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+Project Gutenberg (https://www.gutenberg.org) public repository for
+eBook #68662 (https://www.gutenberg.org/ebooks/68662)
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-The Project Gutenberg eBook of Elements of arithmetic, by Augustus De
-Morgan
-
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world 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. If you are not located in the United States, you
-will have to check the laws of the country where you are located before
-using this eBook.
-
-Title: Elements of arithmetic
-
-Author: Augustus De Morgan
-
-Release Date: August 1, 2022 [eBook #68662]
-
-Language: English
-
-Produced by: Richard Tonsing and the Online Distributed Proofreading
- Team at https://www.pgdp.net (This file was produced from
- images generously made available by The Internet Archive)
-
-*** START OF THE PROJECT GUTENBERG EBOOK ELEMENTS OF ARITHMETIC ***
-
-
-
-
-
-Transcriber’s Notes:
-
- Underscores “_” before and after a word or phrase indicate _italics_
- in the original text.
- Equal signs “=” before and after a word or phrase indicate =bold=
- in the original text.
- Carat symbol “^” designates a superscript.
- Small capitals have been converted to SOLID capitals.
- Illustrations have been moved so they do not break up paragraphs.
- Old or antiquated spellings have been preserved.
- Typographical and punctuation errors have been silently corrected.
-
-
-
-
- ELEMENTS OF ARITHMETIC.
-
-
- BY AUGUSTUS DE MORGAN,
-
- OF TRINITY COLLEGE, CAMBRIDGE;
-
- FELLOW OF THE ROYAL ASTRONOMICAL SOCIETY,
- AND OF THE CAMBRIDGE PHILOSOPHICAL SOCIETY;
- PROFESSOR OF MATHEMATICS IN UNIVERSITY COLLEGE, LONDON.
-
- “Hominis studiosi est intelligere, quas utilitates
- proprie afferat arithmetica his, qui solidam et
- perfectam doctrinam in cæteris philosophiæ partibus
- explicant. Quod enim vulgo dicunt, principium esse
- dimidium totius, id vel maxime in philosophiæ partibus
- conspicitur.”--MELANCTHON.
-
- “Ce n’est point par la routine qu’on e’instruit, c’est par
- sa propre réflexion; et il est essentiel de contracter
- l’habitude de se rendre raison de ce qu’on fait: cette
- habitude s’acquiert plus facilement qu’on ne pense; et une
- fois acquise, elle ne se perd plus.”--CONDILLAC.
-
- _SEVENTEENTH THOUSAND._
-
- LONDON:
- WALTON AND MABERLY,
- UPPER GOWER STREET, AND IVY LANE, PATERNOSTER ROW.
-
- M.DCCC.LVIII.
-
- LONDON:
- PRINTED BY J. WERTHEIMER AND CO.,
- CIRCUS-PLACE, FINSBURY-CIRCUS.
-
-
-
-
-PREFACE.
-
-
-The preceding editions of this work were published in 1830, 1832,
-1835, and 1840. This fifth edition differs from the three preceding,
-as to the body of the work, in nothing which need prevent the four,
-or any two of them, from being used together in a class. But it is
-considerably augmented by the addition of eleven new Appendixes,[1]
-relating to matters on which it is most desirable that the advanced
-student should possess information. The first Appendix, on
-_Computation_, and the sixth, on _Decimal Money_, should be read and
-practised by every student with as much attention as any part of the
-work. The mastery of the rules for instantaneous conversion of the
-usual fractions of a pound sterling into decimal fractions, gives the
-possessor the greater part of the advantage which he would derive from
-the introduction of a decimal coinage.
-
-At the time when this work was first published, the importance
-of establishing arithmetic in the young mind upon reason and
-demonstration, was not admitted by many. The case is now altered:
-schools exist in which rational arithmetic is taught, and mere rules
-are made to do no more than their proper duty. There is no necessity
-to advocate a change which is actually in progress, as the works which
-are published every day sufficiently shew. And my principal reason for
-alluding to the subject here, is merely to warn those who want nothing
-but routine, that this is not the book for their purpose.
-
- A. DE MORGAN.
- _London, May 1, 1846._
-
-[1] Some separate copies of these Appendixes are printed, for those who
-may desire to add them to the former editions.
-
-
-
-
-TABLE OF CONTENTS.
-
-
- BOOK I.
- SECTION PAGE
- I. Numeration 1
- II. Addition and Subtraction 14
- III. Multiplication 24
- IV. Division 34
- V. Fractions 51
- VI. Decimal Fractions 65
- VII. Square Root 89
- VIII. Proportion 100
- IX. Permutations and Combinations 118
-
- BOOK II.
- I. Weights and Measures, &c. 124
- II. Rule of Three 144
- III. Interest, &c. 150
-
- APPENDIX.
- I. On the mode of computing 161
- II. On verification by casting out nines and elevens 166
- III. On scales of notation 168
- IV. On the definition of fractions 171
- V. On characteristics 174
- VI. On decimal money 176
- VII. On the main principle of book-keeping 180
- VIII. On the reduction of fractions to others of nearly
- equal value 190
- IX. On some general properties of numbers 193
- X. On combinations 201
- XI. On Horner’s method of solving equations 210
- XII. Rules for the application of arithmetic to geometry 217
-
-
-
-
-ELEMENTS OF ARITHMETIC.
-
-
-
-
-BOOK I.
-
-PRINCIPLES OF ARITHMETIC.
-
-
-SECTION I.
-
-NUMERATION.
-
-1. Imagine a multitude of objects of the same kind assembled together;
-for example, a company of horsemen. One of the first things that must
-strike a spectator, although unused to counting, is, that to each man
-there is a horse. Now, though men and horses are things perfectly
-unlike, yet, because there is one of the first kind to every one of the
-second, one man to every horse, a new notion will be formed in the mind
-of the observer, which we express in words by saying that there is the
-same _number_ of men as of horses. A savage, who had no other way of
-counting, might remember this number by taking a pebble for each man.
-Out of a method as rude as this has sprung our system of calculation,
-by the steps which are pointed out in the following articles. Suppose
-that there are two companies of horsemen, and a person wishes to
-know in which of them is the greater number, and also to be able to
-recollect how many there are in each.
-
-2. Suppose that while the first company passes by, he drops a pebble
-into a basket for each man whom he sees. There is no connexion between
-the pebbles and the horsemen but this, that for every horseman there
-is a pebble; that is, in common language, the _number_ of pebbles and
-of horsemen is the same. Suppose that while the second company passes,
-he drops a pebble for each man into a second basket: he will then have
-two baskets of pebbles, by which he will be able to convey to any
-other person a notion of how many horsemen there were in each company.
-When he wishes to know which company was the larger, or contained most
-horsemen, he will take a pebble out of each basket, and put them aside.
-He will go on doing this as often as he can, that is, until one of the
-baskets is emptied. Then, if he also find the other basket empty, he
-says that both companies contained the same number of horsemen; if the
-second basket still contain some pebbles, he can tell by them how many
-more were in the second than in the first.
-
-3. In this way a savage could keep an account of any numbers in which
-he was interested. He could thus register his children, his cattle,
-or the number of summers and winters which he had seen, by means
-of pebbles, or any other small objects which could be got in large
-numbers. Something of this sort is the practice of savage nations at
-this day, and it has in some places lasted even after the invention
-of better methods of reckoning. At Rome, in the time of the republic,
-the prætor, one of the magistrates, used to go every year in great
-pomp, and drive a nail into the door of the temple of Jupiter; a way of
-remembering the number of years which the city had been built, which
-probably took its rise before the introduction of writing.
-
-4. In process of time, names would be given to those collections of
-pebbles which are met with most frequently. But as long as small
-numbers only were required, the most convenient way of reckoning them
-would be by means of the fingers. Any person could make with his
-two hands the little calculations which would be necessary for his
-purposes, and would name all the different collections of the fingers.
-He would thus get words in his own language answering to one, two,
-three, four, five, six, seven, eight, nine, and ten. As his wants
-increased, he would find it necessary to give names to larger numbers;
-but here he would be stopped by the immense quantity of words which
-he must have, in order to express all the numbers which he would be
-obliged to make use of. He must, then, after giving a separate name
-to a few of the first numbers, manage to express all other numbers by
-means of those names.
-
-5. I now shew how this has been done in our own language. The English
-names of numbers have been formed from the Saxon: and in the following
-table each number after ten is written down in one column, while
-another shews its connexion with those which have preceded it.
-
- One eleven ten and one[2]
- two twelve ten and two
- three thirteen ten and three
- four fourteen ten and four
- five fifteen ten and five
- six sixteen ten and six
- seven seventeen ten and seven
- eight eighteen ten and eight
- nine nineteen ten and nine
- ten twenty two tens
-
- twenty-one two tens and one fifty five tens
- twenty-two two tens and two sixty six tens
- &c. &c. &c. &c. seventy seven tens
- thirty three tens eighty eight tens
- &c. &c. ninety nine tens
- forty four tens a hundred ten tens
- &c. &c.
-
- a hundred and one ten tens and one
- &c. &c.
-
- a thousand ten hundreds
- ten thousand
- a hundred thousand
- a million ten hundred thousand
- or one thousand thousand
- ten millions
- a hundred millions
- &c.
-
-[2] It has been supposed that _eleven_ and _twelve_ are derived
-from the Saxon for _one left_ and _two left_ (meaning, after ten is
-removed); but there seems better reason to think that _leven_ is a word
-meaning ten, and connected with _decem_.
-
-6. Words, written down in ordinary language, would very soon be too
-long for such continual repetition as takes place in calculation. Short
-signs would then be substituted for words; but it would be impossible
-to have a distinct sign for every number: so that when some few signs
-had been chosen, it would be convenient to invent others for the rest
-out of those already made. The signs which we use areas follow:
-
- 0 1 2 3 4 5 6 7 8 9
- nought one two three four five six seven eight nine
-
-I now proceed to explain the way in which these signs are made to
-represent other numbers.
-
-7. Suppose a man first to hold up one finger, then two, and so on,
-until he has held up every finger, and suppose a number of men to do
-the same thing. It is plain that we may thus distinguish one number
-from another, by causing two different sets of persons to hold up each
-a certain number of fingers, and that we may do this in many different
-ways. For example, the number fifteen might be indicated either by
-fifteen men each holding up one finger, or by four men each holding up
-two fingers and a fifth holding up seven, and so on. The question is,
-of all these contrivances for expressing the number, which is the most
-convenient? In the choice which is made for this purpose consists what
-is called the method of _numeration_.
-
-8. I have used the foregoing explanation because it is very probable
-that our system of numeration, and almost every other which is used
-in the world, sprung from the practice of reckoning on the fingers,
-which children usually follow when first they begin to count. The
-method which I have described is the rudest possible; but, by a little
-alteration, a system may be formed which will enable us to express
-enormous numbers with great ease.
-
-9. Suppose that you are going to count some large number, for example,
-to measure a number of yards of cloth. Opposite to yourself suppose a
-man to be placed, who keeps his eye upon you, and holds up a finger for
-every yard which he sees you measure. When ten yards have been measured
-he will have held up ten fingers, and will not be able to count any
-further unless he begin again, holding up one finger at the eleventh
-yard, two at the twelfth, and so on. But to know how many have been
-counted, you must know, not only how many fingers he holds up, but also
-how many times he has begun again. You may keep this in view by placing
-another man on the right of the former, who directs his eye towards his
-companion, and holds up one finger the moment he perceives him ready
-to begin again, that is, as soon as ten yards have been measured. Each
-finger of the first man stands only for one yard, but each finger of
-the second stands for as many as all the fingers of the first together,
-that is, for ten. In this way a hundred may be counted, because the
-first may now reckon his ten fingers once for each finger of the second
-man, that is, ten times in all, and ten tens is one hundred (5).[3]
-Now place a third man at the right of the second, who shall hold up
-a finger whenever he perceives the second ready to begin again. One
-finger of the third man counts as many as all the ten fingers of the
-second, that is, counts one hundred. In this way we may proceed until
-the third has all his fingers extended, which will signify that ten
-hundred or one thousand have been counted (5). A fourth man would
-enable us to count as far as ten thousand, a fifth as far as one
-hundred thousand, a sixth as far as a million, and so on.
-
-[3] The references are to the preceding articles.
-
-10. Each new person placed himself towards your left in the rank
-opposite to you. Now rule columns as in the next page, and to the right
-of them all place in words the number which you wish to represent;
-in the first column on the right, place the number of fingers which
-the first man will be holding up when that number of yards has been
-measured. In the next column, place the fingers which the second man
-will then be holding up; and so on.
-
- |7th.|6th.|5th.|4th.|3rd.|2nd.|1st.|
- I.| | | | | | 5 | 7 | fifty-seven.
- II.| | | | | 1 | 0 | 4 | one hundred and four.
- III.| | | | | 1 | 1 | 0 | one hundred and ten.
- IV.| | | | 2 | 3 | 4 | 8 | two thousand three hundred
- | | | | | | | | and forty-eight.
- V.| | | 1 | 5 | 9 | 0 | 6 | fifteen thousand nine
- | | | | | | | | hundred and six.
- VI.| | 1 | 8 | 7 | 0 | 0 | 4 | one hundred and
- | | | | | | | | eighty-seven thousand
- | | | | | | | | and four.
- VII.| 3 | 6 | 9 | 7 | 2 | 8 | 5 | three million, six hundred
- | | | | | | | | and ninety-seven
- | | | | | | | | thousand, two hundred and
- | | | | | | | | eighty-five.
-
-11. In I. the number fifty-seven is expressed. This means (5) five tens
-and seven. The first has therefore counted all his fingers five times,
-and has counted seven fingers more. This is shewn by five fingers of
-the second man being held up, and seven of the first. In II. the number
-one hundred and four is represented. This number is (5) ten tens and
-four. The second person has therefore just reckoned all his fingers
-once, which is denoted by the third person holding up one finger;
-but he has not yet begun again, because he does not hold up a finger
-until the first has counted ten, of which ten only four are completed.
-When all the last-mentioned ten have been counted, he then holds up
-one finger, and the first being ready to begin again, has no fingers
-extended, and the number obtained is eleven tens, or ten tens and one
-ten, or one hundred and ten. This is the case in III. You will now find
-no difficulty with the other numbers in the table.
-
-12. In all these numbers a figure in the first column stands for only
-as many yards as are written under that figure in (6). A figure in
-the second column stands, not for as many yards, but for as many tens
-of yards; a figure in the third column stands for as many hundreds of
-yards; in the fourth column for as many thousands of yards; and so on:
-that is, if we suppose a figure to move from any column to the one on
-its left, it stands for ten times as many yards as before. Recollect
-this, and you may cease to draw the lines between the columns, because
-each figure will be sufficiently well known by the _place_ in which it
-is; that is, by the number of figures which come upon the right hand of
-it.
-
-13. It is important to recollect that this way of writing numbers,
-which has become so familiar as to seem the _natural_ method, is not
-more natural than any other. For example, we might agree to signify one
-ten by the figure of one with an accent, thus, 1′; twenty or two tens
-by 2′; and so on: one hundred or ten tens by 1″; two hundred by 2″; one
-thousand by 1‴; and so on: putting Roman figures for accents when they
-become too many to write with convenience. The fourth number in the
-table would then be written 2‴ 3′ 4′ 8, which might also be expressed
-by 8 4′ 3″ 2‴, 4′ 8 3″ 2‴; or the order of the figures might be changed
-in any way, because their meaning depends upon the accents which are
-attached to them, and not upon the place in which they stand. Hence,
-a cipher would never be necessary; for 104 would be distinguished
-from 14 by writing for the first 1″ 4, and for the second 1′ 4. The
-common method is preferred, not because it is more exact than this, but
-because it is more simple.
-
-14. The distinction between our method of numeration and that of the
-ancients, is in the meaning of each figure depending partly upon the
-place in which it stands. Thus, in 44444 each four stands for four of
-_something_; but in the first column on the right it signifies only
-four of the pebbles which are counted; in the second, it means four
-collections of ten pebbles each; in the third, four of one hundred
-each; and so on.
-
-15. The things measured in (11) were yards of cloth. In this case one
-yard of cloth is called the _unit_. The first figure on the right is
-said to be in the _units’ place_, because it only stands for so many
-units as are in the number that is written under it in (6). The second
-figure is said to be in the _tens’_ place, because it stands for a
-number of tens of units. The third, fourth, and fifth figures are in
-the places of the _hundreds_, _thousands_, and _tens of thousands_, for
-a similar reason.
-
-16. If the quantity measured had been acres of land, an acre of land
-would have been called the _unit_, for the unit is _one_ of the things
-which are measured. Quantities are of two sorts; those which contain an
-exact number of units, as 47 yards, and those which do not, as 47 yards
-and a half. Of these, for the present, we only consider the first.
-
-17. In most parts of arithmetic, all quantities must have the same
-unit. You cannot say that 2 yards and 3 feet make 5 _yards_ or 5
-_feet_, because 2 and 3 make 5; yet you may say that 2 _yards_ and 3
-_yards_ make 5 _yards_, and that 2 _feet_ and 3 _feet_ make 5 _feet_.
-It would be absurd to try to measure a quantity of one kind with a unit
-which is a quantity of another kind; for example, to attempt to tell
-how many yards there are in a gallon, or how many bushels of corn there
-are in a barrel of wine.
-
-18. All things which are true of some numbers of one unit are true of
-the same numbers of any other unit. Thus, 15 pebbles and 7 pebbles
-together make 22 pebbles; 15 acres and 7 acres together make 22 acres,
-and so on. From this we come to say that 15 and 7 make 22, meaning that
-15 things of the same kind, and 7 more of the same kind as the first,
-together make 22 of that kind, whether the kind mentioned be pebbles,
-horsemen, acres of land, or any other. For these it is but necessary to
-say, once for all, that 15 and 7 make 22. Therefore, in future, on this
-part of the subject I shall cease to talk of any particular units, such
-as pebbles or acres, and speak of numbers only. A number, considered
-without intending to allude to any particular things, is called an
-_abstract_ number: and it then merely signifies repetitions of a unit,
-or the _number of times_ a unit is repeated.
-
-19. I will now repeat the principal things which have been mentioned in
-this chapter.
-
-I. Ten signs are used, one to stand for nothing, the rest for the first
-nine numbers. They are 0, 1, 2, 3, 4, 5, 6, 7, 8, 9. The first of these
-is called a _cipher_.
-
-II. Higher numbers have not signs for themselves, but are signified
-by placing the signs already mentioned by the side of each other, and
-agreeing that the first figure on the right hand shall keep the value
-which it has when it stands alone; that the second on the right hand
-shall mean ten times as many as it does when it stands alone; that the
-third figure shall mean one hundred times as many as it does when it
-stands alone; the fourth, one thousand times as many; and so on.
-
-III. The right hand figure is said to be in the _units’ place_, the
-next to that in the _tens’ place_, the third in the _hundreds’ place_,
-and so on.
-
-IV. When a number is itself an exact number of tens, hundreds, or
-thousands, &c., as many ciphers must be placed on the right of it as
-will bring the number into the place which is intended for it. The
-following are examples:
-
- Fifty, or five tens, 50: seven hundred, 700.
- Five hundred and twenty-eight thousand, 528000.
-
-If it were not for the ciphers, these numbers would be mistaken for 5,
-7, and 528.
-
-V. A cipher in the middle of a number becomes necessary when any one of
-the denominations, units, tens, &c. is wanting. Thus, twenty thousand
-and six is 20006, two hundred and six is 206. Ciphers might be placed
-at the beginning of a number, but they would have no meaning. Thus 026
-is the same as 26, since the cipher merely shews that there are no
-hundreds, which is evident from the number itself.
-
-20. If we take out of a number, as 16785, any of those figures which
-come together, as 67, and ask, what does this sixty-seven mean? of what
-is it sixty-seven? the answer is, sixty-seven of the same collections
-as the 7, when it was in the number; that is, 67 hundreds. For the 6
-is 6 thousands, or 6 ten hundreds, or sixty hundreds; which, with the
-7, or 7 hundreds, is 67 hundreds: similarly, the 678 is 678 tens. This
-number may then be expressed either as
-
- 1 ten thousand 6 thousands 7 hundreds 8 tens and 5;
- or 16 thousands 78 tens and 5; or 1 ten thousand 678 tens and 5;
- or 167 hundreds 8 tens and 5; or 1678 tens and 5, and so on.
-
-21. EXERCISES.
-
-I. Write down the signs for--four hundred and seventy-six; two thousand
-and ninety-seven; sixty-four thousand three hundred and fifty; two
-millions seven hundred and four; five hundred and seventy-eight
-millions of millions.
-
-II. Write at full length 53, 1805, 1830, 66707, 180917324, 66713721,
-90976390, 25000000.
-
-III. What alteration takes place in a number made up entirely of nines,
-such as 99999, by adding one to it?
-
-IV. Shew that a number which has five figures in it must be greater
-than one which has four, though the first have none but small figures
-in it, and the second none but large ones. For example, that 10111 is
-greater than 9879.
-
-22. You now see that the convenience of our method of numeration arises
-from a few simple signs being made to change their value as they
-change the column in which they are placed. The same advantage arises
-from counting in a similar way all the articles which are used in
-every-day life. For example, we count money by dividing it into pounds,
-shillings, and pence, of which a shilling is 12 pence, and a pound 20
-shillings, or 240 pence. We write a number of pounds, shillings, and
-pence in three columns, generally placing points between the columns.
