation which is not relevant to this special
+doctrine) we have, in fact, presented to our senses a definite set of
+transformations forming a congruence-group, resulting in a set of
+measure relations which are in no respect arbitrary. Accordingly our
+scientific laws are to be stated relevantly to that particular
+congruence-group. Thus the investigation of the type (elliptic,
+hyperbolic or parabolic) of this special congruence-group is a perfectly
+definite problem, to be decided by experiment. The consideration of
+experiments adapted to this object requires some development of
+non-Euclidean geometry (see section VI., _Non-Euclidean Geometry_). But
+if the doctrine means that, assuming some sort of objective reality for
+the material universe, beings can be imagined, to whom _either_ all
+congruence-groups are equally important, _or_ some other
+congruence-group is specially important, the doctrine appears to be an
+immediate deduction from the mathematical facts. Assuming a definite
+congruence-group, the investigation of surfaces (or three-dimensional
+loci in space of four dimensions) with geodesic geometries of the form
+of metrical geometries of other types of congruence-groups forms an
+important chapter of non-Euclidean geometry. Arising from this
+investigation there is a widely-spread fallacy, which has found its way
+into many philosophic writings, namely, that the possibility of the
+geometry of existent three-dimensional space being other than Euclidean
+depends on the physical existence of Euclidean space of four or more
+dimensions. The foregoing exposition shows the baselessness of this
+idea.
+
+  BIBLIOGRAPHY.--For an account of the investigations on the axioms of
+  geometry during the Greek period, see M. Cantor, _Vorlesungen uber die
+  Geschichte der Mathematik_, Bd. i. and iii.; T.L. Heath, _The Thirteen
+  Books of Euclid's Elements, a New Translation from the Greek, with
+  Introductory Essays and Commentary, Historical, Critical, and
+  Explanatory_ (Cambridge, 1908)--this work is the standard source of
+  information; W.B. Frankland, _Euclid, Book I., with a Commentary_
+  (Cambridge, 1905)--the commentary contains copious extracts from the
+  ancient commentators. The next period of really substantive importance
+  is that of the 18th century. The leading authors are: G. Saccheri,
+  S.J., _Euclides ab omni naevo vindicatus_ (Milan, 1733). Saccheri was
+  an Italian Jesuit who unconsciously discovered non-Euclidean geometry
+  in the course of his efforts to prove its impossibility. J.H. Lambert,
+  _Theorie der Parallellinien_ (1766); A.M. Legendre, _Elements de
+  geometrie_ (1794). An adequate account of the above authors is given
+  by P. Stackel and F. Engel, _Die Theorie der Parallellinien von Euklid
+  bis auf Gauss_ (Leipzig, 1895). The next period of time (roughly from
+  1800 to 1870) contains two streams of thought, both of which are
+  essential to the modern analysis of the subject. The first stream is
+  that which produced the discovery and investigation of non-Euclidean
+  geometries, the second stream is that which has produced the geometry
+  of position, comprising both projective and descriptive geometry not
+  very accurately discriminated. The leading authors on non-Euclidean
+  geometry are K.F. Gauss, in private letters to Schumacher, cf. Stackel
+  and Engel, _loc. cit._; N. Lobatchewsky, rector of the university of
+  Kazan, to whom the honour of the effective discovery of non-Euclidean
+  geometry must be assigned. His first publication was at Kazan in 1826.
+  His various memoirs have been re-edited by Engel; cf. _Urkunden zur
+  Geschichte der nichteuklidischen Geometrie_ by Stackel and Engel, vol.
+  i. "Lobatchewsky." J. Bolyai discovered non-Euclidean geometry
+  apparently in independence of Lobatchewsky. His memoir was published
+  in 1831 as an appendix to a work by his father W. Bolyai, _Tentamen
+  juventutem...._ This memoir has been separately edited by J.
+  Frischauf, _Absolute Geometrie nach J. Bolyai_ (Leipzig, 1872); B.
+  Riemann, _Uber die Hypothesen, welche der Geometrie zu Grunde liegen_
+  (1854); cf. _Gesamte Werke_, a translation in The Collected Papers of
+  W.K. Clifford. This is a fundamental memoir on the subject and must
+  rank with the work of Lobatchewsky. Riemann discovered elliptic
+  metrical geometry, and Lobatchewsky hyperbolic geometry. A full
+  account of Riemann's ideas, with the subsequent developments due to
+  Clifford, F. Klein and W. Killing, will be found in _The Boston
+  Colloquium for 1903_ (New York, 1905), article "Forms of Non-Euclidean
+  Space," by F.S. Woods. A. Cayley, _loc. cit._ (1859), and F. Klein,
+  "Uber die sogenannte nichteuklidische Geometrie," _Math. Annal._ vols.