-Thus, 263 pence would not be written as 263, but as £1. 1. 11, where £
-shews that the 1 in the first column is a pound. Here is a _system of
-numeration_ in which a number in the second column on the right means
-12 times as much as the same number in the first; and one in the third
-column is twenty times as great as the same in the second, or 240 times
-as great as the same in the first. In each of the tables of measures
-which you will hereafter meet with, you will see a separate system of
-numeration, but the methods of calculation for all will be the same.
-
-23. In order to make the language of arithmetic shorter, some other
-signs are used. They are as follow:
-
-I. 15 + 38 means that 38 is to be added to 15, and is the same thing
-as 53. This is the _sum_ of 15 and 38, and is read fifteen _plus_
-thirty-eight (_plus_ is the Latin for _more_).
-
-II. 64-12 means that 12 is to be taken away from 64, and is the same
-thing as 52. This is the _difference_ of 64 and 12, and is read
-sixty-four _minus_ twelve (_minus_ is the Latin for _less_).
-
-III. 9 × 8 means that 8 is to be taken 9 times, and is the same thing
-as 72. This is the _product_ of 9 and 8, and is read nine _into_ eight.
-
-IV. 108/6 means that 108 is to be divided by 6, or that you must find
-out how many sixes there are in 108; and is the same thing as 18. This
-is the _quotient_ of 108 and 6; and is read a hundred and eight _by_
-six.
-
-V. When two numbers, or collections of numbers, with the foregoing
-signs, are the same, the sign = is put between them. Thus, that 7
-and 5 make 12, is written in this way, 7 + 5 = 12. This is called an
-_equation_, and is read, seven _plus_ five _equals_ twelve. It is plain
-that we may construct as many equations as we please. Thus:
-
- 12
- 7 + 9 - 3 = 12 + 1; --- - 1 + 3 × 2 = 11,
- 2
-
-and so on.
-
-24. It often becomes necessary to speak of something which is true not
-of any one number only, but of all numbers. For example, take 10 and 7;
-their sum[4] is 17, their difference is 3. If this sum and difference
-be added together, we get 20, which is twice the greater of the two
-numbers first chosen. If from 17 we take 3, we get 14, which is twice
-the less of the two numbers. The same thing will be found to hold good
-of any two numbers, which gives this general proposition,--If the sum
-and difference of two numbers be added together, the result is twice
-the greater of the two; if the difference be taken from the sum, the
-result is twice the lesser of the two. If, then, we take _any_ numbers,
-and call them the first number and the second number, and let the first
-number be the greater; we have
-
-[4] Any little computations which occur in the rest of this section may
-be made on the fingers, or with counters.
-
- (1st No. + 2d No.) + (1st No. - 2d No.) = twice 1st No.
-
- (1st No. + 2d No.) - (1st No. - 2d No.) = twice 2d No.
-
-The brackets here enclose the things which must be first done, before
-the signs which join the brackets are made use of. Thus, 8-(2 + 1) × (1
-+ 1) signifies that 2 + 1 must be taken 1 + 1 times, and the product
-must be subtracted from 8. In the same manner, any result made from
-two or more numbers, which is true whatever numbers are taken, may be
-represented by using first No., second No., &c., to stand for them, and
-by the signs in (23). But this may be much shortened; for as first No.,
-second No., &c., may mean any numbers, the letters _a_ and _b_ may be
-used instead of these words; and it must now be recollected that _a_
-and _b_ stand for two numbers, provided only that _a_ is greater than
-_b_. Let twice _a_ be represented by 2_a_, and twice _b_ by 2_b_. The
-equations then become
-
- (_a_ + _b_) + (_a_ - _b_) = 2_a_,
-
- and (_a_ + _b_) - (_a_ - _b_) = 2_b_.
-
-This may be explained still further, as follows:
-
-25. Suppose a number of sealed packets, marked _a_, _b_, _c_, _d_, &c.,
-on the outside, each of which contains a distinct but unknown number of
-counters. As long as we do not know how many counters each contains, we
-can make the letter which belongs to each stand for its number, so as
-to talk of _the number a_, instead of the number in the packet marked
-_a_. And because we do not know the numbers, it does not therefore
-follow that we know nothing whatever about them; for there are some
-connexions which exist between all numbers, which we call _general
-properties_ of numbers. For example, take any number, multiply it by
-itself, and subtract one from the result; and then subtract one from
-the number itself. The first of these will always contain the second
-exactly as many times as the original number increased by one. Take
-the number 6; this multiplied by itself is 36, which diminished by one
-is 35; again, 6 diminished by 1 is 5; and 35 contains 5, 7 times, that
-is, 6 + 1 times. This will be found to be true of any number, and, when
-proved, may be said to be true of the number contained in the packet
-marked _a_, or of the number _a_. If we represent a multiplied by
-itself by _aa_,[5] we have, by (23)
-
- _aa_ - 1
- ------------- = _a_ + 1.
- _a_ - 1
-
-[5] This should be (23) _a_ × _a_, but the sign × is unnecessary here.
-It is used with numbers, as in 2 × 7, to prevent confounding this,
-which is 14, with 27.
-
-26. When, therefore, we wish to talk of a number without specifying
-any one in particular, we use a letter to represent it. Thus: Suppose
-we wish to reason upon what will follow from dividing a number into
-three parts, without considering what the number is, or what are the
-parts into which it is divided. Let _a_ stand for the number, and _b_,
-_c_, and _d_, for the parts into which it is divided. Then, by our
-supposition,
-
- _a_ = _b_ + _c_ + _d_.
-
-On this we can reason, and produce results which do not belong to any
-particular number, but are true of all. Thus, if one part be taken away
-from the number, the other two will remain, or
-
- _a_ - _b_ = _c_ + _d_.
-
-If each part be doubled, the whole number will be doubled, or
-
- 2_a_ = 2_b_ + 2_c_ + 2_d_.
-
-If we diminish one of the parts, as _d_, by a number _x_, we diminish
-the whole number just as much, or
-
- _a_ - _x_ = _b_ + _c_ + (_d_ - _x_).
-
-
-27. EXERCISES.
-
- What is _a_ + 2_b_ - _c_,
- where _a_ = 12,
- _b_ = 18,
- _c_ = 7?--_Answer_, 41.
-
- _aa_ - _bb_
- What is ----------- ,
- _a_ - _b_
-
- where _a_ = 6 and _b_ = 2?--_Ans._ 8.
-
- What is the difference between (_a_ + _b_)(_c_ + _d_)
- and _a_ + _bc_ + _d_, for the following values of
- _a_, _b_, _c_, and _d_?
-
- _a_ | _b_ | _c_ | _d_ | _Ans._
- 1 | 2 | 3 | 4 | 10
- 2 | 12 | 7 | 1 | 25
- 1 | 1 | 1 | 1 | 1
-
-
-
-
-SECTION II.
-
-ADDITION AND SUBTRACTION.
-
-
-28. There is no process in arithmetic which does not consist entirely
-in the increase or diminution of numbers. There is then nothing which
-might not be done with collections of pebbles. Probably, at first,
-either these or the fingers were used. Our word _calculation_ is
-derived from the Latin word _calculus_, which means a pebble. Shorter
-ways of counting have been invented, by which many calculations, which
-would require long and tedious reckoning if pebbles were used, are made
-at once with very little trouble. The four great methods are, Addition,
-Subtraction, Multiplication, and Division; of which, the last two are
-only ways of doing several of the first and second at once.
-
-29. When one number is increased by others, the number which is as
-large as all the numbers together is called their _sum_. The process
-of finding the sum of two or more numbers is called ADDITION, and, as
-was said before, is denoted by placing a cross (+) between the numbers
-which are to be added together.
-
-Suppose it required to find the sum of 1834 and 2799. In order to add
-these numbers, take them to pieces, dividing each into its units, tens,
-hundreds, and thousands:
-
- 1834 is 1 thous. 8 hund. 3 tens and 4;
- 2799 is 2 thous. 7 hund. 9 tens and 9.
-
-Each number is thus broken up into four parts. If to each part of the
-first you add the part of the second which is under it, and then put
-together what you get from these additions, you will have added 1834
-and 2799. In the first number are 4 units, and in the second 9: these
-will, when the numbers are added together, contribute 13 units to
-the sum. Again, the 3 tens in the first and the 9 tens in the second
-will contribute 12 tens to the sum. The 8 hundreds in the first and
-the 7 hundreds in the second will add 15 hundreds to the sum; and
-the thousand in the first with the 2 thousands in the second will
-contribute 3 thousands to the sum; therefore the sum required is
-
- 3 thousands, 15 hundreds, 12 tens, and 13 units.
-
-To simplify this result, you must recollect that--
-
- 13 units are 1 ten and 3 units.
- 12 tens are 1 hund. and 2 tens.
- 15 hund. are 1 thous. and 5 hund.
- 3 thous. are 3 thous.
-
-Now collect the numbers on the right hand side together, as was done
-before, and this will give, as the sum of 1834 and 2799,
-
- 4 thousands, 6 hundreds, 3 tens, and 3 units,
-
-which (19) is written 4633.
-
-30. The former process, written with the signs of (23) is as follows:
-
- 1834 = 1 × 1000 + 8 × 100 + 3 × 10 + 4
- 2799 = 2 × 1000 + 7 × 100 + 9 × 10 + 9
-
-Therefore,
-
- 1834 + 2799 = 3 × 1000 + 15 × 100 + 12 × 10 + 13
-
- But 13 = 1 × 10 + 3
- 12 × 10 = 1 × 100 + 2 × 10
- 15 × 100 = 1 × 1000 + 5 × 100
- 3 × 1000 = 3 × 1000
- Therefore,
- 1834 + 2799 = 4 × 1000 + 6 × 100 + 3 × 10 + 3
- = 4633.
-
-31. The same process is to be followed in all cases, but not at the
-same length. In order to be able to go through it, you must know how to
-add together the simple numbers. This can only be done by memory; and
-to help the memory you should make the following table three or four
-times for yourself:
-
- +----+----+----+----+----+----+----+----+----+----+
- | | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 |
- +----+----+----+----+----+----+----+----+----+----+
- | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 |
- +----+----+----+----+----+----+----+----+----+----+
- | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 |
- +----+----+----+----+----+----+----+----+----+----+
- | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
- +----+----+----+----+----+----+----+----+----+----+
- | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 |
- +----+----+----+----+----+----+----+----+----+----+
- | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 |
- +----+----+----+----+----+----+----+----+----+----+
- | 6 | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 |
- +----+----+----+----+----+----+----+----+----+----+
- | 7 | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 |
- +----+----+----+----+----+----+----+----+----+----+
- | 8 | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 |
- +----+----+----+----+----+----+----+----+----+----+
- | 9 | 10 | 11 | 12 | 13 | 14 | 15 | 16 | 17 | 18 |
- +----+----+----+----+----+----+----+----+----+----+
-
-The use of this table is as follows: Suppose you want to find the sum
-of 8 and 7. Look in the left-hand column for either of them, 8, for
-example; and look in the top column for 7. On the same line as 8, and
-underneath 7, you find 15, their sum.
-
-32. When this table has been thoroughly committed to memory, so that
-you can tell at once the sum of any two numbers, neither of which
-exceeds 9, you should exercise yourself in adding and subtracting two
-numbers, one of which is greater than 9 and the other less. You should
-write down a great number of such sentences as the following, which
-will exercise you at the same time in addition, and in the use of the
-signs mentioned in (23).
-
- 12 + 6 = 18 22 + 6 = 28 19 + 8 = 27
- 54 + 9 = 63 56 + 7 = 63 22 + 8 = 30
- 100 - 9 = 91 27 - 8 = 19 44 - 6 = 38, &c.
-
-33. When the last two articles have been thoroughly studied, you will
-be able to find the sum of any numbers by the following process,[6]
-which is the same as that in (29).
-
-[6] In this and all other processes, the student is strongly
-recommended to look at and follow the first Appendix.
-
-RULE I. Place the numbers under one another, units under units, tens
-under tens, and so on.
-
-II. Add together the units of all, and part the _whole_ number thus
-obtained into units and tens. Thus, if 85 be the number, part it into
-8 tens and 5 units; if 136 be the number, part it into 13 tens and 6
-units (20).
-
-III. Write down the units of this number under the units of the rest,
-and keep in memory the number of tens.
-
-IV. Add together all the numbers in the column of tens, remembering
-to take in (or carry, as it is called) the tens which you were told
-to recollect in III., and divide this number of tens into tens and
-hundreds. Thus, if 335 tens be the number obtained, part this into 33
-hundreds and 5 tens.
-
-V. Place the number of tens under the tens, and remember the number of
-hundreds.
-
-VI. Proceed in this way through every column, and at the last column,
-instead of separating the number you obtain into two parts, write it
-all down before the rest.
-
-EXAMPLE.--What is
-
- 1805 + 36 + 19727 + 3 + 1474 + 2008
-
- 1805
- 36
- 19727
- 3
- 1474
- 2008
- -----
- 25053
-
-The addition of the units’ line, or 8 + 4 + 3 + 7 + 6 + 5, gives
-33, that is, 3 tens and 3 units. Put 3 in the units’ place, and add
-together the line of tens, taking in at the beginning the 3 tens which
-were created by the addition of the units’ line. That is, find 3 + 0
-+ 7 + 2 + 3 + 0, which gives 15 for the number of tens; that is, 1
-hundred and 5 tens. Add the line of hundreds together, taking care to
-add the 1 hundred which arose in the addition of the line of tens;
-that is, find 1 + 0 + 4 + 7 + 8, which gives exactly 20 hundreds,
-or 2 thousands and no hundreds. Put a cipher in the hundreds’ place
-(because, if you do not, the next figure will be taken for hundreds
-instead of thousands), and add the figures in the thousands’ line
-together, remembering the 2 thousands which arose from the hundreds’
-line; that is, find 2 + 2 + 1 + 9 + 1, which gives 15 thousands, or 1
-ten thousand and 5 thousand. Write 5 under the line of thousands, and
-collect the figures in the line of tens of thousands, remembering the
-ten thousand which arose out of the thousands’ line; that is, find 1 +
-1, or 2 ten thousands. Write 2 under the ten thousands’ line, and the
-operation is completed.
-
-34. As an exercise in addition, you may satisfy yourself that what I
-now say of the following square is correct. The numbers in every row,
-whether reckoned upright, or from right to left, or from corner to
-corner, when added together give the number 24156.
-
- +----+----+----+----+----+----+----+----+----+----+----+
- |2016|4212|1656|3852|1296|3492| 936|3132| 576|2772| 216|
- +----+----+----+----+----+----+----+----+----+----+----+
- | 252|2052|4248|1692|3888|1332|3528| 972|3168| 612|2412|
- +----+----+----+----+----+----+----+----+----+----+----+
- |2448| 288|2088|4284|1728|3924|1368|3564|1008|2808| 648|
- +----+----+----+----+----+----+----+----+----+----+----+
- | 684|2484| 324|2124|4320|1764|3960|1404|3204|1044|2844|
- +----+----+----+----+----+----+----+----+----+----+----+
- |2880| 720|2520| 360|2160|4356|1800|3600|1440|3240|1080|
- +----+----+----+----+----+----+----+----+----+----+----+
- |1116|2916| 756|2556| 396|2196|3996|1836|3636|1476|3276|
- +----+----+----+----+----+----+----+----+----+----+----+
- |3312|1152|2952| 792|2592| 36|2232|4032|1872|3672|1512|
- +----+----+----+----+----+----+----+----+----+----+----+
- |1548|3348|1188|2988| 432|2628| 72|2268|4068|1908|3708|
- +----+----+----+----+----+----+----+----+----+----+----+
- |3744|1584|3384| 828|3024| 468|2664| 108|2304|4104|1944|
- +----+----+----+----+----+----+----+----+----+----+----+
- |1980|3780|1224|3420| 864|3060| 504|2700| 144|2340|4140|
- +----+----+----+----+----+----+----+----+----+----+----+
- |4176|1620|3816|1260|3456| 900|3096| 540|2736| 180|2376|
- +----+----+----+----+----+----+----+----+----+----+----+
-
-35. If two numbers must be added together, it will not alter the sum if
-you take away a part of one, provided you put on as much to the other.
-It is plain that you will not alter the whole number of a collection
-of pebbles in two baskets by taking any number out of one, and putting
-them into the other. Thus, 15 + 7 is the same as 12 + 10, since 12 is 3
-less than 15, and 10 is three more than 7. This was the principle upon
-which the whole of the process in (29) was conducted.
-
-36. Let _a_ and _b_ stand for two numbers, as in (24). It is impossible
-to tell what their sum will be until the numbers themselves are
-known. In the mean while _a_ + _b_ stands for this sum. To say, in
-algebraical language, that the sum of _a_ and _b_ is not altered by
-adding _c_ to _a_, provided we take away _c_ from _b_, we have the
-following equation:
-
- (_a_ + _c_) + (_b_ - _c_) = _a_ + _b_;
-
-which may be written without brackets, thus,
-
- _a_ + _c_ + _b_ - _c_ = _a_ + _b_.
-
-For the meaning of these two equations will appear to be the same, on
-consideration.
-
-37. If _a_ be taken twice, three times, &c., the results are
-represented in algebra by 2_a_, 3_a_, 4_a_, &c. The sum of any two of
-this series may be expressed in a shorter form than by writing the sign
-+ between them; for though we do not know what number _a_ stands for,
-we know that, be it what it may,
-
- 2_a_ + 2_a_ = 4_a_, 3_a_ + 2_a_ = 5_a_, 4_a_ + 9_a_ = 13_a_;
-
-and generally, if _a_ taken _m_ times be added to _a_ taken _n_ times,
-the result is _a_ taken _m_ + _n_ times, or
-
- _ma_ + _na_ = (_m_ + _n_)_a_.
-
-38. The use of the brackets must here be noticed. They mean, that the
-expression contained inside them must be used exactly as a single
-letter would be used in the same place. Thus, _pa_ signifies that _a_
-is taken _p_ times, and (_m_ + _n_)_a_, that _a_ is taken _m_ + _n_
-times. It is, therefore, a different thing from _m_ + _na_, which means
-that _a_, after being taken _n_ times, is added to _m_. Thus (3 + 4) ×
-2 is 7 × 2 or 14; while 3 + 4 × 2 is 3 + 8, or 11.
-
-39. When one number is taken away from another, the number which is
-left is called the _difference_ or _remainder_. The process of finding
-the difference is called SUBTRACTION. The number which is to be taken
-away must be of course the lesser of the two.
-
-40. The process of subtraction depends upon these two principles.
-
-I. The difference of two numbers is not altered by adding a number to
-the first, if you add the same number to the second; or by subtracting
-a number from the first, if you subtract the same number from the
-second. Conceive two baskets with pebbles in them, in the first of
-which are 100 pebbles more than in the second. If I put 50 more
-pebbles into each of them, there are still only 100 more in the first
-than in the second, and the same if I take 50 from each. Therefore, in
-finding the difference of two numbers, if it should be convenient, I
-may add any number I please to both of them, because, though I alter
-the numbers themselves by so doing, I do not alter their difference.
-
- II. Since 6 exceeds 4 by 2,
- and 3 exceeds 2 by 1,
- and 12 exceeds 5 by 7,
-
-6, 3, and 12 together, or 21, exceed 4, 2, and 5 together, or 11, by
-2, 1, and 7 together, or 10: the same thing may be said of any other
-numbers.
-
-41. If _a_, _b_, and _c_ be three numbers, of which _a_ is greater than
-_b_ (40), I. leads to the following,
-
- (_a_ + _c_) - (_b_ + _c_) = _a_ - _b_.
-
-Again, if _c_ be less than _a_ and _b_,
-
- (_a_ - _c_) - (_b_ - _c_) = _a_ - _b_.
-
-The brackets cannot be here removed as in (36). That is, _p_- (_q_-_r_)
-is not the same thing as _p_-_q_- _r_. For, in the first, the
-difference of _q_ and _r_ is subtracted from _p_; but in the second,
-first _q_ and then _r_ are subtracted from _p_, which is the same as
-subtracting as much as _q_ and _r_ together, or _q_ + _r_. Therefore
-_p_-_q_-_r_ is _p_-(_q_ + _r_). In order to shew how to remove the
-brackets from _p_ -(_q_-_r_) without altering the value of the result,
-let us take the simple instance 12-(8-5). If we subtract 8 from 12, or
-form 12-8, we subtract too much; because it is not 8 which is to be
-taken away, but as much of 8 as is left after diminishing it by 5. In
-forming 12-8 we have therefore subtracted 5 too much. This must be set
-right by adding 5 to the result, which gives 12-8 + 5 for the value
-of 12-(8-5). The same reasoning applies to every case, and we have
-therefore,
-
- _p_ - (_q_ + _r_) = _p_ - _q_ - _r_.
-
- _p_ - (_q_ - _r_) = _p_ - _q_ + _r_.
-
-By the same kind of reasoning,
-
- _a_ - (_b_ + _c_ - _d_ - _e_) = _a_ - _b_ - _c_ + _d_ + _e_.
-
- 2_a_ + 3_b_ - (_a_ - 2_b_) = 2_a_ + 3_b_ - _a_ + 2_b_ = _a_ + 5_b_.
-
- 4_x_ + _y_ - (17_x_ - 9_y_) = 4_x_ + _y_ - 17_x_ + 9_y_
- = 10_y_ - 13_x_.
-
-42. I want to find the difference of the numbers 57762 and 34631. Take
-these to pieces as in (29) and
-
- 57762 is 5 ten-th. 7 th. 7 hund. 6 tens and 2 units.
-
- 34631 is 3 ten-th. 4 th. 6 hund. 3 tens and 1 unit.
-
- Now 2 units exceed 1 unit by 1 unit.
- 6 tens 3 tens 3 tens.
- 7 hundreds 6 hundreds 1 hundred.
- 7 thousands 4 thousands 3 thousands.
- 5 ten-thousands 3 ten-thous. 2 ten-thous.
-
-Therefore, by (40, Principle II.) all the first column _together_
-exceeds all the second column by all the third column, that is, by
-
- 2 ten-th. 3 th. 1 hund. 3 tens and 1 unit,
-
-which is 23131. Therefore the difference of 57762 and 34631 is 23131,
-or 57762-34631 = 23131.
-
-43. Suppose I want to find the difference between 61274 and 39628.
-Write them at length, and
-
- 61274 is 6 ten-th. 1 th. 2 hund. 7 tens and 4 units.
-
- 39628 is 3 ten-th. 9 th. 6 hund. 2 tens and 8 units.
-
-If we attempt to do the same as in the last article, there is a
-difficulty immediately, since 8, being greater than 4, cannot be
-taken from it. But from (40) it appears that we shall not alter the
-difference of two numbers if we add the same number to _both_ of them.
-Add ten to the first number, that is, let there be 14 units instead of
-four, and add ten also to the second number, but instead of adding ten
-to the number of units, add one to the number of tens, which is the
-same thing. The numbers will then stand thus,
-
- 6 ten-thous. 1 thous. 2 hund. 7 tens and 14 _units_.[7]
-
- 3 ten-thous. 9 thous. 6 hund. 3 _tens_ and 8 units.
-
-[7] Those numbers which have been altered are put in italics.
-
-You now see that the units and tens in the lower can be subtracted from
-those in the upper line, but that the hundreds cannot. To remedy this,
-add one thousand or 10 hundred to both numbers, which will not alter
-their difference, and remember to increase the hundreds in the upper
-line by 10, and the thousands in the lower line by 1, which are the
-same things. And since the thousands in the lower cannot be subtracted
-from the thousands in the upper line, add 1 ten thousand or 10 thousand
-to both numbers, and increase the thousands in the upper line by 10,
-and the ten thousands in the lower line by 1, which are the same
-things; and at the close the numbers which we get will be,
-
- 6 ten-thous. 11 _thous._ 12 _hund._ 7 tens and 14 _units_.
-
- 4 _ten-thous._ 10 _thous._ 6 hund. 3 _tens_ and 8 units.
-
-These numbers are not, it is true, the same as those given at the
-beginning of this article, but their difference is the same, by (40).
-With the last-mentioned numbers proceed in the same way as in (42),
-which will give, as their difference,
-
- 2 ten-thous. 1 thous. 6 hund. 4 tens, and 6 units, which is 21646.
-
-44. From this we deduce the following rules for subtraction:
-
-I. Write the number which is _to be subtracted_ (which is, of course,
-the lesser of the two, and is called the _subtrahend_) under the other,
-so that its units shall fall under the units of the other, and so on.
-
-II. Subtract each figure of the lower line from the one above it, if
-that can be done. Where that cannot be done, add ten to the upper
-figure, and then subtract the lower figure; but recollect in this case
-always to increase the next figure in the lower line by 1, before you
-begin to subtract it from the upper one.
-
-45. If there should not be as many figures in the lower line as in the
-upper one, proceed as if there were as many ciphers at the beginning
-of the lower line as will make the number of figures equal. You do not
-alter a number by placing ciphers at the beginning of it. For example,
-00818 is the same number as 818, for it means
-
- 0 ten-thous. 0 thous. 8 hunds. 1 ten and 8 units;
-
-the first two signs are nothing, and the rest is
-
- 8 hundreds, 1 ten, and 8 units, or 818.
-
-The second does not differ from the first, except in its being said
-that there are no thousands and no tens of thousands in the number,
-which may be known without their being mentioned at all. You may ask,
-perhaps, why this does not apply to a cipher placed in the middle of
-a number, or at the right of it, as, for example, in 28007 and 39700?
-But you must recollect, that if it were not for the two ciphers in the
-first, the 8 would be taken for 8 tens, instead of 8 thousands; and if
-it were not for the ciphers in the second, the 7 would be taken for 7
-units, instead of 7 hundreds.
-
-
- 46. EXAMPLE.
-
- What is the difference between 3708291640030174
- and 30813649276188
- ----------------
- Difference 3677477990753986
-
-EXERCISES.
-
- I. What is 18337 + 149263200 - 6472902?--_Answer_ 142808635.
- What is 1000 - 464 + 3279 - 646?--_Ans._ 3169.
-
-II. Subtract
-
- 64 + 76 + 144 - 18 from 33 - 2 + 100037.--_Ans._ 99802.
-
-III. What shorter rule might be made for subtraction when all the
-figures in the upper line are ciphers except the first? for example, in
-finding
-
- 10000000 - 2731634.
-
-IV. Find 18362 + 2469 and 18362-2469, add the second result to the
-first, and then subtract 18362; subtract the second from the first, and
-then subtract 2469.--_Answer_ 18362 and 2469.
-
-V. There are four places on the same line in the order A, B, C, and D.
-From A to D it is 1463 miles; from A to C it is 728 miles; and from B
-to D it is 1317 miles. How far is it from A to B, from B to C, and from
-C to D?--_Answer._ From A to B 146, from B to C 582, and from C to D
-735 miles.
-
-VI. In the following table subtract B from A, and B from the remainder,
-and so on until B can be no longer subtracted. Find how many times B
-can be subtracted from A, and what is the last remainder.
-
- No. of
- A B times. Remainder.
- 23604 9999 2 3606
- 209961 37173 5 24096
- 74712 6792 11 0
- 4802469 654321 7 222222
- 18849747 3141592 6 195
- 987654321 123456789 8 9
-
-
-
-
-SECTION III.
-
-MULTIPLICATION.
-
-
-47. I have said that all questions in arithmetic require nothing but
-addition and subtraction. I do not mean by this that no rule should
-ever be used except those given in the last section, but that all
-other rules only shew shorter ways of finding what might be found,
-if we pleased, by the methods there deduced. Even the last two rules
-themselves are only short and convenient ways of doing what may be done
-with a number of pebbles or counters.
-
-48. I want to know the sum of five seventeens, or I ask the following
-question: There are five heaps of pebbles, and seventeen pebbles in
-each heap; how many are there in all? Write five seventeens in a
-column, and make the addition, which gives 85. In this case 85 is
-called the _product_ of 5 and 17, and the process of finding the
-product is called MULTIPLICATION, which gives nothing more than the
-addition of a number of the same quantities. Here 17 is called the
-_multiplicand_, and 5 is called the _multiplier_.
-
- 17
- 17
- 17
- 17
- 17
- ----
- 85
-
-49. If no question harder than this were ever proposed, there would be
-no occasion for a shorter way than the one here followed. But if there
-were 1367 heaps of pebbles, and 429 in each heap, the whole number is
-then 1367 times 429, or 429 multiplied by 1367. I should have to write
-429 1367 times, and then to make an addition of enormous length. To
-avoid this, a shorter rule is necessary, which I now proceed to explain.
-
-50. The student must first make himself acquainted with the products of
-all numbers as far as 10 times 10 by means of the following table,[8]
-which must be committed to memory.
-
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 2 | 4 | 6 | 8 | 10 | 12 | 14 | 16 | 18 | 20 | 22 | 24 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 3 | 6 | 9 | 12 | 15 | 18 | 21 | 24 | 27 | 30 | 33 | 36 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 4 | 8 | 12 | 16 | 20 | 24 | 28 | 32 | 36 | 40 | 44 | 48 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 5 | 10 | 15 | 20 | 25 | 30 | 35 | 40 | 45 | 50 | 55 | 60 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 6 | 12 | 18 | 24 | 30 | 36 | 42 | 48 | 54 | 60 | 66 | 72 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 7 | 14 | 21 | 28 | 35 | 42 | 49 | 56 | 63 | 70 | 77 | 84 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 8 | 16 | 24 | 32 | 40 | 48 | 56 | 64 | 72 | 80 | 88 | 96 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 9 | 18 | 27 | 36 | 45 | 54 | 63 | 72 | 81 | 90 | 99 |108 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 10 | 20 | 30 | 40 | 50 | 60 | 70 | 80 | 90 |100 |110 |120 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 11 | 22 | 33 | 44 | 55 | 66 | 77 | 88 | 99 |110 |121 |132 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
- | 12 | 24 | 36 | 48 | 60 | 72 | 84 | 96 |108 |120 |132 |144 |
- +----+----+----+----+----+----+----+----+----+----+----+----+
-
-[8] As it is usual to learn the product of numbers up to 12 times 12, I
-have extended the table thus far. In my opinion, all pupils who shew a
-tolerable capacity should slowly commit the products to memory as far
-as 20 times 20, in the course of their progress through this work.
-
-If from this table you wish to know what is 7 times 6, look in the
-first upright column on the left for either of them; 6 for example.
-Proceed to the right until you come into the column marked 7 at the
-top. You there find 42, which is the product of 6 and 7.
-
-51. You may find, in this way, either 6 times 7, or 7 times 6, and
-for both you find 42. That is, six sevens is the same number as seven
-sixes. This may be shewn as follows: Place seven counters in a line,
-and repeat that line in all six times. The number of counters in the
-whole is 6 times 7, or six sevens, if I reckon the rows from the top
-to the bottom; but if I count the rows that stand side by side, I find
-seven of them, and six in each row, the whole number of which is 7
-times 6, or seven sixes. And the whole number is 42, whichever way I
-count. The same method may be applied to any other two numbers. If the
-signs of (23) were used, it would be said that 7 × 6 = 6 × 7.
-
- ● ● ● ● ● ● ●
- ● ● ● ● ● ● ●
- ● ● ● ● ● ● ●
- ● ● ● ● ● ● ●
- ● ● ● ● ● ● ●
- ● ● ● ● ● ● ●
-
-52. To take any quantity a number of times, it will be enough to take
-every one of its parts the same number of times. Thus, a sack of corn
-will be increased fifty-fold, if each bushel which it contains be
-replaced by 50 bushels. A country will be doubled by doubling every
-acre of land, or every county, which it contains. Simple as this
-may appear, it is necessary to state it, because it is one of the
-principles on which the rule of multiplication depends.
-
-53. In order to multiply by any number, you may multiply separately
-by any parts into which you choose to divide that number, and add the
-results. For example, 4 and 2 make 6. To multiply 7 by 6 first multiply
-7 by 4, and then by 2, and add the products. This will give 42, which
-is the product of 7 and 6. Again, since 57 is made up of 32 and 25, 57
-times 50 is made up of 32 times 50 and 25 times 50, and so on. If the
-signs were used, these would be written thus:
-
- 7 × 6 = 7 × 4 + 7 × 2.
- 50 × 57 = 50 × 32 + 50 × 25.
-
-54. The principles in the last two articles may be expressed thus: If
-_a_ be made up of the parts _x_, _y_, and _x_, _ma_ is made up of _mx_,
-_my_, and _mz_; or,
-
- if _a_ = _x_ + _y_ + _z_.
- _ma_ = _mx_ + _my_ + _mz_,
- or, _m_(_x_ + _y_ + _z_) = _mx_ + _my_ + _mz_.
-
-A similar result may be obtained if _a_, instead of being made up of
-_x_, _y_, and _z_, is made by combined additions and subtractions, such
-as _x_ + _y_-_z_, _x_- _y_ + _z_, _x_-_y_-_z_, &c. To take the first as
-an instance:
-
- Let _a_ = _x_ + _y_ - _z_,
- then _ma_ = _mx_ + _my_ - _mz_.
-
-For, if _a_ had been _x_ + _y_, _ma_ would have been _mx_ + _my_. But
-since _a_ is less than _x_ + _y_ by _z_, too much by _z_ has been
-repeated every time that _x_ + _y_ has been repeated;--that is, _mz_
-too much has been taken; consequently, _ma_ is not _mx_ + _my_, but
-_mx_ + _my_-_mz_. Similar reasoning may be applied to other cases, and
-the following results may be obtained:
-
- _m_(_a_ + _b_ + _c_ - _d_) = _ma_ + _mb_ + _mc_ - _md_.
-
- _a_(_a_ - _b_) = _aa_ - _ab_.
- _b_(_a_ - _b_) = _ba_ - _bb_.
- 3(2_a_ - 4_b_) = 6_a_ - 12_b_.
- 7_a_(7 + 2_b_) = 49_a_ + 14_ab_.
- (_aa_ + _a_ + 1)_a_ = _aaa_ + _aa_ + _a_.
- (3_ab_ - 2_c_)4_abc_ = 12_aabbc_ - 8_abcc_.
-
-55. There is another way in which two numbers may be multiplied
-together. Since 8 is 4 times 2, 7 times 8 may be made by multiplying 7
-and 4, and then multiplying that _product_ by 2. To shew this, place 7
-counters in a line, and repeat that line in all 8 times, as in figures
-I. and II.
-
- I.
- +---------------+
- | ● ● ● ● ● ● ● |
- A | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- +---------------+
-
- +---------------+
- | ● ● ● ● ● ● ● |
- B | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- +---------------+
-
- II.
- +---------------+
- | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- +---------------+
-
- +---------------+
- | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- +---------------+
-
- +---------------+
- | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- +---------------+
-
- +---------------+
- | ● ● ● ● ● ● ● |
- | ● ● ● ● ● ● ● |
- +---------------+
-
-
-The number of counters in all is 8 times 7, or 56. But (as in fig. I.)
-enclose each four rows in oblong figures, such as A and B. The number
-in each oblong is 4 times 7, or 28, and there are two of those oblongs;
-so that in the whole the number of counters is twice 28, or 28 x 2, or
-7 first multiplied by 4, and that product multiplied by 2. In figure
-II. it is shewn that 7 multiplied by 8 is also 7 first multiplied by
-2, and that product multiplied by 4. The same method may be applied
-to other numbers. Thus, since 80 is 8 times 10, 256 times 80 is 256
-multiplied by 8, and that product multiplied by 10. If we use the
-signs, the foregoing assertions are made thus:
-
- 7 × 8 = 7 × 4 × 2 = 7 × 2 × 4.
- 256 × 80 = 256 × 8 × 10 = 256 × 10 × 8.
-
-EXERCISES.
-
-Shew that 2 × 3 × 4 × 5 = 2 × 4 × 3 × 5 = 5 × 4 × 2 × 3, &c.
-
-Shew that 18 × 100 = 18 × 57 + 18 × 43.
-
-56. Articles (51) and (55) may be expressed in the following way, where
-by _ab_ we mean _a_ taken _b_ times; by _abc_, _a_ taken _b_ times, and
-the result taken _c_ times.
-
- _ab_ = _ba_.
- _abc_ = _acb_ = _bca_ = _bac_, &c.
- _abc_ = _a_ × (_bc_) = _b_ × (_ca_) = _c_ × (_ab_).
-
-If we would say that the same results are produced by multiplying by
-_b_, _c_, and _d_, one after the other, and by the product _bcd_ at
-once, we write the following:
-
- _a_ × _b_ × _c_ × _d_ = _a_ × _bcd_.
-
-The fact is, that if any numbers are to be multiplied together, the
-product of any two or more may be formed, and substituted instead
-of those two or more; thus, the product _abcdef_ may be formed by
-multiplying
-
- _ab_ _cde_ _f_
- _abf_ _de_ _c_
- _abc_ _def_ &c.
-
-57. In order to multiply by 10, annex a cipher to the right hand of the
-multiplicand. Thus, 10 times 2356 is 23560. To shew this, write 2356 at
-length which is
-
- 2 thousands, 3 hundreds, 5 tens, and 6 units.
-
-Take each of these parts ten times, which, by (52), is the same as
-multiplying the whole number by 10, and it will then become
-
- 2 tens of thou. 3 tens of hun. 5 tens of tens, and 6 tens,
-
-which is
-
- 2 ten-thou. 3 thous. 5 hun. and 6 tens.
-
-This must be written 23560, because 6 is not to be 6 units, but 6 tens.
-Therefore 2356 × 10 = 23560.
-
-In the same way you may shew, that in order to multiply by 100 you
-must affix two ciphers to the right; to multiply by 1000 you must
-affix three ciphers, and so on. The rule will be best caught from the
-following table:
-
- 13 × 10 = 130
- 13 × 100 = 1300
- 13 × 1000 = 13000
- 13 × 10000 = 130000
- 142 × 1000 = 142000
- 23700 × 10 = 237000
- 3040 × 1000 = 3040000
- 10000 × 100000 = 1000000000
-
-58. I now shew how to multiply by one of the numbers, 2, 3, 4, 5, 6, 7,
-8, or 9. I do not include 1, because multiplying by 1, or taking the
-number once, is what is meant by simply writing down the number. I want
-to multiply 1368 by 8. Write the first number at full length, which is
-
- 1 thousand, 3 hundreds, 6 tens, and 8 units.
-
-To multiply this by 8, multiply each of these parts by 8 (50) and (52),
-which will give
-
- 8 thousands, 24 hundreds, 48 tens, and 64 units.
-
- Now 64 units are written thus 64
- 48 tens 480
- 24 hundreds 2400
- 8 thousands 8000
-
-Add these together, which gives 10944 as the product of 1368 and 8, or
-1368 × 8 = 10944. By working a few examples in this way you will see
-for following rule.
-
-59. I. Multiply the first figure of the multiplicand by the multiplier,
-write down the units’ figure, and reserve the tens.
-
-II. Do the same with the second figure of the multiplicand, and add
-to the product the number of tens from the first; put down the units’
-figure of this, and reserve the tens.
-
-III. Proceed in this way till you come to the last figure, and then
-write down the whole number obtained from that figure.
-
-IV. If there be a cipher in the multiplicand, treat it as if it were a
-number, observing that 0 × 1 = 0, 0 × 2 = 0, &c.
-
-60. In a similar way a number can be multiplied by a figure which is
-accompanied by ciphers, as, for example, 8000. For 8000 is 8 × 1000,
-and therefore (55) you must first multiply by 8 and then by 1000, which
-last operation (57) is done by placing 3 ciphers on the right. Hence
-the rule in this case is, multiply by the simple number, and place the
-number of ciphers which follow it at the right of the product.
-
- EXAMPLE.
-
- Multiply 1679423800872
- by 60000
- ------------------
- 100765428052320000
-
-61. EXERCISES.
-
- What is 1007360 × 7? _Answer_, 7051520.
-
- 123456789 × 9 + 10 and 123 × 9 + 4?--_Ans._ 1111111111 and 1111.
-
- What is 136 × 3 + 129 × 4 + 147 × 8 + 27 × 3000?--_Ans._ 83100.
-
-An army is made up of 33 regiments of infantry, each containing 800
-men; 14 of cavalry, each containing 600 men; and 2 of artillery, each
-containing 300 men. The enemy has 6 more regiments of infantry, each
-containing 100 more men; 3 more regiments of cavalry, each containing
-100 men less; and 4 corps of artillery of the same magnitude as those
-of the first: two regiments of cavalry and one of infantry desert from
-the former to the latter. How many men has the second army more than
-the first?--_Answer_, 13400.
-
-62. Suppose it is required to multiply 23707 by 4567. Since 4567 is
-made up of 4000, 500, 60, and 7, by (53) we must multiply 23707 by each
-of these, and add the products.
-
- Now (58) 23707 × 7 is 165949
- (60) 23707 × 60 is 1422420
- 23707 × 500 is 11853500
- 23707 × 4000 is 94828000
- ---------
- The sum of these is 108269869
-
-which is the product required.
-
-It will do as well if, instead of writing the ciphers at the end of
-each line, we keep the other figures in their places without them. If
-we take away the ciphers, the second line is one place to the left of
-the first, the third one place to the left of the second, and so on.
-Write the multiplier and the multiplicand over these lines, and the
-process will stand thus:
-
- 23707
- 4567
- ------
- 165949
- 142242
- 118535
- 94828
- ---------
- 108269869
-
-63. There is one more case to be noticed; that is, where there is a
-cipher in the middle of the multiplier. The following example will shew
-that in this case nothing more is necessary than to keep the first
-figure of each line in the column under the figure of the multiplier
-from which that line arises. Suppose it required to multiply 365 by
-101001. The multiplier is made up of 100000, 1000 and 1. Proceed as
-before, and
-
- 365 × 1 is 365
- (57) 365 × 1000 is 365000
- 365 × 100000 is 36500000
- --------
- The sum of which is 36865365
-
-and the whole process with the ciphers struck off is:
-
- 365
- 101001
- ------
- 365
- 365
- 365
- --------
- 36865365
-
-64. The following is the rule in all cases:
-
-I. Place the multiplier under the multiplicand, so that the units of
-one may be under those of the other.
-
-II. Multiply the whole multiplicand by each figure of the multiplier
-(59), and place the unit of each line in the column under the figure of
-the multiplier from which it came.
-
-III. Add together the lines obtained by II. column by column.
-
-65. When the multiplier or multiplicand, or both, have ciphers on the
-right hand, multiply the two together without the ciphers, and then
-place on the right of the product all the ciphers that are on the right
-both of the multiplier and multiplicand. For example, what is 3200 ×
-3000? First, 3200 is 32 × 100, or one hundred times as great as 32.
-Again, 32 × 13000 is 32 × 13, with three ciphers affixed, that is 416,
-with three ciphers affixed, or 416000. But the product required must
-be 100 times as great as this, or must have two ciphers affixed. It is
-therefore 41600000, having as many ciphers as are in both multiplier
-and multiplicand.
-
-66. When any number is multiplied by itself any number of times, the
-result is called a _power_ of that number. Thus:
-
- 6 is called the first power of 6
- 6 × 6 second power of 6
- 6 × 6 × 6 third power of 6
- 6 × 6 × 6 × 6 fourth power of 6
- &c. &c.