+  iv. and vi. (1871 and 1872), between them elaborated the projective
+  theory of distance; H. Helmholtz, "Uber die thatsachlichen Grundlagen
+  der Geometrie" (1866), and "Uber die Thatsachen, die der Geometrie zu
+  Grunde liegen" (1868), both in his _Wissenschaftliche Abhandlungen_,
+  vol. ii., and S. Lie, _loc. cit._ (1890 and 1893), between them
+  elaborated the group theory of congruence.
+
+  The numberless works which have been written to suggest equivalent
+  alternatives to Euclid's parallel axioms may be neglected as being of
+  trivial importance, though many of them are marvels of geometric
+  ingenuity.
+
+  The second stream of thought confined itself within the circle of
+  ideas of Euclidean geometry. Its origin was mainly due to a succession
+  of great French mathematicians, for example, G. Monge, _Geometrie
+  descriptive_ (1800); J.V. Poncelet, _Traite des proprietes projectives
+  des figures_ (1822); M. Chasles, _Apercu historique sur l'origine et
+  le developpement des methodes en geometrie_ (Bruxelles, 1837), and
+  _Traite de geometrie superieure_ (Paris, 1852); and many others. But
+  the works which have been, and are still, of decisive influence on
+  thought as a store-house of ideas relevant to the foundations of
+  geometry are K.G.C. von Staudt's two works, _Geometrie der Lage_
+  (Nurnberg, 1847); and _Beitrage zur Geometrie der Lage_ (Nurnberg,
+  1856, 3rd ed. 1860).
+
+  The final period is characterized by the successful production of
+  exact systems of axioms, and by the final solution of problems which
+  have occupied mathematicians for two thousand years. The successful
+  analysis of the ideas involved in serial continuity is due to R.
+  Dedekind, _Stetigkeit und irrationale Zahlen_ (1872), and to G.
+  Cantor, _Grundlagen einer allgemeinen Mannigfaltigkeitslehre_
+  (Leipzig, 1883), and _Acta math._ vol. 2.
+
+  Complete systems of axioms have been stated by M. Pasch, _loc. cit._;
+  G. Peano, _loc. cit._; M. Pieri, _loc. cit._; B. Russell, _Principles
+  of Mathematics_; O. Veblen, _loc. cit._; and by G. Veronese in his
+  treatise, _Fondamenti di geometria_ (Padua, 1891; German transl. by A.
+  Schepp, _Grundzuge der Geometrie_, Leipzig, 1894). Most of the leading
+  memoirs on special questions involved have been cited in the text; in
+  addition there may be mentioned M. Pieri, "Nuovi principii di
+  geometria projettiva complessa," _Trans. Accad. R. d. Sci._ (Turin,
+  1905); E.H. Moore, "On the Projective Axioms of Geometry," _Trans.
+  Amer. Math. Soc._, 1902; O. Veblen and W.H. Bussey, "Finite Projective
+  Geometries," _Trans. Amer. Math. Soc._, 1905; A.B. Kempe, "On the
+  Relation between the Logical Theory of Classes and the Geometrical
+  Theory of Points," _Proc. Lond. Math. Soc._, 1890; J. Royce, "The
+  Relation of the Principles of Logic to the Foundations of Geometry,"
+  _Trans. of Amer. Math. Soc._, 1905; A. Schoenflies, "Uber die
+  Moglichkeit einer projectiven Geometrie bei transfiniter
+  (nichtarchimedischer) Massbestimmung," _Deutsch. M.-V. Jahresb._,
+  1906.
+
+  For general expositions of the bearings of the above investigations,
+  cf. Hon. Bertrand Russell, _loc. cit._; L. Couturat, _Les Principes
+  des mathematiques_ (Paris, 1905); H. Poincare, _loc. cit._; Russell
+  and Whitehead, _Principia mathematica_ (Cambridge, Univ. Press). The
+  philosophers whose views on space and geometric truth deserve especial
+  study are Descartes, Leibnitz, Hume, Kant and J.S. Mill.     (A. N. W.)
+
+
+FOOTNOTES:
+
+  [1] For Egyptian geometry see EGYPT, S _Science and Mathematics_.
+
+  [2] Cf. A.N. Whitehead, _Universal Algebra_, Bk. vi. (Cambridge,
+    1898).