-
-The second and third powers are usually called the _square_ and
-_cube_, which are incorrect names, derived from certain connexions of
-the second and third power with the square and cube in geometry. As
-exercises in multiplication, the following powers are to be found.
-
- Number proposed. Square. Cube.
- 972 944784 918330048
- 1008 1016064 1024192512
- 3142 9872164 31018339288
- 3163 10004569 31644451747
- 5555 30858025 171416328875
- 6789 46090521 312908547069
-
- The fifth power of 36 is 60466176
- fourth 50 6250000
- fourth 108 136048896
- fourth 277 5887339441
-
-67. It is required to multiply _a_ + _b_ by _c_ + _d_, that is, to take
-_a_ + _b_ as many times as there are units in _c_ + _d_. By (53) _a_
-+ _b_ must be taken _c_ times, and _d_ times, or the product required
-is (_a_ + _b_)_c_ + (_a_ + _b_)_d_. But (52) (_a_ + _b_)_c_ is _ac_ +
-_bc_, and (_a_ + _b_)_d_ is _ad_ + _bd_; whence the product required is
-_ac_ + _bc_ + _ad_ + _bd_; or,
-
- (_a_ + _b_)(_c_ + _d_) = _ac_ + _bc_ + _ad_ + _bd_.
-
-By similar reasoning
-
- (_a_ - _b_)(_c_ + _d_) is (_a_ - _b_)_c_ + (_a_ - _b_)_d_; or,
-
- (_a_ - _b_)(_c_ + _d_) = _ac_ - _bc_ + _ad_ - _bd_.
-
-To multiply _a_-_b_ by _c_-_d_, first take _a_-_b_ _c_ times, which
-gives _ac_-_bc_. This is not correct; for in taking it _c_ times
-instead of _c_-_d_ times, we have taken it _d_ times too many; or have
-made a result which is (_a_-_b_)_d_ too great. The real result is
-therefore _ac_-_bc_-(_a_ -_b_)_d_. But (_a_-_b_)_d_ is _ad_- _bd_, and
-therefore
-
- (_a_ - _b_)(_c_ - _d_) = _ac_ - _bc_ - _ad_ - _bd_
- = _ac_ - _bc_ - _ad_ + _bd_ (41)
-
-From these three examples may be collected the following rule for the
-multiplication of algebraic quantities: Multiply each term of the
-multiplicand by each term of the multiplier; when the two terms have
-both + or both-before them, put + before their product; when one has
-+ and the other-, put-before their product. In using the first terms,
-which have no sign, apply the rule as if they had the sign +.
-
-68. For example, (_a_ + _b_)(_a_ + _b_) gives _aa_ + _ab_ + _ab_ +
-_bb_. But _ab_ + _ab_ is 2_ab_; hence the _square_ of _a_ + _b_ is
-_aa_ + 2_ab_ + _bb_. Again (_a_- _b_)(_a_-_b_) gives _aa_-_ab_-_ab_
-+ _bb_. But two subtractions of _ab_ are equivalent to subtracting
-2_ab_; hence the _square_ of _a_- _b_ is _aa_-2_ab_ + _bb_. Again, (_a_
-+ _b_)(_a_-_b_) gives _aa_ + _ab_-_ab_ -_bb_. But the addition and
-subtraction of _ab_ makes no change; hence the product of _a_ + _b_ and
-_a_- _b_ is _aa_-_bb_.
-
-Again, the square of _a_ + _b_ + _c_ + _d_ or (_a_ + _b_ + _c_ +
-_d_)(_a_ + _b_ + _c_ + _d_) will be found to be _aa_ + 2_ab_ + 2_ac_
-+ 2_ad_ + _bb_ + 2_bc_ + 2_bd_ + _cc_ + 2_cd_ + _dd_; or the rule for
-squaring such a quantity is: Square the first term, and multiply all
-that come _after_ by twice that term; do the same with the second, and
-so on to the end.
-
-
-SECTION IV.
-
-DIVISION.
-
-69. Suppose I ask whether 156 can be divided into a number of parts
-each of which is 13, or how many thirteens 156 contains; I propose a
-question, the solution of which is called DIVISION. In this case, 156
-is called the _dividend_, 13 the _divisor_, and the number of parts
-required is the _quotient_; and when I find the quotient, I am said to
-divide 156 by 13.
-
-70. The simplest method of doing this is to subtract 13 from 156,
-and then to subtract 13 from the remainder, and so on; or, in common
-language, to _tell off_ 156 by thirteens. A similar process has already
-occurred in the exercises on subtraction, Art. (46). Do this, and
-mark one for every subtraction that is made, to remind you that each
-subtraction takes 13 once from 156, which operations will stand as
-follows:
-
- 156
- 13 1
- ------
- 143
- 13 1
- ------
- 130
- 13 1
- ------
- 117
- 13 1
- ------
- 104
- 13 1
- ------
- 91
- 13 1
- ------
- 78
- 13 1
- ------
- 65
- 13 1
- ------
- 52
- 13 1
- ------
- 39
- 13 1
- ------
- 26
- 13 1
- ------
- 13
- 13 1
- ------
- 0
-
-Begin by subtracting 13 from 156, which leaves 143. Subtract 13 from
-143, which leaves 130; and so on. At last 13 only remains, from which
-when 13 is subtracted, there remains nothing. Upon counting the number
-of times which you have subtracted 13, you find that this number is 12;
-or 156 contains twelve thirteens, or contains 13 twelve times.
-
-This method is the most simple possible, and might be done with
-pebbles. Of these you would first count 156. You would then take 13
-from the heap, and put them into one heap by themselves. You would
-then take another 13 from the heap, and place them in another heap by
-themselves; and so on until there were none left. You would then count
-the number of heaps, which you would find to be 12.
-
-71. Division is the opposite of multiplication. In multiplication you
-have a number of heaps, with the same number of pebbles in each, and
-you want to know how many _pebbles_ there are in all. In division you
-know how many there are in all, and how many there are to be in each
-heap, and you want to know how many _heaps_ there are.
-
-72. In the last example a number was taken which contains an exact
-number of thirteens. But this does not happen with every number. Take,
-for example, 159. Follow the process of (70), and it will appear that
-after having subtracted 13 twelve times, there remains 3, from which
-13 cannot be subtracted. We may say then that 159 contains twelve
-thirteens and 3 _over_; or that 159, when divided by 13, gives a
-_quotient_ 12, and a _remainder_ 3. If we use signs,
-
- 159 = 13 × 12 + 3.
-
-
-EXERCISES.
-
- 146 = 24 × 6 + 2, or 146 contains six twenty-fours and 2 over.
- 146 = 6 × 24 + 2, or 146 contains twenty-four sixes and 2 over.
- 300 = 42 × 7 + 6, or 300 contains seven forty-twos and 6 over.
- 39624 = 7277 × 5 + 3239.
-
-73. If _a_ contain _b_ _q_ times with a remainder _r_, _a_ must be
-greater than _bq_ by _r_; that is,
-
- _a_ = _bq_ + _r_.
-
-If there be no remainder, _a_ = _bq_. Here _a_ is the dividend, _b_ the
-divisor, _q_ the quotient, and _r_ the remainder. In order to say that
-_a_ contains _b_ _q_ times, we write,
-
- _a_/_b_ = _q_, or _a_ : _b_ = _q_,
-
-which in old books is often found written thus:
-
- _a_ ÷ _b_ = _q_.
-
-74. If I divide 156 into several parts, and find how often 13 is
-contained in each of them, it is plain that 156 contains 13 as often as
-all its parts together. For example, 156 is made up of 91, 39, and 26.
-Of these
-
- 91 contains 13 7 times,
- 39 contains 13 3 times,
- 26 contains 13 2 times;
-
-therefore 91 + 39 + 26 contains 13 7 + 3 + 2 times, or 12 times.
-
-Again, 156 is made up of 100, 50, and 6.
-
- Now 100 contains 13 7 times and 9 over,
- 50 contains 13 3 times and 11 over,
- 6 contains 13 0 times[9] and 6 over.
-
-[9] To speak always in the same way, instead of saying that 6 does not
-contain 13, I say that it contains it 0 times and 6 over, which is
-merely saying that 6 is 6 more than nothing.
-
-Therefore 100 + 50 + 6 contains 13 7 + 3 + 0 times and 9 + 11 + 6 over;
-or 156 contains 13 10 times and 26 over. But 26 is itself 2 thirteens;
-therefore 156 contains 10 thirteens and 2 thirteens, or 12 thirteens.
-
-75. The result of the last article is expressed by saying, that if
-
- _a_ = _b_ + _c_ + _d_, then _a_/_m_ = _b_/_m_ + _c_/_m_ + _d_/_m_
-
-76. In the first example I did not take away 13 more than once at a
-time, in order that the method might be as simple as possible. But
-if I know what is twice 13, 3 times 13, &c., I can take away as many
-thirteens at a time as I please, if I take care to mark at each step
-how many I take away. For example, take away 13 ten times at once from
-156, that is, take away 130, and afterwards take away 13 twice, or take
-away 26, and the process is as follows:
-
- 156
- 130 10 times 13.
- ---
- 26
-
- 26 2 times 13.
- ---
- 0
-
-Therefore 156 contains 13 10 + 2, or 12 times.
-
-Again, to divide 3096 by 18.
-
- 3096
- 1800 100 times 18.
- ----
- 1296
- 900 50 times 18.
- ----
- 396
- 360 20 times 18.
- ----
- 36
- 36 2 times 18.
- ----
- 0
-
-Therefore 3096 contains 18 100 + 50 + 20 + 2, or 172 times.
-
-77. You will now understand the following sentences, and be able to
-make similar assertions of other numbers.
-
-450 is 75 × 6; it therefore contains any number, as 5, 6 times as often
-as 75 contains it.
-
- 135 contains 3 more than 26 times; therefore,
- Twice 135 ” 3 ” 52 or twice 26 times.
- 10 times 135 ” 3 ” 260 or 10 times 26
- 50 times 135 ” 3 ” 1300 or 50 times 26
-
- 472 contains 18 more than 21 times; therefore,
- 4720 contains 18 more than 210 times,
- 47200 contains 18 more than 2100 times,
- 472000 contains 18 more than 21000 times,
-
- 32 contains 12 more than 2 times, and less than 3 times.
- 320 ” 12 ” 20 30
- 3200 ” 12 ” 200 300
- 32000 ” 12 ” 2000 3000
- &c. &c. &c.
-
-78. The foregoing articles contain the principles of division. The
-question now is, to apply them in the shortest and most convenient way.
-Suppose it required to divide 4068 by 18, or to find 4068/18 (23).
-
-If we divide 4068 into any number of parts, we may, by the process
-followed in (74), find how many times 18 is contained in each of these
-parts, and from thence how many times it is contained in the whole.
-Now, what separation of 4068 into parts will be most convenient?
-Observe that 4, the first figure of 4068, does not contain 18; but that
-40, the first and second figures together, _does contain 18 more than
-twice, but less than three times_.[10] But 4068 (20) is made up of 40
-hundreds, and 68; of which, 40 hundreds (77) contains 18 more than 200
-times, and less than 300 times. Therefore, 4068 also contains more than
-200 times 18, since it must contain 18 more times than 4000 does. It
-also contains 18 less than 300 times, because 300 times 18 is 5400, a
-greater number than 4068. Subtract 18 200 times from 4068; that is,
-subtract 3600, and there remains 468. Therefore, 4068 contains 18 200
-times, and as many more times as 468 contains 18.
-
-[10] If you have any doubt as to this expression, recollect that it
-means “contains more than two eighteens, but not so much as three.”
-
-It remains, then, to find how many times 468 contains 18. Proceed
-exactly as before. Observe that 46 contains 18 more than twice, and
-less than 3 times; therefore, 460 contains it more than 20, and less
-than 30 times (77); as does also 468. Subtract 18 20 times from 468,
-that is, subtract 360; the remainder is 108. Therefore, 468 contains
-18 20 times, and as many more as 108 contains it. Now, 108 is found to
-contain 18 6 times exactly; therefore, 468 contains it 20 + 6 times,
-and 4068 contains it 200 + 20 + 6 times, or 226 times. If we write down
-the process that has been followed, without any explanation, putting
-the divisor, dividend, and quotient, in a line separated by parentheses
-it will stand, as in example(A).
-
-Let it be required to divide 36326599 by 1342 (B).
-
- A. B.
-
- 18)4068(200 + 20 + 6 1342)36326599(20000 + 7000 + 60 + 9
- 3600 26840000
- ---- --------
- 468 9486599
- 360 9394000
- --- -------
- 108 92599
- 108 80520
- --- -----
- 0 12079
- 12078
- -----
- 1
-
-As in the previous example, 36326599 is separated into 36320000 and
-6599; the first four figures 3632 being separated from the rest,
-because it takes four figures from the left of the dividend to make
-a number which is greater than the divisor. Again, 36320000 is found
-to contain 1342 more than 20000, and less than 30000 times; and 1342
-× 20000 is subtracted from the dividend, after which the remainder is
-9486599. The same operation is repeated again and again, and the result
-is found to be, that there is a quotient 20000 + 7000 + 60 + 9, or
-27069, and a remainder 1.
-
-Before you proceed, you should now repeat the foregoing article at
-length in the solution of the following questions. What are
-
- 10093874 66779922 2718218
- -------- , -------- , ------- ?
- 3207 114433 13352
-
-the quotients of which are 3147, 583, 203; and the remainders 1445,
-65483, 7762.
-
-79. In the examples of the last article, observe, 1st, that it is
-useless to write down the ciphers which are on the right of each
-subtrahend, provided that without them you keep each of the other
-figures in its proper place: 2d, that it is useless to put down the
-right hand figures of the dividend so long as they fall over ciphers,
-because they do not begin to have any share in the making of the
-quotient until, by continuing the process, they cease to have ciphers
-under them: 3d, that the quotient is only a number written at length,
-instead of the usual way. For example, the first quotient is 200 + 20
-+ 6, or 226; the second is 20000 + 7000 + 60 + 9, or 27069. Strike
-out, therefore, all the ciphers and the numbers which come above them,
-except those in the first line, and put the quotient in one line; and
-the two examples of the last article will stand thus:
-
- 18)4068(226 1342)36326599(27069
- 36 2684
- --- -----
- 46 9486
- 36 9394
- --- -----
- 108 9259
- 108 8052
- --- -----
- 0 12079
- 12078
- -----
- 1
-
-80. Hence the following rule is deduced:
-
-I. Write the divisor and dividend in one line, and place parentheses on
-each side of the dividend.
-
-II. Take off from the left-hand of the dividend the least number of
-figures which make a number greater than the divisor; find what number
-of times the divisor is contained in these, and write this number as
-the first figure of the quotient.
-
-III. Multiply the divisor by the last-mentioned figure, and subtract
-the product from the number which was taken off at the left of the
-dividend.
-
-IV. On the right of the remainder place the figure of the dividend
-which comes next after those already separated in II.: if the remainder
-thus increased be greater than the divisor, find how many times the
-divisor is contained in it; put this number at the right of the first
-figure of the quotient, and repeat the process: if not, on the right
-place the next figure of the dividend, and the next, and so on until it
-is greater; but remember to place a cipher in the quotient for every
-figure of the dividend which you are obliged to take, except the first.
-
-V. Proceed in this way until all the figures of the dividend are
-exhausted.
-
-In judging how often one large number is contained in another, a first
-and rough guess may be made by striking off the same number of figures
-from both, and using the results instead of the numbers themselves.
-Thus, 4,732 is contained in 14,379 about the same number of times
-that 4 is contained in 14, or about 3 times. The reason is, that 4
-being contained in 14 as often as 4000 is in 14000, and these last
-only differing from the proposed numbers by lower denominations, viz.
-hundreds, &c. we may expect that there will not be much difference
-between the number of times which 14000 contains 4000, and that which
-14379 contains 4732: and it generally happens so. But if the second
-figure of the divisor be 5, or greater than 5, it will be more accurate
-to increase the first figure of the divisor by 1, before trying the
-method just explained. Nothing but practice can give facility in this
-sort of guess-work.
-
-81. This process may be made more simple when the divisor is not
-greater than 12, if you have sufficient knowledge of the multiplication
-table (50). For example, I want to divide 132976 by 4. At full length
-the process stands thus:
-
- 4)132976(33244
- 12
- ---
- 12
- 12
- ---
- 9
- 8
- --
- 17
- 16
- ---
- 16
- 16
- --
- 0
-
-But you will recollect, without the necessity of writing it down,
-that 13 contains 4 three times with a remainder 1; this 1 you will
-place before 2, the next figure of the dividend, and you know that 12
-contains 4 3 times exactly, and so on. It will be more convenient to
-write down the quotient thus:
-
- 4)132976
- -------
- 33244
-
-While on this part of the subject, we may mention, that the shortest
-way to multiply by 5 is to annex a cipher and divide by 2, which is
-equivalent to taking the half of 10 times, or 5 times. To divide by
-5, multiply by 2 and strike off the last figure, which leaves the
-quotient; half the last figure is the remainder. To multiply by 25,
-annex two ciphers and divide by 4. To divide by 25, multiply by 4 and
-strike off the last two figures, which leaves the quotient; one fourth
-of the last two figures, taken as one number, is the remainder. To
-multiply a number by 9, annex a cipher, and subtract the number, which
-is equivalent to taking the number ten times, and then subtracting it
-once. To multiply by 99, annex two ciphers and subtract the number, &c.
-
-In order that a number may be divisible by 2 without remainder, its
-units’ figure must be an even number.[11] That it may be divisible by
-4, its last two figures must be divisible by 4. Take the example 1236:
-this is composed of 12 hundreds and 36, the first part of which, being
-hundreds, is divisible by 4, and gives 12 twenty-fives; it depends then
-upon 36, the last two figures, whether 1236 is divisible by 4 or not.
-A number is divisible by 8 if the last three figures are divisible by
-8; for every digit, except the last three, is a number of thousands,
-and 1000 is divisible by 8; whether therefore the whole shall be
-divisible by 8 or not depends on the last three figures: thus, 127946
-is not divisible by 8, since 946 is not so. A number is divisible by 3
-or 9 only when the sum of its digits is divisible by 3 or 9. Take for
-example 1234; this is
-
-[11] Among the even figures we include 0.
-
- 1 thousand, or 999 and 1
- 2 hundred, or twice 99 and 2
- 3 tens, or three times 9 and 3
- and 4 or 4
-
-Now 9, 99, 999, &c. are all obviously divisible by 9 and by 3, and so
-will be any number made by the repetition of all or any of them any
-number of times. It therefore depends on 1 + 2 + 3 + 4, or the sum of
-the digits, whether 1234 shall be divisible by 9 or 3, or not. From
-the above we gather, that a number is divisible by 6 when it is even,
-and when the sum of its digits is divisible by 3. Lastly, a number is
-divisible by 5 only when the last figure is 0 or 5.
-
-82. Where the divisor is unity followed by ciphers, the rule becomes
-extremely simple, as you will see by the following examples:
-
- 100)33429(334
- 300
- ----
- 342
- 300
- ----
- 429
- 400
- ---
- 29
-
-This is, then, the rule: Cut off as many figures from the right hand of
-the dividend as there are ciphers. These figures will be the remainder,
-and the rest of the dividend will be the quotient.
-
- 10)2717316
- --------
- 271731 and rem. 6.
-
-Or we may prove these results thus: from (20), 2717316 is 271731 tens
-and 6; of which the first contains 10 271731 times, and the second not
-at all; the quotient is therefore 271731, and the remainder 6 (72).
-Again (20), 33429 is 334 hundreds and 29; of which the first contains
-100 334 times, and the second not at all; the quotient is therefore
-334, and the remainder 29.
-
-83. The following examples will shew how the rule may be shortened when
-there are ciphers in the divisor. With each example is placed another
-containing the same process, all unnecessary figures being removed; and
-from the comparison of the two, the rule at the end of this article is
-derived.
-
- I. 1782000)6424700000(3605 1782)6424700(3605
- 5346000 5346
- -------- ----
- 10787000 10787
- 10692000 10692
- ---------- -------
- 9500000 9500
- 8910000 8910
- ------- -------
- 590000 590000
-
-
- II. 12300000)42176189300(3428 123)421761(3428
- 36900000 369
- --------- ----
- 52761893 527
- 49200000 492
- --------- ----
- 35618930 356
- 24600000 246
- --------- ----
- 110189300 1101
- 98400000 984
- -------- ----------
- 11789300 11789300
-
-The rule, then, is: Strike out as many _figures_[12] from the right of
-the dividend as there are _ciphers_ at the right of the divisor. Strike
-out all the ciphers from the divisor, and divide in the usual way; but
-at the end of the process place on the right of the remainder all those
-figures which were struck out of the dividend.
-
-[12] Including both ciphers and others.
-
-84. EXERCISES.
-
- Dividend. | Divisor. |Quotient.|Remainder.
- 9694 | 47 | 206 | 12
- 175618 | 3136 | 56 | 2
- 23796484 | 130000 | 183 | 6484
- 14002564 | 1871 | 7484 | 0
- 310314420 | 7878 | 39390 | 0
- 3939040647 | 6889 | 571787 | 4
- 22876792454961 | 43046721 | 531441 | 0
-
-Shew that
-
- 100 × 100 × 100 - 43 × 43 × 43
- I. ------------------------------ = 100 × 100 + 100 × 43 + 43 × 43.
- 100 - 43
-
- 100 × 100 × 100 + 43 × 43 × 43
- II. ------------------------------ = 100 × 100 - 100 × 43 + 43 × 43.
- 100 + 43
-
- 76 × 76 + 2 × 76 × 52 + 52 × 52
- III. -------------------------------- = 76 + 52.
- 76 + 52
-
- 12 × 12 × 12 × 12 - 1
- IV. 1 + 12 + 12 × 12 + 12 × 12 × 12 = ----------------------.
- 12 - 1
-
-What is the nearest number to 1376429 which can be divided by 36300
-without remainder?--_Answer_, 1379400.
-
-If 36 oxen can eat 216 acres of grass in one year, and if a sheep eat
-half as much as an ox, how long will it take 49 oxen and 136 sheep
-together to eat 17550 acres?--_Answer_, 25 years.
-
-85. Take any two numbers, one of which divides the other without
-remainder; for example, 32 and 4. Multiply both these numbers by any
-other number; for example, 6. The products will be 192 and 24. Now,
-192 contains 24 just as often as 32 contains 4. Suppose 6 baskets,
-each containing 32 pebbles, the whole number of which will be 192.
-Take 4 from one basket, time after time, until that basket is empty.
-It is plain that if, instead of taking 4 from that basket, I take 4
-from each, the whole 6 will be emptied together: that is, 6 times 32
-contains 6 times 4 just as often as 32 contains 4. The same reasoning
-applies to other numbers, and therefore _we do not alter the quotient
-if we multiply the dividend and divisor by the same number_.
-
-86. Again, suppose that 200 is to be divided by 50. Divide both the
-dividend and divisor by the same number; for example, 5. Then, 200 is 5
-times 40, and 50 is 5 times 10. But by (85), 40 divided by 10 gives the
-same quotient as 5 times 40 divided by 5 times 10, and therefore _the
-quotient of two numbers is not altered by dividing both the dividend
-and divisor by the same number_.
-
-87. From (55), if a number be multiplied successively by two others, it
-is multiplied by their product. Thus, 27, first multiplied by 5, and
-the product multiplied by 3, is the same as 27 multiplied by 5 times
-3, or 15. Also, if a number be divided by any number, and the quotient
-be divided by another, it is the same as if the first number had been
-divided by the product of the other two. For example, divide 60 by 4,
-which gives 15, and the quotient by 3, which gives 5. It is plain, that
-if each of the four fifteens of which 60 is composed be divided into
-three equal parts, there are twelve equal parts in all; or, a division
-by 4, and then by 3, is equivalent to a division by 4 × 3, or 12.
-
-88. The following rules will be better understood by stating them in
-an example. If 32 be multiplied by 24 and divided by 6, the result is
-the same as if 32 had been multiplied by the quotient of 24 divided
-by 6, that is, by 4; for the sixth part of 24 being 4, the sixth part
-of any number repeated 24 times is that number repeated 4 times; or,
-multiplying by 24 and dividing by 6 is equivalent to multiplying by 4.
-
-89. Again, if 48 be multiplied by 4, and that product be divided by
-24, it is the same thing as if 48 were divided at once by the quotient
-of 24 divided by 4, that is, by 6. For, every unit which is repeated 6
-times in 48 is repeated 4 times as often, or 24 times, in 4 times 48,
-or the quotient of 48 and 6 is the same as the quotient of 48 × 4 and 6
-× 4.
-
-90. The results of the last five articles may be algebraically
-expressed thus:
-
- _ma_ _a_
- ---- = ---- (85)
- _mb_ _b_
-
-If _n_ divide _a_ and _b_ without remainder,
-
- _a_
- ----
- _n_ _a_
- ------ = ---- (86)
- _b_ _b_
- ----
- _n_
-
- _a_
- ----
- _b_ _a_
- ------ = ---- (87)
- _c_ _bc_
-
- _ab_ _b_
- ------ = _a_ × ---- (88)
- _c_ _c_
-
- _ac_ _a_
- ----- = ------ (89)
- _b_ _b_
- ----
- _c_
-
-It must be recollected, however, that these have only been proved in
-the case where all the divisions are without remainder.
-
-91. When one number divides another without leaving any remainder,
-or is contained an exact number of times in it, it is said to be a
-_measure_ of that number, or to _measure_ it. Thus, 4 is a measure of
-136, or measures 136; but it does not measure 137. The reason for
-using the word measure is this: Suppose you have a rod 4 feet long,
-with nothing marked upon it, with which you want to measure some
-length; for example, the length of a street. If that street should
-happen to be 136 feet in length, you will be able to _measure_ it with
-the rod, because, since 136 contains 4 34 times, you will find that the
-street is exactly 34 times the length of the rod. But if the street
-should happen to be 137 feet long, you cannot measure it with the rod;
-for when you have measured 34 of the rods, you will find a remainder,
-whose length you cannot tell without some shorter measure. Hence 4 is
-said to measure 136, but not to measure 137. A measure, then, is a
-divisor which leaves no remainder.
-
-92. When one number is a measure of two others, it is called a _common
-measure_ of the two. Thus, 15 is a common measure of 180 and 75. Two
-numbers may have several common measures. For example, 360 and 168
-have the common measures 2, 3, 4, 6, 24, and several others. Now, this
-question maybe asked: Of all the common measures of 360 and 168, which
-is the greatest? The answer to this question is derived from a rule of
-arithmetic, called the rule for finding the GREATEST COMMON MEASURE,
-which we proceed to consider.
-
-93. If one quantity measure two others, it measures their sum and
-difference. Thus, 7 measures 21 and 56. It therefore measures 56 + 21
-and 56-21, or 77 and 35. This is only another way of saying what was
-said in (74).
-
-94. If one number measure a second, it measures every number which the
-second measures. Thus, 5 measures 15, and 15 measures 30, 45, 60, 75,
-&c.; all which numbers are measured by 5. It is plain that if
-
- 15 contains 5 3 times,
- 30, or 15 + 15 contains 5 3 + 3 times, or 6 times,
- 45, or 15 + 15 + 15 contains 5 3 + 3 + 3 or 9 times;
-
-and so on.
-
-95. Every number which measures both the dividend and divisor measures
-the remainder also. To shew this, divide 360 by 112. The quotient is
-3, and the remainder 24, that is (72) 360 is three times 112 and 24,
-or 360 = 112 × 3 + 24. From this it follows, that 24 is the difference
-between 360 and 3 times 112, or 24 = 360-112 × 3. Take any number which
-measures both 360 and 112; for example, 4. Then
-
- 4 measures 360,
- 4 measures 112, and therefore (94) measures 112 × 3,
- or 112 + 112 + 112.
-
-Therefore (93) it measures 360-112 × 3, which is the remainder 24. The
-same reasoning may be applied to all other measures of 360 and 112; and
-the result is, that every quantity which measures both the dividend and
-divisor also measures the remainder. Hence, every _common measure_ of
-a dividend and divisor is also a _common measure_ of the divisor and
-remainder.
-
-96. Every common measure of the divisor and remainder is also a
-common measure of the dividend and divisor. Take the same example,
-and recollect that 360 = 112 × 3 + 24. Take any common measure of the
-remainder 24 and the divisor 112; for example, 8. Then
-
- 8 measures 24;
- and 8 measures 112, and therefore (94) measures 112 × 3.
-
-Therefore (93) 8 measures 112 × 3 + 24, or measures the dividend 360.
-Then every common measure of the remainder and divisor is also a common
-measure of the divisor and dividend, or there is no common measure of
-the remainder and divisor which is not also a common measure of the
-divisor and dividend.
-
-97. I. It is proved in (95) that the remainder and divisor have all the
-common measures which are in the dividend and divisor.
-
-II. It is proved in (96) that they have no others.
-
-It therefore follows, that the greatest of the common measures of the
-first two is the greatest of those of the second two, which shews how
-to find the greatest common measure of any two numbers,[13] as follows:
-
-98. Take the preceding example, and let it be required to find the g.
-c. m. of 360 and 112, and observe that
-
- 360 divided by 112 gives the remainder 24,
- 112 divided by 24 gives the remainder 16,
- 24 divided by 16 gives the remainder 8,
- 16 divided by 8 gives no remainder.
-
-[13] For shortness, I abbreviate the words _greatest common measure_
-into their initial letters, g. c. m.
-
-Now, since 8 divides 16 without remainder, and since it also divides
-itself without remainder, 8 is the g. c. m. of 8 and 16, because it is
-impossible to divide 8 by any number greater than 8; so that, even if
-16 had a greater measure than 8, it could not be _common_ to 16 and 8.
-
- Therefore 8 is g. c. m. of 16 and 8,
- (97) g. c. m. of 16 and 8 is g. c. m. of 24 and 16,
- g. c. m. of 24 and 16 is g. c. m. of 112 and 24,
- g. c. m. of 112 and 24 is g. c. m. of 360 and 112,
- Therefore 8 is g. c. m. of 360 and 112.
-
-The process carried on may be written down in either of the following
-ways:
-
- 112)360(3
- 336
- ---
- 24)112(4 112 | 360 3
- 96 96 | 336 4
- --- ----+-------
- 16)24(1 16 | 24 1
- 16 16 | 16 2
- -- ----+-------
- 8)16(2 0 | 8
- 16
- --
- 0
-
-The rule for finding the greatest common measure of two numbers is,
-
-I. Divide the greater of the two by the less.
-
-II. Make the remainder a divisor, and the divisor a dividend, and find
-another remainder.
-
-III. Proceed in this way until there is no remainder, and the last
-divisor is the greatest common measure required.
-
-99. You may perhaps ask how the rule is to shew when the two numbers
-have no common measure. The fact is, that there are, strictly speaking,
-no such numbers, because all numbers are measured by 1; that is,
-contain an exact number of units, and therefore 1 is a common measure
-of every two numbers. If they have no other common measure, the last
-divisor will be 1, as in the following example, where the greatest
-common measure of 87 and 25 is found.
-
- 25)87(3
- 75
- --
- 12)25(2
- 24
- --
- 1)12(12
- 12
- --
- 0
-
-EXERCISES.
-
- Numbers. g. c. m.
- 6197 9521 1
- 58363 2602 1
- 5547 147008443 1849
- 6281 326041 571
- 28915 31495 5
- 1509 300309 3
-
- What are 36 × 36 + 2 × 36 × 72 + 72 × 72
- and 36 × 36 × 36 + 72 × 72 × 72;
-
-and what is their greatest common measure?--_Answer_, 11664.
-
-100. If two numbers be divisible by a third, and if the quotients be
-again divisible by a fourth, that third is not the greatest common
-measure. For example, 360 and 504 are both divisible by 4. The
-quotients are 90 and 126. Now 90 and 126 are both divisible by 9,
-the quotients of which division are 10 and 14. By (87), dividing a
-number by 4, and then dividing the quotient by 9, is the same thing
-as dividing the number itself by 4 × 9, or by 36. Then, since 36 is
-a common measure of 360 and 504, and is greater than 4, 4 is not the
-greatest common measure. Again, since 10 and 14 are both divisible by
-2, 36 is not the greatest common measure. It therefore follows, that
-when two numbers are divided by their greatest common measure, the
-quotients have no common measure except 1 (99). Otherwise, the number
-which was called the greatest common measure in the last sentence is
-not so in reality.
-
-101. To find the greatest common measure of three numbers, find the g.
-c. m. of the first and second, and of this and the third. For since
-all common divisors of the first and second are contained in their g.
-c. m., and no others, whatever is common to the first, second, and
-third, is common also to the third and the g. c. m. of the first and
-second, and no others. Similarly, to find the g. c. m. of four numbers,
-find the g. c. m. of the first, second, and third, and of that and the
-fourth.
-
-102. When a first number contains a second, or is divisible by it
-without remainder, the first is called a multiple of the second. The
-words _multiple_ and _measure_ are thus connected: Since 4 is a
-measure of 24, 24 is a multiple of 4. The number 96 is a multiple of
-8, 12, 24, 48, and several others. It is therefore called a _common
-multiple_ of 8, 12, 24. 48, &c. The product of any two numbers is
-evidently a common multiple of both. Thus, 36 × 8, or 288, is a common
-multiple of 36 and 8. But there are common multiples of 36 and 8 less
-than 288; and because it is convenient, when a common multiple of two
-quantities is wanted, to use the least of them, I now shew how to find
-the least common multiple of two numbers.
-
-103. Take, for example, 36 and 8. Find their greatest common measure,
-which is 4, and observe that 36 is 9 × 4, and 8 is 2 × 4. The quotients
-of 36 and 8, when divided by their greatest common measure, are
-therefore 9 and 2. Multiply these quotients together, and multiply the
-product by the greatest common measure, 4, which gives 9 × 2 × 4, or
-72. This is a multiple of 8, or of 4 × 2 by (55); and also of 36 or of
-4 × 9. It is also the least common multiple; but this cannot be proved
-to you, because the demonstration cannot be thoroughly understood
-without more practice in the use of letters to stand for numbers. But
-you may satisfy yourself that it is the least in this case, and that
-the same process will give the least common multiple in any other case
-which you may take. It is not even necessary that you should know it is
-the least. Whenever a common multiple is to be used, any one will do as
-well as the least. It is only to avoid large numbers that the least is
-used in preference to any other.
-
-When the greatest common measure is 1, the least common multiple of the
-two numbers is their product.
-
-The rule then is: To find the least common multiple of two numbers,
-find their greatest common measure, and multiply one of the numbers by
-the quotient which the other gives when divided by the greatest common
-measure. To find the least common multiple of three numbers, find the
-least common multiple of the first two, and find the least common
-multiple of that multiple and the third, and so on.
-
-EXERCISES.
-
- Numbers proposed. | Least common multiple.
- 14, 21 | 42
- 16, 5, 24 | 240
- 1, 2, 3, 4, 5, 6, 7, 8, 9, 10 | 2520
- 6, 8, 11, 16, 20 | 2640
- 876, 864 | 63072
- 868, 854 | 52948
-
-A convenient mode of finding the least common multiple of several
-numbers is as follows, when the common measures are easily visible:
-Pick out a number of common measures of two or more, which have
-themselves no divisors greater than unity. Write them as divisors,
-and divide every number which will divide by one or more of them.
-Bring down the quotients, and also the numbers which will not divide
-by any of them. Repeat the process with the results, and so on until
-the numbers brought down have no two of them any common measure except
-unity. Then, for the least common multiple, multiply all the divisors
-by all the numbers last brought down. For instance, let it be required
-to find the least common multiple of all the numbers from 11 to 21.
-
- 2, 2, 3, 5, 7)11 12 13 14 15 16 17 18 19 20 21
- ---------------------------------
- 11 1 13 1 1 4 17 3 19 1 1
-
-There are now no common measures left in the row, and the least common
-multiple required is the product of 2, 2, 3, 5, 7, 11, 13, 4, 17, 3,
-and 19; or 232792560.
-
-
-
-
-SECTION V.
-
-FRACTIONS.
-
-
-104. Suppose it required to divide 49 yards into five equal parts, or,
-as it is called, to find the fifth part of 49 yards. If we divide 45 by
-5, the quotient is 9, and the remainder is 4; that is (72), 49 is made
-up of 5 times 9 and 4. Let the line A B represent 49 yards:
-
- A----------------------------------------B
- C-------------- I --
- D-------------- K --
- E-------------- L --
- F-------------- M --
- G-------------- N --
-
- I K L M N
- H +-+-+-+-+-+
- | | | | | |
-
-Take 5 lines, C, D, E, F, and G, each 9 yards in length, and the line
-H, 4 yards in length. Then, since 49 is 5 nines and 4, C, D, E, F, G,
-and H, are together equal to A B. Divide H, which is 4 yards, into five
-equal parts, I, K, L, M, and N, and place one of these parts opposite
-to each of the lines, C, D, E, F, and G. It follows that the ten lines,
-C, D, E, F, G, I, K, L, M, N, are together equal to A B, or 49 yards.
-Now D and K together are of the same length as C and I together, and
-so are E and L, F and M, and G and N. Therefore, C and I together,
-repeated 5 times, will be 49 yards; that is, C and I together make up
-the fifth part of 49 yards.
-
-105. C is a certain number of yards, viz. 9; but I is a new sort of
-quantity, to which hitherto we have never come. It is not an exact
-number of yards, for it arises from dividing 4 yards into 5 parts, and
-taking one of those parts. It is the fifth part of 4 yards, and is
-called a FRACTION of a yard. It is written thus, ⁴/₅(23), and is what
-we must add to 9 yards in order to make up the fifth part of 49 yards.
-
-The same reasoning would apply to dividing 49 bushels of corn, or 49
-acres of land, into 5 equal parts. We should find for the fifth part
-of the first, 9 bushels and the fifth part of 4 bushels; and for the
-second, 9 acres and the fifth part of 4 acres.
-
-We say, then, once for all, that the fifth part of 49 is 9 and ⁴/₅, or
-9 + ⁴/₅; which is usually written (9⁴/₅), or if we use signs, 49/5 =
-(9⁴/₅).
-
-
-EXERCISES.
-
-What is the seventeenth part of 1237?--_Answer_, (72-¹³/₁₇).
-
- 10032 663819 22773399
- What are -----, ------, and -------- ?
- 1974 23710 2424
-
- 162 23649 2343
- _Answer_, (5 ----), (27 -----), (9394 ----).
- 1974 23710 2424
-
-106. By the term fraction is understood a part of any number, or the
-sum of any of the equal parts into which a number is divided. Thus,
-⁴⁹/₅, ⁴/₅, ²⁰/₇, are fractions. The term fraction even includes whole
-numbers:[14] for example, 17 is ¹⁷/₁, ³⁴/₂, ⁵¹/₃, &c.
-
-[14] Numbers which contain an exact number of units, such as 5, 7,
-100, &c., are called _whole numbers_ or _integers_, when we wish to
-distinguish them from fractions.
-
-The upper number is called the _numerator_, the lower number is
-called the _denominator_, and both of these are called _terms_ of the
-fraction. As long as the numerator is less than the denominator, the
-fraction is less than a unit: thus, ⁶/₁₇ is less than a unit; for 6
-divided into 6 parts gives 1 for each part, and must give less when
-divided into 17 parts. Similarly, the fraction is equal to a unit when
-the numerator and denominator are equal, and greater than a unit when
-the numerator is greater than the denominator.
-
-107. By ⅔ is meant the third part of 2. This is the same as twice the
-third part of 1.
-
-To prove this, let A B be two yards, and divide each of the yards A C
-and C B into three equal parts.
-
- |--|--|--|--|--|--|
- A D E C F G B
-
-Then, because A E, E F, and F B, are all equal to one another, A E is
-the third part of 2. It is therefore ⅔. But A E is twice A D, and A
-D is the third part of one yard, or ⅓; therefore ⅔ is twice ⅓; that
-is, in order to get the length ⅔, it makes no difference whether we
-divide _two_ yards at once into three parts, and take _one_ of them,
-or whether we divide _one_ yard into three parts, and take _two_ of
-them. By the same reasoning, ⅝ may be found either by dividing 5 into
-8 parts, and taking one of them, or by dividing 1 into 8 parts, and
-taking five of them. In future, of these two meanings I shall use that
-which is most convenient at the time, as it is proved that they are
-the same thing. This principle is the same as the following: The third
-part of any number may be obtained by adding together the thirds of all
-the units of which it consists. Thus, the third part of 2, or of two
-units, is made by taking one-third out of each of the units, that is,
-
- ⅔ = ⅓ × 2.
-
-This meaning appears ambiguous when the numerator is greater than the
-denominator: thus, ¹⁵/₇ would mean that 1 is to be divided into 7
-parts, and 15 of them are to be taken. We should here let as many units
-be each divided into 7 parts as will give more than 15 of those parts,
-and take 15 of them.
-
-108. The value of a fraction is not altered by multiplying the
-numerator and denominator by the same quantity. Take the fraction ¾,
-multiply its numerator and denominator by 5, and it becomes ¹⁵/₂₀,
-which is the same thing as ¾; that is, one-twentieth part of 15 yards
-is the same thing as one-fourth of 3 yards: or, if our second meaning
-of the word fraction be used, you get the same length by dividing a
-yard into 20 parts and taking 15 of them, as you get by dividing it
-into 4 parts and taking 3 of them. To prove this,
-
-[Illustration]
-
-let A B represent a yard; divide it into 4 equal parts, A C, C D, D E,
-and E B, and divide each of these parts into 5 equal parts. Then A E is
-¾. But the second division cuts the line into 20 equal parts, of which
-A E contains 15. It is therefore ¹⁵/₂₀. Therefore, ¹⁵/₂₀ and ¾ are the
-same thing.
-
-Again, since ¾ is made from ¹⁵/₂₀ by dividing both the numerator
-and denominator by 5, the value of a fraction is not altered by
-dividing both its numerator and denominator by the same quantity. This
-principle, which is of so much importance in every part of arithmetic,
-is often used in common language, as when we say that 14 out of 21 is 2
-out of 3, &c.
-
-109. Though the two fractions ¾ and ¹⁵/₂₀ are the same in value,
-and either of them may be used for the other without error, yet the
-first is more convenient than the second, not only because you have a
-clearer idea of the fourth of three yards than of the twentieth part
-of fifteen yards, but because the numbers in the first being smaller,
-are more convenient for multiplication and division. It is therefore
-useful, when a fraction is given, to find out whether its numerator
-and denominator have any common divisors or common measures. In (98)
-was given a rule for finding the greatest common measure of any two
-numbers; and it was shewn that when the two numbers are divided by
-their greatest common measure, the quotients have no common measure
-except 1. Find the greatest common measure of the terms of the
-fraction, and divide them by that number. The fraction is then said to
-be _reduced to its lowest terms_, and is in the state in which the best
-notion can be formed of its magnitude.
-
-EXERCISES.