+
+  [3] Cf. A.N. Whitehead, _loc. cit._
+
+  [4] Cf. A.N. Whitehead, "The Geodesic Geometry of Surfaces in
+    non-Euclidean Space," _Proc. Lond. Math. Soc._ vol. xxix.
+
+  [5] Cf. Klein, "Zur nicht-Euklidischen Geometrie," _Math. Annal._
+    vol. xxxvii.
+
+  [6] On the theory of parallels before Lobatchewsky, see Stackel und
+    Engel, _Theorie der Parallellinien von Euklid bis auf Gauss_
+    (Leipzig, 1895). The foregoing remarks are based upon the materials
+    collected in this work.
+
+  [7] See Stackel und Engel, _op. cit._, and "Gauss, die beiden Bolyai,
+    und die nicht-Euklidische Geometrie," _Math. Annalen_, Bd. xlix.;
+    also Engel's translation of Lobatchewsky (Leipzig, 1898), pp. 378 ff.
+
+  [8] Lobatchewsky's works on the subject are the following:--"On the
+    Foundations of Geometry," _Kazan Messenger_, 1829-1830; "New
+    Foundations of Geometry, with a complete Theory of Parallels,"
+    _Proceedings of the University of Kazan_, 1835 (both in Russian, but
+    translated into German by Engel, Leipzig, 1898); "Geometrie
+    imaginaire," Crelle's Journal, 1837; _Theorie der Parallellinien_
+    (Berlin, 1840; 2nd ed., 1887; translated by Halsted, Austin, Texas,
+    1891). His results appear to have been set forth in a paper (now
+    lost) which he read at Kazan in 1826.
+
+  [9] Translated by Halsted (Austin, Texas, 4th ed., 1896.)
+
+  [10] _Abhandlungen d. Konigl. Ges. d. Wiss. zu Gottingen_, Bd. xiii.;
+    _Ges. math. Werke_, pp. 254-269; translated by Clifford, _Collected
+    Mathematical Papers_.
+
+  [11] Cf. _Gesamm. math. und phys. Werke_, vol. i. (Leipzig, 1894).
+
+  [12] _Wiss. Abh._ vol. ii. pp. 610, 618 (1866, 1868).
+
+  [13] _Mind_, O.S., vols. i. and iii.; _Vortrage und Reden_, vol. ii.
+    pp. 1, 256.
+
+  [14] His papers are "Saggio di interpretazione della geometria
+    non-Euclidea," _Giornale di matematiche_, vol. vi. (1868); "Teoria
+    fondamentale degli spazii di curvatura costante," _Annali di
+    matematica_, vol. ii. (1868-1869). Both were translated into French
+    by J. Houel, _Annales scientifiques de l'Ecole Normale superieure_,
+    vol. vi. (1869).
+
+  [15] Beltrami shows also that this definition agrees with that of
+    Gauss.
+
+  [16] "Sur la theorie des foyers," _Nouv. Ann._ vol. xii.
+
+  [17] _Math. Annalen_, iv. vi., 1871-1872.
+
+  [18] For an investigation of these and similar properties, see
+    Whitehead, _Universal Algebra_ (Cambridge, 1898), bk. vi. ch. ii. The
+    polar form was independently discovered by Simon Newcomb in 1877.
+
+  [19] For an analysis of Leibnitz's ideas on space, cf. B. Russell,
+    _The Philosophy of Leibnitz_, chs. viii.-x.
+
+  [20] Cf. Hon. Bertrand Russell, "Is Position in Time and Space
+    Absolute or Relative?" _Mind_, n.s. vol. 10 (1901), and A.N.
+    Whitehead, "Mathematical Concepts of the Material World," _Phil.
+    Trans._ (1906), p. 205.
+
+  [21] Cf. _Critique of Pure Reason_, 1st section: "Of Space,"
+    conclusion A, Max Muller's translation.
+
+  [22] Cf. Ernst Mach, _Erkenntniss und Irrtum_ (Leipzig); the relevant
+    chapters are translated by T.J. McCormack, _Space and Geometry_
+    (London, 1906); also A. Meinong, _Uber die Stellung der
+    Gegenstandstheorie im System der Wissenschaften_ (Leipzig, 1907).
+
+  [23] Cf. Russell, _Principles of Mathematics_, S 352 (Cambridge,
+    1903).
+
+  [24] Cf. A.N. Whitehead, _The Axioms of Projective Geometry_, S 3
+    (Cambridge, 1906).
+
+  [25] Cf. Russell, _Princ. of Math._, ch. i.