-
-With each fraction is written the same reduced to its lowest terms.
-
- 2794 22 × 127 22
- ---- = ---------- = ----
- 2921 23 × 127 23
-
- 2788 17 × 164 17
- ---- = ---------- = ----
- 4920 30 × 164 30
-
- 93208 764 × 122 764
- ----- = ---------- = ---
- 13786 113 × 122 113
-
- 888800 22 × 40400 22
- -------- = ------------ = -----
- 40359600 999 × 40400 999
-
- 95469 121 × 789 121
- ------ = ----------- = ---
- 359784 456 × 789 456
-
-110. When the terms of the fraction given are already in factors,[15]
-any one factor in the numerator may be divided by a number, provided
-some one factor in the denominator is divided by the same. This follows
-from (88) and (108). In the following examples the figures altered by
-division are accented.
-
-[15] A factor of a number is a number which divides it without
-remainder: thus, 4, 6, 8, are factors of 24, and 6 × 4, 8 × 3, 2 × 2 ×
-2 × 3, are several ways of decomposing 24 into factors.
-
- 12 × 11 × 10 3′ × 11 × 10 1′ × 11 × 5′
- ------------ = ------------- = ------------- = 55.
- 2 × 3 × 4 2 × 3 × 1′ 1′ × 1′ × 1′
-
- 18 × 15 × 13 2′ × 3′ × 1′ 1′ × 1′ × 1′
- ------------ = ------------- = ------------- = ¹/₁₆.
- 20 × 54 × 52 4′ × 6′ × 4′ 2′ × 2′ × 4′
-
- 27 × 28 3′ × 4′ 3′ × 2′
- ------- = --------- = -------- = ⁶/₅.
- 9 × 70 1′ × 10′ 1′ × 5′
-
-111. As we can, by (108), multiply the numerator and denominator of a
-fraction by any number, without altering its value, we can now readily
-reduce two fractions to two others, which shall have the same value as
-the first two, and which shall have the same denominator. Take, for
-example, ⅔ and ⁴/₇; multiply both terms of ⅔ by 7, and both terms of
-⁴/₇ by 3. It then appears that
-
- 2 × 7
- ⅔ is ------- or ¹⁴/₂₁
- 3 × 7
-
- 4 × 3
- ⁴/₇ is ------- or ¹²/₂₁.
- 7 × 3
-
-Here are then two fractions ¹⁴/₂₁ and ¹²/₂₁, equal to ⅔ and ⁴/₇, and
-having the same denominator, 21; in this case, ⅔ and ⁴/₇ are said to be
-_reduced to a common denominator_.
-
-It is required to reduce ⅒, ⅚, and ⁷/₉ to a common denominator.
-Multiply both terms of the first by the product of 6 and 9; of the
-second by the product of 10 and 9; and of the third by the product of
-10 and 6. Then it appears (108) that
-
- 1 × 6 × 9
- ⅒ is ----------- or ⁵⁴/₅₄₀
- 10 × 6 × 9
-
- 5 × 10 × 9
- ⅚ is ------------ or ⁴⁵⁰/₅₄₀
- 6 × 10 × 9
-
- 7 × 10 × 6
- ⁷/₉ is ------------ or ⁴²⁰/₅₄₀.
- 9 × 10 × 6
-
-On looking at these last fractions, we see that all the numerators and
-the common denominator are divisible by 6, and (108) this division will
-not alter their values. On dividing the numerators and denominators of
-⁵⁴/₅₄₀, ⁴⁵⁰/₅₄₀, and ⁴²⁰/₅₄₀ by 6, the resulting fractions are, ⁹/₉₀,
-⁷⁵/₉₀, and ⁷⁰/₉₀. These are fractions with a common denominator, and
-which are the same as ⅒, ⅚, and ⁷/₉; and therefore these are a more
-simple answer to the question than the first fractions. Observe also
-that 540 is one common multiple of 10, 6, and 9, namely, 10 × 6 × 9,
-but that 90 is _the least_ common multiple of 10, 6, and 9 (103). The
-following process, therefore, is better. To reduce the fractions ⅒,
-⅚, and ⁷/₉, to others having the same value and a common denominator,
-begin by finding the least common multiple of 10, 6, and 9, by the rule
-in (103), which is 90. Observe that 10, 6, and 9 are contained in 90 9,
-15, and 10 times. Multiply both terms of the first by 9, of the second
-by 15, and of the third by 10, and the fractions thus produced are
-⁹/₉₀, ⁷⁵/₉₀, and ⁷⁰/₉₀, the same as before.
-
-If one of the numbers be a whole number, it may be reduced to a
-fraction having the common denominator of the rest, by (106).
-
-EXERCISES.
-
- Fractions proposed reduced to a common denominator.
-
- 2 1 1 | 20 6 5
- --- --- --- | ---- --- ---
- 3 5 6 | 30 30 30
- |
- |
- 1 2 3 12 3 | 28 24 18 48 63
- --- --- --- ---- --- | --- --- --- --- ---
- 3 7 14 21 4 | 84 84 84 84 84
- |
- 4 5 6 | 3000 400 50 6
- 3 --- ---- ---- | ---- ----- ----- ----
- 10 100 1000 | 1000 1000 1000 1000
- |
- 33 281 | 22341 106499
- ---- ---- | -------- ------
- 379 677 | 256583 256583
-
-112. By reducing two fractions to a common denominator, we are able
-to compare them; that is, to tell which is the greater and which the
-less of the two. For example, take ½ and ⁷/₁₅. These fractions reduced,
-without alteration of their value, to a common denominator, are ¹⁵/₃₀
-and ¹⁴/₃₁. Of these the first must be the greater, because (107) it may
-be obtained by dividing 1 into 30 equal parts and taking 15 of them,
-but the second is made by taking 14 of those parts.
-
-It is evident that of two fractions which have the same denominator,
-the greater has the greater numerator; and also that of two fractions
-which have the same numerator, the greater has the less denominator.
-Thus, ⁸/₇ is greater than ⁸/⁹, since the first is a 7th, and the
-last only a 9th part of 8. Also, any numerator may be made to belong
-to as small a fraction as we please, by sufficiently increasing the
-denominator. Thus, ¹⁰/₁₀₀ is ¹/₁₀, ¹⁰/₁₀₀₀ is ¹/₁₀₀, and ¹⁰/₁₀₀₀₀₀₀ is
-¹/₁₀₀₀₀₀₀ (108).
-
-We can now also increase and diminish the first fraction by the second.
-For the first fraction is made up of 15 of the 30 equal parts into
-which 1 is divided. The second fraction is 14 of those parts. The sum
-of the two, therefore, must be 15 + 14, or 29 of those parts; that is,
-½ + ⁷/₁₅ is ²⁹/₃₀. The difference of the two must be 15-14, or 1 of
-those parts; that is, ½-⁷/₁₅ = ¹/₃₀.
-
-113. From the last two articles the following rules are obtained:
-
-I. To compare, to add, or to subtract fractions, first reduce them to
-a common denominator. When this has been done, that is the greatest of
-the fractions which has the greatest numerator.
-
-Their sum has the sum of the numerators for its numerator, and the
-common denominator for its denominator.
-
-Their difference has the difference of the numerators for its
-numerator, and the common denominator for its denominator.
-
-
-EXERCISES.
-
- 1 1 1 1 53 44 153 18329
- --- + --- + --- - --- = ---- ---- - ----- = -------
- 2 3 4 5 60 3 427 1282
-
- 8 3 4 1834 1 12 253
- 1 + ---- + ---- + ---- = ---- 2 - --- + ---- = ----
- 10 100 1000 1000 7 13 91
-
- 1 8 94 3 163 97 93066
- --- + --- + ---- = --- --- - ---- = -------
- 2 16 188 2 521 881 459001
-
-114. Suppose it required to add a whole number to a fraction, for
-example, 6 to ⁴/₉. By (106) 6 is ⁵⁴/₉, and ⁵⁴/₉ + ⁴/₉ is ⁵⁸/⁹; that is,
-6 + ⁴/⁹, or as it is usually written, (6⁴/₉), is ⁵⁸/₉. The rule in this
-case is: Multiply the whole number by the denominator of the fraction,
-and to the product add the numerator of the fraction; the sum will be
-the numerator of the result, and the denominator of the fraction will
-be its denominator. Thus, (3¼) = ¹³/₄, (22⁵/₉) = ²⁰³/₉, (74²/₅₅) =
-⁴⁰⁷²/₅₅. This rule is the opposite of that in (105).
-
-115. From the last rule it appears that
-
- 907 17230907 225 667225
- 1723 ------ is --------, 667 ----- is ------,
- 10000 10000 1000 1000
-
- 99 2300099
- and 23 ------ is -------.
- 10000 10000
-
-Hence, when a whole number is to be added to a fraction whose
-denominator is 1 followed by _ciphers_, the number of which is not less
-than the number of _figures_ in the numerator, the rule is: Write the
-whole number first, and then the numerator of the fraction, with as
-many ciphers between them as the number of _ciphers_ in the denominator
-exceeds the number of _figures_ in the numerator. This is the numerator
-of the result, and the denominator of the fraction is its denominator.
-If the number of ciphers in the denominator be equal to the number of
-figures in the numerator, write no ciphers between the whole number and
-the numerator.
-
-EXERCISES.
-
-Reduce the following mixed quantities to fractions:
-
- 23707 6 299 2210
- 1 ------, 2457 ---, 1207 --------, and 233 -----.
- 100000 10 10000000 10000
-
-116. Suppose it required to multiply ⅔ by 4. This by (48) is taking ⅔
-four times; that is, finding ⅔ + ⅔ + ⅔ + ⅔. This by (112) is ⁸/₃; so
-that to multiply a fraction by a whole number the rule is: Multiply the
-numerator by the whole number, and let the denominator remain.
-
-117. If the denominator of the fraction be divisible by the whole
-number, the rule may be stated thus: Divide the denominator of the
-fraction by the whole number, and let the numerator remain. For
-example, multiply ⁷/₃₆ by 6. This (116) is ⁴²/₃₆, which, since the
-numerator and denominator are now divisible by 6, is (108) the same as
-⁷/₆. It is plain that ⁷/₆ is made from ⁷/₃₆ in the manner stated in the
-rule.
-
-118. Multiplication has been defined to be the taking as many of one
-number as there are units in another. Thus, to multiply 12 by 7 is to
-take as many twelves as there are units in 7, or to take 12 as many
-times as you must take 1 in order to make 7. Thus, what is done with 1
-in order to make 7, is done with 12 to make 7 times 12. For example,
-
- 7 is 1 + 1 + 1 + 1 + 1 + 1 + 1
- 7 times 12 is 12 + 12 + 12 + 12 + 12 + 12 + 12.
-
-When the same thing is done with two fractions, the result is still
-called their product, and the process is still called multiplication.
-There is this difference, that whereas a whole number is made by adding
-1 to itself a number of times, a fraction is made by dividing 1 into
-a number of equal parts, and adding _one of these parts_ to itself a
-number of times. This being the meaning of the word multiplication,
-as applied to fractions, what is ¾ multiplied by ⅞? Whatever is done
-with 1 in order to make ⅞ must now be done with ¾; but to make ⅞, 1 is
-divided into 8 parts, and 7 of them are taken. Therefore, to make ¾ ×
-⅞, ¾ must be divided into 8 parts, and 7 of them must be taken. Now ¾
-is, by (108), the same thing as ²⁴/₃₂. Since ²⁴/₃₂ is made by dividing
-1 into 32 parts, and taking 24 of them, or, which is the same thing,
-taking 3 of them 8 times, if ²⁴/₃₂ be divided into 8 equal parts, each
-of them is ³/₃₂; and if 7 of these parts be taken, the result is ²¹/₃₂
-(116): therefore ¾ multiplied by ⅞ is ²¹/₃₂; and the same reasoning
-may be applied to any other fractions. But ²¹/₃₂ is made from ¾ and ⅞
-by multiplying the two numerators together for the numerator, and the
-two denominators for the denominator; which furnishes a rule for the
-multiplication of fractions.
-
-119. If this product ²¹/₃₂ is to be multiplied by a third fraction, for
-example, by ⁵/₉, the result is, by the same rule, ¹⁰⁵/₂₈₈; and so on.
-The general rule for multiplying any number of fractions together is
-therefore:
-
-Multiply all the numerators together for the numerator of the product,
-and all the denominators together for its denominator.
-
-120. Suppose it required to multiply together ¹⁵/₁₆ and ⁸/₁₀. The
-product may be written thus:
-
- 15 × 8 120
- -------, and is ----,
- 16 × 10 160
-
-which reduced to its lowest terms (109) is ¾. This result might have
-been obtained directly, by observing that 15 and 10 are both measured
-by 5, and 8 and 16 are both measured by 8, and that the fraction may be
-written thus:
-
- 3 × 5 × 8
- -------------.
- 2 × 8 × 2 × 5
-
-Divide both its numerator and denominator by 5 × 8 (108) and (87),
-and the result is at once ¾; therefore, before proceeding to multiply
-any number of fractions together, if there be any numerator and any
-denominator, whether belonging to the same fraction or not, which have
-a common measure, divide them both by that common measure, and use the
-quotients instead of the dividends.
-
-A whole number may be considered as a fraction whose denominator is 1;
-thus, 16 is ¹⁶/₁ (106); and the same rule will apply when one or more
-of the quantities are whole numbers.
-
-EXERCISES
-
- 136 268 36448 18224
- ---- × --- = ------- = -------
- 7470 919 6864930 3432465
-
- 1 2 3 4 1 2 17 2
- --- × --- × --- × --- = --- ---- × ---- = ----
- 2 3 4 5 5 17 45 45
-
- 2 13 241 6266 13 601 7813
- --- × ---- × ---- = ------ ---- × ---- = -----
- 59 7 19 7847 461 11 5071
-
-
- Fraction proposed. Square. Cube.
- 701 491401 344472101
- ----- ------- ---------
- 158 24964 3944312
-
- 140 19600 2744000
- ----- ------ --------
- 141 19881 2803221
-
- 355 126025 44738875
- ----- ------- ---------
- 113 12769 1442897
-
-From 100 acres of ground, two-thirds of them are taken away; 50 acres
-are then added to the result, and ⁵/₇ of the whole is taken; what
-number of acres does this produce?--_Answer_, (59¹¹/₂₁).
-
-121. In dividing one whole number by another, for example, 108 by 9,
-this question is asked,--Can we, by the addition of any number of
-nines, produce 108? and if so, how many nines will be sufficient for
-that purpose?
-
-Suppose we take two fractions, for example, ⅔ and ⅘, and ask, Can we,
-by dividing ⅘ into some number of equal parts, and adding a number of
-these parts together, produce ⅔? if so, into _how many parts_ must we
-divide ⅘, and _how many of them_ must we add together? The solution of
-this question is still called the division of ⅔ by ⅘; and the fraction
-whose denominator is the number of parts into which ⅘ is divided, and
-whose numerator is the number of them which is taken, is called the
-quotient. The solution of this question is as follows: Reduce both
-these fractions to a common denominator (111), which does not alter
-their value (108); they then become ¹⁰/₁₅ and ¹²/₁₅. The question
-now is, to divide ¹²/₁₅ into a number of parts, and to produce ¹⁰/₁₅
-by taking a number of these parts. Since ¹²/₁₅ is made by dividing 1
-into 15 parts and taking 12 of them, if we divide ¹²/₁₅ into 12 equal
-parts, each of these parts is ¹/₁₅; if we take 10 of these parts, the
-result is ¹⁰/₁₅. Therefore, in order to produce ¹⁰/₁₅ or ⅔ (108), we
-must divide ¹²/₁₅ or ⅘ into 12 parts, and take 10 of them; that is, the
-quotient is ¹⁰/₁₂. If we call ⅔ the dividend, and ⅘ the divisor, as
-before, the quotient in this case is derived from the following rule,
-which the same reasoning will shew to apply to other cases:
-
-The numerator of the quotient is the numerator of the dividend
-multiplied by the denominator of the divisor. The denominator of the
-quotient is the denominator of the dividend multiplied by the numerator
-of the divisor. This rule is the reverse of multiplication, as will be
-seen by comparing what is required in both cases. In multiplying ⅘ by
-¹⁰/₁₂, I ask, if out of ⅘ be taken 10 parts out of 12, how much _of a
-unit_ is taken, and the answer is ⁴⁰/⁶⁰, or ⅔. Again, in dividing ⅔ by
-⅘, I ask what part of ⅘ is ⅔, the answer to which is ¹⁰/₁₂.
-
-122. By taking the following instance, we shall see that this rule can
-be sometimes simplified. Divide ¹⁶/₃₃ by ²⁸/₁₅. Observe that 16 is 4 ×
-4, and 28 is 4 × 7; 33 is 3 × 11, and 15 is 3 × 5; therefore the two
-fractions are
-
- 4 × 4 4 × 7
- ------ and -----,
- 3 × 11 3 × 5
-
-and their quotient, according to the rule, is
-
- 4 × 4 × 3 × 5
- --------------,
- 3 × 11 × 4 × 7
-
-in which 4 × 3 is found both in the numerator and denominator. The
-fraction is therefore (108) the same as
-
- 4 × 5 20
- ------, or ----.
- 11 × 7 77
-
-The rule of the last article, therefore, admits of this modification:
-If the two numerators or the two denominators have a common measure,
-divide by that common measure, and use the quotients instead of the
-dividends.
-
-123. In dividing a fraction by a whole number, for example, ⅔ by 15,
-consider 15 as the fraction ¹⁵/₁. The rule gives ²/⁴⁵ as the quotient.
-Therefore, to divide a fraction by a whole number, multiply the
-denominator by that whole number.
-
-EXERCISES.
-
- Dividend. Divisor. Quotient.
-
- 41 63 41
- ---- ---- -----
- 33 11 189
-
- 467 907 47167
- ---- ---- -------
- 151 101 136957
-
- 7813 601 13
- ----- ---- ----
- 5071 11 461
-
- ¹/₅ × ¹/₅ × ¹/₅ - ²/₁₇× ²/₁₇ × ²/₁₇
- What are -----------------------------------,
- ¹/₅ - ²/₁₇
-
- and ⁸/₁₁ × ⁸/₁₁ - ³/₁₁ × ³/₁₁
- ----------------------- ?
- ⁸/₁₁ - ³/₁₁
-
- 559
- _Answer_, ----, and 1.
- 7225
-
-A can reap a field in 12 days, B in 6, and C in 4 days; in what time
-can they all do it together?[16]--_Answer_, 2 days.
-
-[16] The method of solving this and the following question may be shewn
-thus: If the number of days in which each could reap the field is
-given, the part which each could do in a day by himself can be found,
-and thence the part which all could do together; this being known, the
-number of days which it would take all to do the whole can be found.
-
-In what time would a cistern be filled by cocks which would separately
-fill it in 12, 11, 10, and 9 hours?--_Answer_, (2⁴⁵⁴/₇₆₃) hours.
-
-124. The principal results of this section may be exhibited
-algebraically as follows; let _a_, _b_, _c_, &c. stand for any whole
-numbers. Then
-
- _a_ 1 _a_ _ma_
- (107) ---- = ---- × _a_ (108) ---- = ----
- _b_ _b_ _b_ _mb_
-
- _a_ _c_ _ad_ _bc_
- (111) --- and --- are the same as ---- and ----
- _b_ _d_ _bd_ _bd_
-
- _a_ _b_ _a_ + _b_
- (112) --- + --- = ---------
- _c_ _c_ _c_
-
- _a_ _b_ _a_ - _b_
- --- - --- = ---------
- _c_ _c_ _c_
-
- _a_ _c_ _ad_ + _bc_
- (113) --- + --- = -----------
- _b_ _d_ _bd_
-
- _a_ _c_ _ad_ - _bc_
- --- - --- = -----------
- _b_ _d_ _bd_
-
- _a_ _c_ _ac_
- (118) --- × --- = ----
- _b_ _d_ _bd_
-
- _a_ _c_ _a_/_b_ _ad_
- (121) --- divᵈ. by --- or --------- = ----
- _b_ _d_ _c_/_d_ _bc_
-
-125. These results are true even when the letters themselves represent
-fractions. For example, take the fraction
-
- _a_/_b_
- -------,
- _c_/_d_
-
-whose numerator and denominator are fractional, and multiply its
-numerator and denominator by the fraction
-
- _e_ _ae_/_bf_
- ---, which gives ----------,
- _f_ _ce_/_df_
-
- _aedf_
- which (121) is -------,
- _bfce_
-
-which, dividing the numerator and denominator by _ef_ (108), is
-
- _ad_
- ----.
- _bc_
-
-But the original fraction itself is
-
- _ad_ _a_/_b_ (_a_/_b_) × (_e_/_f_)
- ----; hence ------- = ---------------------
- _bc_ _c_/_d_ (_c_/_d_) × (_e_/_f_)
-
-which corresponds to the second formula[17] in (124). In a similar
-manner it may be shewn, that the other formulæ of the same article
-are true when the letters there used either represent fractions, or
-are removed and fractions introduced in their place. All formulæ
-established throughout this work are equally true when fractions are
-substituted for whole numbers. For example (54), (_m_ + _n_)_a_ = _ma_
-+ _na_. Let _m_, _n_, and _a_ be respectively the fractions
-
- _p_ _r_ _b_
- ---, ---, and ---.
- _q_ _s_ _c_
-
-Then _m_ + _n_ is
-
- _p_ _r_ _ps_ + _qr_
- --- + ---, or -----------
- _q_ _s_ _qs_
-
-and (_m_ + _n_)_a_ is
-
- _ps_ + _qr_ _b_ (_ps_ + _qr_)_b_
- ----------- × ---, or ----------------
- _qs_ _c_ _qsc_
-
- _psb_ + _qrb_
- or -------------.
- _qsc_
-
- _psb_ _qrb_ _pb_ _rb_
- But this (112) is ----- + -----, which is ---- + ----,
- _qsc_ _qsc_ _qc_ _sc_
-
- _psb_ _pb_ _qrb_ _rb_
- since ----- = ----, and ----- = ---- (103).
- _qsc_ _qc_ _qsc_ _sc_
-
- _pb_ _p_ _b_ _rb_ _r_ _b_
- But ---- = --- × ---, and ---- = --- × ---.
- _qc_ _q_ _c_ _sc_ _s_ _c_
-
-Therefore (_m_ + _n_)_a_, or
-
- (_p_ _r_ )_b_ _p_ _b_ _r_ _b_
- (--- + --- )--- = --- × --- + --- × ---.
- (_q_ _s_ )_c_ _q_ _c_ _s_ _c_
-
-In a similar manner the same may be proved of any other formula.
-
-[17] A formula is a name given to any algebraical expression which is
-commonly used.
-
-The following examples may be useful:
-
- _a_ _c_ _e_ _g_
- --- × --- + --- × ---
- _b_ _d_ _f_ _h_ _acfh_ + _bdeg_
- --------------------- = ---------------
- _a_ _e_ _c_ _g_ _aedh_ + _bcfg_
- --- × --- + --- × ---
- _b_ _f_ _d_ _h_
-
- 1 _b_
- ---------- = ---------
- 1 _ab_ + 1
- _a_ + ---
- _b_
-
- 1 1 _bc_ + 1
- --------------- = -------------- = -----------------
- 1 _c_ _abc_ + _a_ + _c_
- _a_ + --------- _a_ + --------
- 1 _bc_ + 1
- _b_ + ---
- _c_
-
- 1 1 57
- Thus, ------------ = --------- = ---
- 1 8 350
- 6 + ------- 6 + ---
- 1 57
- 7 + ---
- 8
-
-The rules that have been proved to hold good for all numbers may be
-applied when the numbers are represented by letters.
-
-
-
-
-SECTION VI.
-
-DECIMAL FRACTIONS.
-
-
-126. We have seen (112) (121) the necessity of reducing fractions
-to a common denominator, in order to compare their magnitudes. We
-have seen also how much more readily operations are performed upon
-fractions which have the same, than upon those which have different,
-denominators. On this account it has long been customary, in all those
-parts of mathematics where fractions are often required, to use none
-but such as either have, or can be easily reduced to others having, the
-same denominators. Now, of all numbers, those which can be most easily
-managed are such as 10, 100, 1000, &c., where 1 is followed by ciphers.
-These are called DECIMAL NUMBERS; and a fraction whose denominator is
-any one of them, is called a DECIMAL FRACTION, or more commonly, a
-DECIMAL.
-
-127. A whole number may be reduced to a decimal fraction, or one
-decimal fraction to another, with the greatest ease. For example,
-
- 940 9400 94000
- 94 is ---, or ----, or ----- (106);
- 10 100 1000
-
- 3 30 300 3000
- ---- is ----, or ----, or ----- (108).
- 30 100 1000 10000
-
-The placing of a cipher on the right hand of any number is the same
-thing as multiplying that number by 10 (57), and this may be done as
-often as we please in the numerator of a fraction, provided it be done
-as often in the denominator (108).
-
-128. The next question is, How can we reduce a fraction which is
-not decimal to another which is, without altering its value? Take,
-for example, the fraction ⁷/₁₆, multiply both the numerator and
-denominator successively by 10, 100, 1000, &c., which will give a
-series of fractions, each of which is equal to ⁷/₁₆ (108), viz. ⁷⁰/₁₆₀,
-⁷⁰⁰/₁₆₀₀, ⁷⁰⁰⁰/₁₆₀₀₀, ⁷⁰⁰⁰⁰/₁₆₀₀₀₀, &c. The denominator of each of
-these fractions can be divided without remainder by 16, the quotients
-of which divisions form the series of decimal numbers 10, 100, 1000,
-10000, &c. If, therefore, one of the numerators be divisible by 16,
-the fraction to which that numerator belongs has a numerator and
-denominator both divisible by 16. When that division has been made,
-which (108) does not alter the value of the fraction, we shall have a
-fraction whose denominator is one of the series 10, 100, 1000, &c.,
-and which is equal in value to ⁷/₁₆. The question is then reduced to
-finding the first of the numbers 70, 700, 7000, 70000, &c., which can
-be divided by 16 without remainder.
-
-Divide these numbers, one after the other, by 16, as follows:
-
- 16)70(4 16)700(43 16)7000(437 16)70000(4375
- 64 64 64 64
- -- --- --- ---
- 6 60 60 60
- 48 48 48
- -- --- ---
- 12 120 120
- 112 112
- --- ---
- 8 80
- 80
- --
- 0
-
-It appears, then, that 70000 is the first of the numerators which is
-divisible by 16. But it is not necessary to write down each of these
-divisions, since it is plain that the last contains all which came
-before. It will do, then, to proceed at once as if the number of
-ciphers were without end, to stop when the remainder is nothing, and
-then count the number of ciphers which have been used. In this case,
-since 70000 is 16 × 4375,
-
- 70000 16 × 4375 4375
- ------, which is ----------, or -----,
- 160000 16 × 10000 10000
-
-gives the fraction required.
-
-Therefore, to reduce a fraction to a decimal fraction, annex ciphers
-to the numerator, and divide by the denominator until there is no
-remainder. The quotient will be the numerator of the required fraction,
-and the denominator will be unity, followed by as many ciphers as were
-used in obtaining the quotient.
-
-EXERCISES.
-
-Reduce to decimal fractions
-
- ½, ¼, ²/₂₅, ¹/₅₀, ³⁹²⁷/₁₂₅₀, and ⁴⁵³/₆₂₅.
-
- _Answer_, ⁵/₁₀, ²⁵/₁₀₀, ⁸/₁₀₀, ²/₁₀₀, ³¹⁴¹⁶/₁₀₀₀₀, and ⁷²⁴⁸/₁₀₀₀₀.
-
-129. It will happen in most cases that the annexing of ciphers to the
-numerator will never make it divisible by the denominator without
-remainder. For example, try to reduce ¹/₇ to a decimal fraction.
-
- 7)1000000000000000000, &c.
- -------------------
- 142857142857142857, &c.
-
-The quotient here is a continual repetition of the figures 1, 4, 2, 8,
-5, 7, in the same order; therefore ¹/₇ cannot be reduced to a decimal
-fraction. But, nevertheless, if we take as a numerator any number of
-figures from the quotient 142857142857, &c., and as a denominator 1
-followed by as many ciphers as were used in making that part of the
-quotient, we shall get a fraction which differs very little from ¹/₇,
-and which will differ still less from it if we put more figures in the
-numerator and more ciphers in the denominator.
-
- Thus, 1 {is less} 1 3 {which is not} 1
- --- { } --- by --- { } ---
- 10 { than } 7 70 { so much as } 10
-
- 14 1 2 1
- --- --- --- ---
- 100 7 700 100
-
- 142 1 6 1
- ---- --- ---- ----
- 1000 7 7000 1000
-
- 1428 1 4 1
- ----- --- ----- -----
- 10000 7 70000 10000
-
- 14285 1 5 1
- ------ --- ------ ------
- 100000 7 700000 100000
-
- 142857 1 1 1
- ------- --- ------- -------
- 1000000 7 7000000 1000000
-
- &c. &c. &c. &c.
-
-In the first column is a series of decimal fractions, which come nearer
-and nearer to ¹/₇, as the third column shews. Therefore, though we
-cannot find a decimal fraction which is exactly ¹/₇, we can find one
-which differs from it as little as we please.
-
-This may also be illustrated thus: It is required to reduce ¹/₇ to
-a decimal fraction without the error of say a millionth of a unit;
-multiply the numerator and denominator of ¹/₇ by a million, and then
-divide both by 7; we have then
-
- 1 1000000 1428571¹/₇
- --- = ------- = -----------
- 7 7000000 1000000
-
-If we reject the fraction ¹/₇ in the numerator, what we reject is
-really the 7th part of the millionth part of a unit; or less than the
-millionth part of a unit. Therefore ¹⁴²⁸⁵⁷/₁₀₀₀₀₀₀ is the fraction
-required.
-
-
-EXERCISES.
-
- Make similar tables} 3 17 1
- with } ---, ---, and ---.
- these fractions } 91 143 247
-
- } 3
- The recurring} --- is 329670,329670, &c.
- quotient of} 91
-
- 17
- --- 118881,118881, &c.
- 143
-
- 1
- --- 404858299595141700,4048582 &c.
- 247
-
-130. The reason for the _recurrence_ of the figures of the quotient
-in the same order is as follows: If 1000, &c. be divided by the
-number 247, the remainder at each step of the division is less than
-247, being either 0, or one of the first 246 numbers. If, then, the
-remainder never become nothing, by carrying the division far enough,
-one remainder will occur a second time. If possible, let the first
-246 remainders be all different, that is, let them be 1, 2, 3, &c.,
-up to 246, variously distributed. As the 247th remainder cannot be so
-great as 247, it must be one of these which have preceded. From the
-step where the remainder becomes the same as a former remainder, it is
-evident that former figures of the quotient must be repeated in the
-same order.
-
-131. You will here naturally ask, What is the use of decimal
-fractions, if the greater number of fractions cannot be reduced at
-all to decimals? The answer is this: The addition, subtraction,
-multiplication, and division of decimal fractions are much easier than
-those of common fractions; and though we cannot reduce all common
-fractions to decimals, yet we can find decimal fractions so near to
-each of them, that the error arising from using the decimal instead
-of the common fraction will not be perceptible. For example, if we
-suppose an inch to be divided into ten million of equal parts, one of
-those parts by itself will not be visible to the eye. Therefore, in
-finding a length, an error of a ten-millionth part of an inch is of no
-consequence, even where the finest measurement is necessary. Now, by
-carrying on the table in (129), we shall see that
-
- 1428571 1 1
- -------- does not differ from --- by --------;
- 10000000 7 10000000
-
-and if these fractions represented parts of an inch, the first might
-be used for the second, since the difference is not perceptible. In
-applying arithmetic to practice, nothing can be measured so accurately
-as to be represented in numbers without any error whatever, whether it
-be length, weight, or any other species of magnitude. It is therefore
-unnecessary to use any other than decimal fractions, since, by means of
-them, any quantity may be represented with as much correctness as by
-any other method.
-
-
-EXERCISES.
-
-Find decimal fractions which do not differ from the following fractions
-by ¹/₁₀₀₀₀₀₀₀₀.
-
- ⅓ _Answer_, ³³³³³³³³/₁₀₀₀₀₀₀₀₀.
- ⁴/₇ ⁵⁷¹⁴²⁸⁵⁷/₁₀₀₀₀₀₀₀₀.
- ¹¹³/₃₅₅ ³¹⁸³⁰⁹⁸⁵/₁₀₀₀₀₀₀₀₀.
- ³⁵⁵/₁₁₃ ³¹⁴¹⁵⁹²⁹²/₁₀₀₀₀₀₀₀₀.
-
-132. Every decimal may be immediately reduced to a quantity consisting
-either of a whole number and more simple decimals, or of more simple
-decimals alone, having one figure only in each of the numerators. Take,
-for example,
-
- 147326 147326 326
- ------. By (115) ------- is 147----;
- 1000 1000 1000
-
-and since 326 is made up of 300, and 20, and 6; by (112) ³²⁶/₁₀₀₀₀ =
-³⁰⁰/₁₀₀₀ + ²⁰/₁₀₀₀ + ⁶/₁₀₀₀. But (108) ³⁰⁰/₁₀₀₀ is ³/₁₀, and ²⁰/₁₀₀₀
-is ²/₁₀₀. Therefore, ¹¹⁴⁷³²6/₁₀₀₀ is made up of 147 + ³/₁₀ + ²/₁₀₀ +
-6/₁₀₀₀. Now, take any number, for example, 147326, and form a number
-of fractions having for their numerators this number, and for their
-denominators 1, 10, 100, 1000, 10000, &c., and reduce these fractions
-into numbers and more simple decimals, in the foregoing manner, which
-will give the table below.
-
-
-DECOMPOSITION OF A DECIMAL FRACTION.
-
- 147326
- ------ = 147326
- 1
-
- 147326 6
- ------ = 14732 + ---
- 10 10
-
- 147326 2 6
- ------ = 1473 + --- + ---
- 100 10 100
-
- 147326 3 2 6
- ------ = 147 + --- + --- + ----
- 1000 10 100 1000
-
- 147326 7 3 2 6
- ------ = 14 + --- + --- + ---- + -----
- 10000 10 100 1000 10000
-
- 147326 4 7 3 2 6
- ------ = 1 + --- + --- + ---- + ----- + ------
- 100000 10 100 1000 10000 100000
-
- 147326 1 4 7 3 2 6
- ------- = --- + --- + ---- + ----- + ------ + -------
- 1000000 10 100 1000 10000 100000 1000000
-
- 147326 1 4 7 3 2 6
- -------- = --- + ---- + ----- + ------ + ------- + --------
- 10000000 100 1000 10000 100000 1000000 10000000
-
-N.B. The student should write this table himself, and then proceed to
-make similar tables from the following exercises.
-
-EXERCISES.
-
-Reduce the following fractions into a series of numbers and more simple
-fractions:
-
- 31415926 31415926
- --------, --------, &c.
- 10 100
-
- 2700031 2700031
- -------, --------, &c.
- 10 100
-
- 2073000 2073000
- -------, --------, &c.
- 10 100
-
- 3331303 3331303
- -------, -------, &c.
- 1000 10000
-
-133. If, in this table, and others made in the same manner, you look at
-those fractions which contain a whole number, you will see that they
-may be made thus: Mark off, from the right hand of the numerator, as
-many _figures_ as there are _ciphers_ in the denominator by a point, or
-any other convenient mark.
-
- This will give 14732·6 when the fraction is 147326
- ------
- 10
-
- 1473·26 147326
- ------
- 100
-
- 147·326 147326
- ------
- 1000
-
- &c. &c.
-
-The figures on the left of the point by themselves make the whole
-number which the fraction contains. Of those on its right, the first
-is the numerator of the fraction whose denominator is 10, the second
-of that whose denominator is 100, and so on. We now come to those
-fractions which do not contain a whole number.
-
-134. The first of these is ¹⁴⁷³²⁶/₁₀₀₀₀₀₀ which the number of
-_ciphers_ in the denominator is the same as the number of _figures_
-in the numerator. If we still follow the same rule, and mark off all
-the figures, by placing the point before them all, thus, ·147326,
-the observation in (133) still holds good; for, on looking at
-¹⁴⁷³²⁶/₁₀₀₀₀₀₀ in the table, we find it is
-
- 1 4 7 3 2 6
- --- + --- + ---- + ----- + ------ + -------
- 10 100 1000 10000 100000 1000000
-
-The next fraction is ¹⁴⁷³²⁶/₁₀₀₀₀₀₀₀, which we find by the table to be
-
- 1 4 7 3 2 6
- --- + ---- + ----- + ------ + ------- + --------
- 100 1000 10000 100000 1000000 10000000
-
-
-In this, 1 is not divided by 10, but by 100; if, therefore, we put a
-point before the whole, the rule is not true, for the first figure on
-the left of the point has the denominator which, according to the rule,
-the second ought to have, the second that which the third ought to
-have, and so on. In order to keep the same rule for this case, we must
-contrive to make 1 the second figure on the right of the point instead
-of the first. This may be done by placing a cipher between it and the
-point, thus, ·0147326. Here the rule holds good, for by that rule this
-fraction is
-
- 0 1 4 7 3 2 6
- --- + --- + ---- + ----- + ------ + ------- + --------
- 10 100 1000 10000 100000 1000000 10000000
-
-
-which is the same as the preceding line, since ⁰/₁₀ is 0, and need not
-be reckoned.
-
-Similarly, when there are two ciphers more in the denominator than
-there are figures in the numerator, the rule will be true if we place
-two ciphers between the point and the numerator. The rule, therefore,
-stated fully, is this:
-
-To reduce a decimal fraction to a whole number and more simple
-decimals, or to more simple decimals alone if it do not contain a whole
-number, mark off by a point as many figures from the numerator as there
-are ciphers in the denominator. If the numerator have not places enough
-for this, write as many ciphers before it as it wants places, and put
-the point before these ciphers. Then, if there be any figures before
-the point, they make the _whole number_ which the fraction contains.
-The first figure after the point with the denominator 10, the second
-with the denominator 100, and so on, are the _fractions_ of which the
-first fraction is composed.
-
-135. Decimal fractions are not usually written at full length. It is
-more convenient to write the numerator only, and to cut off from the
-numerator as many figures as there are ciphers in the denominator,
-when that is possible, by a point. When there are more ciphers in the
-denominator than figures in the numerator, as many ciphers are placed
-before the numerator as will supply the deficiency, and the point is
-placed before the ciphers. Thus, ·7 will be used in future to denote
-⁷/₁₀, ·07 for ⁷/₁₀₀, and so on. The following tables will give the
-whole of this notation at one view, and will shew its connexion with
-the decimal notation explained in the first section. You will observe
-that the numbers on the right of the units’ place stand for units
-_divided_ by 10, 100, 1000, &c. while those on the left are units
-_multiplied_ by 10, 100, 1000, &c.
-
-The student is recommended always to write the decimal point in a line
-with the top of the figures or in the middle, as is done here, and
-never at the bottom. The reason is, that it is usual in the higher
-branches of mathematics to use a point placed between two numbers or
-letters which are multiplied together; thus, 15. 16, _a_. _b_, (_a_ +
-_b_). (_c_ + _d_) stand for the products of those numbers or letters.
-
- 1234 4 4
- I. 123·4 stands for ---- or 123--- or 123 + ---
- 10 10 10
-
- 1234 34 3 4
- 12·34 ---- or 12--- or 12 + --- + ---
- 100 100 10 100
-
- 1234 234 2 3 4
- 1·234 ---- or 1---- or 1 + --- + --- + ----
- 1000 1000 10 100 1000
-
- 1234 1 2 3 4
- ·1234 ----- or --- + --- + ---- + -----
- 10000 10 100 1000 10000
-
- 1234 1 2 3 4
- ·01234 ------ or --- + ---- + ----- + ------
- 100000 100 1000 10000 100000
-
-
- 1234 1 2 3 4
- ·001234 ------- or ---- + ----- + ------ + -------
- 1000000 1000 10000 100000 1000000
-
- II. 1003 1 3
- ·01003 is ------ or --- + ------
- 100000 100 100000
-
- 1003 1 3
- ·1003 is ----- or --- + -----
- 10000 10 10000
-
- 1003 3
- 10·03 is ---- or 10 + ---
- 100 100
-
- 1003 3
- 100·3 is ---- or 100 + ---
- 10 10
-
- III. 1 2 8 3
- ·1283 = --- + --- + ---- + -----
- 10 100 1000 10000
-
- = ·1 + ·02 + ·008 + ·0003
- = ·1 + ·0283 = ·12 + ·0083
- = ·128 + ·0003 = ·108 + ·0203
- = ·1003 + ·028 = ·1203 + ·008
-
- { 1 is 1000 inches
- { 2 is 200
- { 3 is 30
- { 4 is 4
- IV. In 1234·56789 { 5 is ⁵/₁₀ of an inch
- inches the { 6 is ⁶/₁₀₀
- { 7 is ⁷/₁₀₀₀
- { 8 is ⁸/₁₀₀₀₀
- { 9 is ⁹/₁₀₀₀₀₀
-
-136. The ciphers on the right hand of the decimal point serve the same
-purpose as the ciphers in (10). They are not counted as any thing
-themselves, but serve to shew the place in which the accompanying
-numbers stand. They might be dispensed with by writing the numbers in
-ruled columns, as in the first section. They are distinguished from
-the numbers which accompany them by calling the latter _significant
-figures_. Thus, ·0003747 is a decimal of seven places with four
-significant figures, ·346 is a decimal of three places with three
-significant figures, &c.
-
-137. The value of a decimal is not altered by putting any number of
-ciphers on its right. Take, for example, ·3 and ·300. The first (135)
-is ³/₁₀, and the second ³⁰⁰/₁₀₀₀, which is made from the first by
-multiplying both its numerator and denominator by 100, and (108) is the
-same quantity.
-
-138. To reduce two decimals to a common denominator, put as many
-ciphers on the right of that which has the smaller number of places
-as will make the number of places in both fractions the same. Take,
-for example, ·54 and 4·3297. The first is ⁵⁴/₁₀₀, and the second
-⁴³²⁹⁷/₁₀₀₀₀. Multiply the numerator and denominator of the first by 100
-(108), which reduces it to ⁵⁴⁰⁰/₁₀₀₀₀, which has the same denominator
-as ⁴³²⁹⁷/₁₀₀₀₀. But ⁵⁴⁰⁰/₁₀₀₀₀ is ·5400 (135). In whole numbers, the
-decimal point should be placed at the end: thus, 129 should be written
-129·. It is, however, usual to omit the point; but you must recollect
-that 129 and 129·000 are of the same value, since the first is 129 and
-the second ¹²⁹⁰⁰⁰/₁₀₀₀.
-
-139. The rules which were given in the last chapter for addition,
-subtraction, multiplication, and division, apply to all fractions, and
-therefore to decimal fractions among the rest. But the way of writing
-decimal fractions, which is explained in this chapter, makes the
-application of these rules more simple. We proceed to the different
-cases.