+
+  [26] Cf. Russell, _loc. cit._, and G. Frege, "Uber die Grundlagen der
+    Geometrie," _Jahresber. der Deutsch. Math. Ver._ (1906).
+
+  [27] This formulation--though not in respect to number--is in all
+    essentials that of M. Pieri, cf. "I principii della Geometria di
+    Posizione," _Accad. R. di Torino_ (1898); also cf. Whitehead, _loc.
+    cit._
+
+  [28] Cf. G. Peano, "Sui fondamenti della Geometria," p. 73, _Rivista
+    di matematica_, vol. iv. (1894), and D. Hilbert, _Grundlagen der
+    Geometrie_ (Leipzig, 1899); and R.F. Moulton, "A Simple
+    non-Desarguesian Plane Geometry," _Trans. Amer. Math. Soc._, vol.
+    iii. (1902).
+
+  [29] Cf. "Sui postulati fondamentali della geometria projettiva,"
+    _Giorn. di matematica_, vol. xxx. (1891); also of Pieri, _loc. cit._,
+    and Whitehead, _loc. cit._
+
+  [30] Cf. Hilbert, _loc. cit._; for a fuller exposition of Hilbert's
+    proof cf. K.T. Vahlen, _Abstrakte Geometrie_ (Leipzig, 1905), also
+    Whitehead, _loc. cit._
+
+  [31] Cf. H. Wiener, _Jahresber. der Deutsch. Math. Ver._ vol. i.
+    (1890); and F. Schur, "Uber den Fundamentalsatz der projectiven
+    Geometrie," _Math. Ann._ vol. li. (1899).
+
+  [32] Cf. Hilbert, _loc. cit._, and Whitehead, _loc. cit._
+
+  [33] Cf. Dedekind, _Stetigkeit und irrationale Zahlen_ (1872).
+
+  [34] Cf. v. Staudt, _Geometrie der Lage_ (1847).
+
+  [35] Cf. Pasch, _Vorlesungen uber neuere Geometrie_ (Leipzig, 1882),
+    a classic work; also Fiedler, _Die darstellende Geometrie_ (1st ed.,
+    1871, 3rd ed., 1888); Clebsch, _Vorlesungen uber Geometrie_, vol.
+    iii.; Hilbert, _loc. cit._; F. Schur, _Math. Ann. Bd._ lv. (1902);
+    Vahlen, _loc. cit._; Whitehead, _loc. cit._
+
+  [36] Cf. _loc. cit._
+
+  [37] Cf. _I Principii di geometria_ (Turin, 1889) and "Sui fondamenti
+    della geometria," _Rivista di mat._ vol. iv. (1894).
+
+  [38] Cf. _loc. cit._
+
+  [39] Cf. Vailati, _Rivista di mat._ vol. iv. and Russell, _loc. cit._
+    S 376.
+
+  [40] Cf. O. Veblen, "On the Projective Axioms of Geometry," _Trans.
+    Amer. Math. Soc._ vol. iii. (1902).
+
+  [41] Cf. P. Stackel and F. Engel, _Die Theorie der Parallellinien von
+    Euklid bis auf Gauss_ (Leipzig, 1895).
+
+  [42] Cf. Pasch, _loc. cit._, and R. Bonola, "Sulla introduzione degli
+    enti improprii in geometria projettive," _Giorn. di mat._ vol.
+    xxxviii. (1900); and Whitehead, _Axioms of Descriptive Geometry_
+    (Cambridge, 1907).
+
+  [43] The original idea (confined to this particular case) of ideal
+    points is due to von Staudt (_loc. cit._).
+
+  [44] Cf. _Critique_, "Trans. Aesth." Sect. I.
+
+  [45] Cf. _loc. cit._
+
+  [46] Cf. _Uber die Grundlagen der Geometrie_ (Leipzig, Ber., 1890);
+    and _Theorie der Transformationsgruppen_ (Leipzig, 1893), vol. iii.
+
+  [47] Cf. A. Cayley, "A Sixth Memoir on Quantics," _Trans. Roy. Soc._,
+    1859, and _Coll. Papers_, vol. ii.; and F. Klein, _Math. Ann._ vol.
+    iv., 1871.
+
+  [48] Cf. _loc. cit._
+
+  [49] For similar deductions from a third set of axioms, suggested in
+    essence by Peano, Riv. mat. vol. iv. _loc. cit._ cf. Whitehead, _Desc.
+    Geom. loc. cit._
+
+  [50] Cf. H. Poincare, _La Science et l'hypothese_, ch. iii.
+
+
+
+
+
+
+
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