-
-Suppose it required to add 42·634, 45·2806, 2·001, and 54. By (112)
-these must be reduced to a common denominator, which is done (138) by
-writing them as follows: 42·6340, 45·2806, 2·0010, and 54·0000. These
-are decimal fractions, whose numerators are 426340, 452806, 20010, and
-540000, and whose common denominator is 10000. By (112) their sum is
-
- 426340 + 452806 + 20010 + 540000 1439156
- --------------------------------, which is -------
- 10000 10000
-
-or 143·9156. The simplest way of doing this is as follows: write the
-decimals down under one another, so that the decimal points may fall
-under one another, thus:
-
- 42·634
- 45·2806
- 2·001
- 54
- --------
- 143·9156
-
-Add the different columns together as in common addition, and place the
-decimal point under the other decimal points.
-
-EXERCISES.
-
- What are 1527 + 64·732094 + 2·0013 + ·00001974;
- 2276·3 + ·107 + ·9 + 26·3172 + 56732·001;
- and 1·11 + 7·7 + ·0039 + ·00142 + ·8838?
-
- _Answer_, 1593·73341374, 59035·6252, 9·69912.
-
-140. Suppose it required to subtract 91·07324 from 137·321. These
-fractions when reduced to a common denominator are 91·07324 and
-137·32100 (138). Their difference is therefore
-
- 13732100 - 9107324 4624776
- ------------------, which is -------
- 100000 100000
-
-or 46·24776. This may be most simply done as follows: write the less
-number under the greater, so that its decimal point may fall under that
-of the greater, thus:
-
- 137·321
- 91·07324
- ---------
- 46·24776
-
-Subtract the lower from the upper line, and wherever there is a figure
-in one line and not in the other, proceed as if there were a cipher in
-the vacant place.
-
-EXERCISES.
-
- What is 12362 - 274·22107 + ·5;
- 9976·2073942 - ·00143976728;
- and 1·2 + ·03 + ·004 - ·0005?
-
- _Answer_, 12088·27893, 9976·20595443272; and 1·2335.
-
-141. The multiplication of a decimal by 10, 100, 1000, &c., is
-performed by merely moving the decimal point to the right. Suppose,
-for example, 13·2079 is to be multiplied by 100. The decimal is
-¹³²⁰⁷⁹/₁₀₀₀₀, which multiplied by 100 is (117) ¹³²⁰⁷⁹/₁₀₀, or 1320·79.
-Again, 1·309 × 100000 is ¹³⁰⁹/₁₀₀₀ × 100000, or (116) ¹³⁰⁹⁰⁰⁰⁰⁰/₁₀₀₀ or
-130900. From these and other instances we get the following rule: To
-multiply a decimal fraction by a decimal number (126), move the decimal
-point as many places to the right as there are ciphers in the decimal
-number. When this cannot be done, annex ciphers to the right of the
-decimal (137) until it can.
-
-142. Suppose it required to multiply 17·036 by 4·27. The first of these
-decimals is ¹⁷⁰³⁶/₁₀₀₀, and the second ⁴²⁷/₁₀₀. By (118) the product
-of these fractions has for its numerator the product of 17036 and 427,
-and for its denominator the product of 1000 and 100; therefore this
-product is ⁷²⁷⁴³⁷²/₁₀₀₀₀₀, or 72·74372. This may be done more shortly
-by multiplying the two numbers 17036 and 427, and cutting off by the
-decimal point as many places as there are decimal places both in 17·036
-and 4·27, because the product of two decimal numbers will contain as
-many ciphers as there are ciphers in both.
-
-143. This question now arises: What if there should not be as many
-figures in the product as there are decimal places in the multiplier
-and multiplicand together? To see what must be done in this case,
-multiply ·172 by ·101, or ¹⁷²/₁₀₀₀ by ¹⁰¹/₁₀₀₀. The product of these
-two is ¹⁷³⁷²/₁₀₀₀₀₀₀, or ·017372 (135). Therefore, when the number of
-places in the product is not sufficient to allow the rule of the last
-article to be followed, as many ciphers must be placed at the beginning
-as will make up the deficiency.
-
-ADDITIONAL EXAMPLES.
-
- ·001 × ·01 is ·00001
- 56 × ·0001 is ·0056.
-
-EXERCISES.
-
-Shew that
-
- 3·002 × 3·002 = 3 × 3 + 2 × 3 × ·002 + ·002 × ·002
- 11·5609 × 5·3191 = 8·44 × 8·44 - 3·1209 × 3·1209
- 8·217 × 10·001 = 8 × 10 + 8 × ·001 + 10 × ·217 + ·001 × ·217.
-
- Fraction. Square. Cube.
- 82·92 6875·7264 570135·233088
- ·0173 ·00029929 ·000005177717
- 1·43 2·0449 2·924207
- ·009 ·000081 ·000000729
-
- 15·625 × 64 = 1000
- 1·5625 × ·64 = 1
- ·015625 × ·0064 = ·0001
- ·15625 × ·64 = ·1
- 1562·5 × ·064 = 100
- 15625000 × ·064 = 1000000
-
-144. The division of a decimal by a decimal number, such as 10, 100,
-1000, &c., is performed by moving the decimal point as many places to
-the left as there are ciphers in the decimal number. If there are not
-places enough in the dividend to allow of this, annex ciphers to the
-beginning of it until there are. For example, divide 1734·229 by 1000:
-the decimal fraction is ¹⁷³⁴²²⁹/₁₀₀₀, which divided by 1000 (123) is
-¹⁷³⁴²²⁹/₁₀₀₀₀₀₀, or 1·734229. If, in the same way, 1·2106 be divided by
-10000, the result is ·00012106.
-
-145. Before proceeding to shorten the rule for the division of one
-decimal fraction by another, it will be necessary to resume what was
-said in (128) upon the reduction of any fraction to a decimal fraction.
-It was there shewn that ⁷/₁₆ is the same fraction as ⁴³⁷⁵/₁₀₀₀₀ or
-·4375. As another example, convert ³/₁₂₈ into a decimal fraction.
-Follow the same process as in (128), thus:
-
- 128)300000000000(234375
- 256
- ----
- 440
- 384
- ----
- 560
- 512
- ----
- 480
- 384
- ----
- 960
- 896
- ----
- 640
- 640
- ---
- 0
-
-Since 7 ciphers are used, it appears that 30000000 is the first of the
-series 30, 300, &c., which is divisible by 128; and therefore ³/₁₂₈
-or, which is the same thing (108), ³⁰⁰⁰⁰⁰⁰⁰/₁₂₈₀₀₀₀₀₀₀ is equal to
-²³⁴³⁷⁵/₁₀₀₀₀₀₀₀ or ·0234375 (135).
-
-From these examples the rule for reducing a fraction to a decimal is:
-Annex ciphers to the numerator; divide by the denominator, and annex
-a cipher to each remainder after the figures of the numerator are all
-used, proceeding exactly as if the numerator had an unlimited number
-of ciphers annexed to it, and was to be divided by the denominator.
-Continue this process until there is no remainder, and observe how many
-ciphers have been used. Place the decimal point in the quotient so as
-to cut off as many figures as you have used ciphers; and if there be
-not figures enough for this, annex ciphers to the beginning until there
-are places enough.
-
-146. From what was shewn in (129), it appears that it is not every
-fraction which can be reduced to a decimal fraction. It was there
-shewn, however, that there is no fraction to which we may not find a
-decimal fraction as near as we please. Thus, ¹/₁₀, ¹⁴/₁₀₀, ¹⁴²/₁₀₀₀,
-¹⁴²⁸/₁₀₀₀₀, ¹⁴²⁸⁵/₁₀₀₀₀₀, &c., or ·1, ·14, ·142, ·1428, ·14285, were
-shewn to be fractions which approach nearer and nearer to ¹/₇. To find
-either of these fractions, the rule is the same as that in the last
-article, with this exception, that, I. instead of stopping when there
-is no remainder, which never happens, stop at any part of the process,
-and make as many decimal places in the quotient as are equal in number
-to the number of ciphers which have been used, annexing ciphers to the
-beginning when this cannot be done, as before. II. Instead of obtaining
-a fraction which is exactly equal to the fraction from which we set
-out, we get a fraction which is very near to it, and may get one still
-nearer, by using more of the quotient. Thus, ·1428 is very near to ¹/₇,
-but not so near as ·142857; nor is this last, in its turn, so near as
-·142857142857, &c.
-
-147. If there should be ciphers in the numerator of a fraction, these
-must not be reckoned with the number of ciphers which are necessary in
-order to follow the rule for changing it into a decimal fraction. Take,
-for example, ¹⁰⁰/₁₂₅; annex ciphers to the numerator, and divide by the
-denominator. It appears that 1000 is divisible by 125, and that the
-quotient is 8. One cipher only has been annexed to the numerator, and
-therefore 100 divided by 125 is ·8. Had the fraction been ¹/₁₂₅, since
-1000 divided by 125 gives 8, and three ciphers would have been annexed
-to the numerator, the fraction would have been ·008.
-
-148. Suppose that the given fraction has ciphers at the right of its
-denominator; for example, ³¹/₂₅₀₀. Then annexing a cipher to the
-numerator is the same thing as taking one away from the denominator;
-for, (108) ³¹⁰/₂₅₀₀ is the same thing as ³¹/₂₅₀, and ³¹⁰/₂₅₀ as ³¹/₂₅.
-The rule, therefore, is in this case: Take away the ciphers from the
-denominator.
-
-EXERCISES.
-
-Reduce the following fractions to decimal fractions:
-
- 1 36 297 1
- ---, ----, ----, and ---.
- 800 1250 64 128
-
- _Answer_, ·00125, ·0288, 4·640625, and ·0078125.
-
-Find decimals of 6 places very near to the following fractions:
-
- 27 156 22 194 2637 1 1 3
- --, ---, -----, ---, ----, ----, ---, and ---.
- 49 33 37000 13 9907 2908 466 277
-
- _Answer_, ·551020, 4·727272, ·000594, 14·923076, ·266175,
- ·000343, ·002145, and ·010830.
-
-149. From (121) it appears, that if two fractions have the same
-denominator, the first may be divided by the second by dividing the
-numerator of the first by the numerator of the second. Suppose it
-required to divide 17·762 by 6·25. These fractions (138), when reduced
-to a common denominator, are 17·762 and 6·250, or ¹⁷⁷⁶²/₁₀₀₀ and
-⁶²⁵⁰/₁₀₀₀. Their quotient is therefore ¹⁷⁷⁶²/₆₂₅₀, which must now be
-reduced to a decimal fraction by the last rule. The process at full
-length is as follows: Leave out the cipher in the denominator, and
-annex ciphers to the numerator, or, which will do as well, to the
-remainders, when it becomes necessary, and divide as in (145).
-
- 625)17762(284192
- 1250
- -----
- 5262
- 5000
- -----
- 2620
- 2500
- -----
- 1200
- 625
- -----
- 5750
- 5625
- -----
- 1250
- 1250
- ----
- 0
-
-Here four ciphers have been annexed to the numerator, and one has been
-taken from the denominator. Make five decimal places in the quotient,
-which then becomes 2·84192, and this is the quotient of 17·762 divided
-by 6·25.
-
-150. The rule for division of one decimal by another is as follows:
-Equalise the number of decimal places in the dividend and divisor,
-by annexing ciphers to that which has fewest places. Then, further,
-annex as many ciphers to the dividend[18] as it is required to have
-decimal places, throw away the decimal point, and operate as in common
-division. Make the required number of decimal places in the quotient.
-
-[18] Or remove ciphers from the divisor; or make up the number of
-ciphers partly by removing from the divisor and annexing to the
-dividend, if there be not a sufficient number in the divisor.
-
-Thus, to divide 6·7173 by ·014 to three decimal places, I first write
-6·7173 and ·0140, with four places in each. Having to provide for three
-decimal places, I should annex three ciphers to 6·7173; but, observing
-that the divisor ·0140 has one cipher, I strike that one out and annex
-two ciphers to 6·7173. Throwing away the decimal points, then divide
-6717300 by 014 or 14 in the usual way, which gives the quotient 479807
-and the remainder 2. Hence 479·807 is the answer.
-
-The common rule is: Let the quotient contain as many decimal places
-as there are decimal places in the dividend more than in the divisor.
-But this rule becomes inoperative except when there are more decimals
-in the dividend than in the divisor, and a number of ciphers must
-be annexed to the former. The rule in the text amounts to the same
-thing, and provides for an assigned number of decimal places. But the
-student is recommended to make himself familiar with the rule of the
-_characteristic_ given in the Appendix, and also to accustom himself
-to _reason out_ the place of the decimal point. Thus, it should be
-visible, that 26·119 ÷ 7·2436 has one figure before the decimal point,
-and that 26·119 ÷ 724·36 has one cipher after it, preceding all
-significant figures.
-
-Or the following rule may be used: Expunge the decimal point of the
-divisor, and move that of the dividend as many places to the right as
-there were places in the divisor, using ciphers if necessary. Then
-proceed as in common division, making one decimal place in the quotient
-for every decimal place of the final dividend which is used. Thus
-17·314 divided by 61·2 is 173·14 divided by 612, and the decimal point
-must precede the first figure of the quotient. But 17·314 divided by
-6617·5 is 173·14 by 66175; and since three decimal places of 173·14000
-... must be used before a quotient figure can be found, that quotient
-figure is the third decimal place, or the quotient is ·002.....
-
-EXAMPLES.
-
- 3·1 ·00062
- ----- = 1240, ------ = ·00096875
- ·0025 ·64
-
-EXERCISES.
-
- 15·006 × 15·006 - ·004 × ·004
- Shew that ----------------------------- = 15·002,
- 15·01
-
- and that
-
- ·01 × ·01 × ·01 + 2·9 × 2·9 × 2·9
- --------------------------------- = 2·9 × 2·9 - 2·9 × ·01 + ·01 × ·01
- 2·91
-
- 1 1 365
- What are -------, ---------, and ------, as far as 6 places
- 3·14159 2·7182818 ·18349
-
-of decimals?--_Answer_, ·318310, ·367879, and 1989·209221.
-
-Calculate 10 terms of each of the following series, as far as 5 places
-of decimals.
-
- 1 1 1 1
- 1 + --- + ----- + --------- + ------------- + &c. = 1·71824.
- 2 2 × 3 2 × 3 × 4 2 × 3 × 4 × 5
-
- 1 1 1 1
- 1 + --- + --- + --- + --- + &c. = 2·92895.
- 2 3 4 5
-
- 80 81 82 83 84
- ---- + ---- + ---- + ---- + ---- + &c. = 9·88286.
- 81 82 83 84 85
-
-151. We now enter upon methods by which unnecessary trouble is saved in
-the computation of decimal quantities. And first, suppose a number of
-miles has been measured, and found to be 17·846217 miles. If you were
-asked how many miles there are in this distance, and a rough answer
-were required which should give miles only, and not parts of miles,
-you would probably say 17. But this, though the number of whole miles
-contained in the distance, is not the nearest number of miles; for,
-since the distance is more than 17 miles and 8 tenths, and therefore
-more than 17 miles and a half, it is nearer the truth to say, it is 18
-miles. This, though too great, is not so much too great as the other
-was too little, and the error is not so great as half a mile. Again,
-if the same were required within a tenth of a mile, the correct answer
-is 17·8; for though this is too little by ·046217, yet it is not so
-much too little as 17·9 is too great; and the error is less than half
-a tenth, or ¹/₂₀. Again, the same distance, within a hundredth of a
-mile, is more correctly 17·85 than 17·84, since the last is too little
-by ·006217, which is greater than the half of ·01; and therefore 17·84
-+ ·01 is nearer the truth than 17·84. Hence this general rule: When a
-certain number of the decimals given is sufficiently accurate for the
-purpose, strike off the rest from the right hand, observing, if the
-first figure struck off be equal to or greater than 5, to increase the
-last remaining figure by 1.
-
-The following are examples of a decimal abbreviated by one place at a
-time.
-
- 3·14159, 3·1416, 3·142, 3·14, 3·1, 3·0
-
- 2·7182818, 2·718282, 2·71828, 2·7183, 2·718, 2·72, 2·7, 3·0
-
- 1·9919, 1·992, 1·99, 2·00, 2·0
-
-152. In multiplication and division it is useless to retain more
-places of decimals in the result than were certainly correct in
-the multiplier, &c., which gave that result. Suppose, for example,
-that 9·98 and 8·96 are distances in inches which have been measured
-correctly to two places of decimals, that is, within half a hundredth
-of an inch each way. The real value of that which we call 9·98 may be
-any where between 9·975 and 9·985, and that of 8·96 may be any where
-between 8·955 and 8·965. The product, therefore, of the numbers which
-represent the correct distances will lie between 9·975 × 8·955 and
-9·985 × 8·965, that is, taking three decimal places in the products,
-between 89·326 and 89·516. The product of the actual numbers given
-is 89·4208. It appears, then, that in this case no more than the
-whole number 89 can be depended upon in the product, or, at most,
-the first place of decimals. The reason is, that the error made in
-measuring 8·96, though only in the third place of decimals, is in
-the multiplication increased at least 9·975, or nearly 10 times; and
-therefore affects the second place. The following simple rule will
-enable us to judge how far a product is to be depended upon. Let _a_ be
-the multiplier, and _b_ the multiplicand; if these be true only to the
-first decimal place, the product is within (_a_ + _b_)/20[19] of the
-truth; if to two decimal places, within (_a_ + _b_)/200; if to three,
-within (_a_ + _b_)/2000; and so on. Thus, in the above example, we have
-9·98 and 8·96, which are true to two decimal places: their sum divided
-by 200 is ·0947, and their product is 89·4208, which is therefore
-within ·0947 of the truth. If, in fact, we increase and diminish
-89·4208 by ·0947, we get 89·5155 and 89·3261, which are very nearly
-the limits found within which the product must lie. We see, then, that
-we cannot in this case depend upon the first place of decimals, as
-(151) an error of ·05 cannot exist if this place be correct; and here
-is a possible error of ·09 and upwards. It is hardly necessary to say,
-that if the numbers given be exact, their product is exact also, and
-that this article applies where the numbers given are correct only to
-a certain number of decimal places. The rule is: Take half the sum
-of the multiplier and multiplicand, remove the decimal point as many
-places to the left as there are correct places of decimals in either
-the multiplier or multiplicand; the result is the quantity within which
-the product can be depended upon. In division, the rule is: Proceed
-as in the last rule, putting the dividend and divisor in place of the
-multiplier and multiplicand, and divide by the _square_ of the divisor;
-the quotient will be the quantity within which the division of the
-first dividend and divisor may be depended upon. Thus, if 17·324 be
-divided by 53·809, both being correct to the third place, their half
-sum will be 35·566, which, by the last rule, is made ·035566, and is to
-be divided by the square of 53·809, or, which will do as well for our
-purpose, the square of 50, or 2500. The result is something less than
-·00002, so that the quotient of 17·324 and 53·809 can be depended on to
-four places of decimals.
-
-[19] These are not quite correct, but sufficiently so for every
-practical purpose.
-
-153. It is required to multiply two decimal fractions together, so as
-to retain in the product only a given number of decimal places, and
-dispense with the trouble of finding the rest. First, it is evident
-that we may write the figures of any multiplier in a contrary order
-(for example, 4321 instead of 1234), provided that in the operation we
-move each line one place to the right instead of to the left, as in the
-following example:
-
- 2221 2221
- 1234 4321
- ---- ----
- 8884 2221
- 6663 4442
- 4442 6663
- 2221 8884
- ------- -------
- 2740714 2740714
-
-Suppose now we wish to multiply 348·8414 by 51·30742, reserving only
-four decimal places in the product. If we reverse the multiplier, and
-proceed in the manner just pointed out, we have the following:
-
- 3488414
- 2470315 |
- ---------+
- 17442070 |
- 3488414|
- 1046524|2
- 24418|898
- 1395|3656
- 69|76828
- ----------+------
- 17898·1522|23188
-
-Cut off, by a vertical line, the first four places of decimals, and
-the columns which produced them. It is plain that in forming our
-abbreviated rule, we have to consider only, I. all that is on the left
-of the vertical line; II. all that is carried from the first column on
-the right of the line. On looking at the first column to the left of
-the line, we see 4, 4, 8, 5, 9, of which the first 4 comes from 4 ×
-1′,[20] the second 4 from 1 × 3′, the 8 from 8 × 7′, the 5 from 8 × 4′,
-and the 9 from 4 × 2′. If, then, we arrange the multiplicand and the
-reversed multiplier thus,
-
- 3488414
- 2470315
-
-each figure of the multiplier is placed under the first figure of
-the multiplicand which is used with it in forming the first _four_
-places of decimals. And here observe, that the units’ figure in the
-multiplier 51·30742, viz. 1, comes under 4, the _fourth_ decimal
-place in the multiplicand. If there had been no carrying from the
-right of the vertical line, the rule would have been: Reverse the
-multiplier, and place it under the multiplicand, so that the figure
-which was the units’ figure in the multiplier may stand under the last
-place of decimals in the multiplicand which is to be preserved; place
-ciphers over those figures of the multiplier which have none of the
-multiplicand above them, if there be any: proceed to multiply in the
-usual way, but begin each figure of the multiplier with the figure of
-the multiplicand which comes above it, taking no account of those on
-the right: place the first figures of all the lines under one another.
-To correct this rule, so as to allow for what is carried from the right
-of the vertical line, observe that this consists of two parts, 1st,
-what is carried directly in the formation of the different lines, and
-2dly, what is carried from the addition of the first column on the
-right. The first of these may be taken into account by beginning each
-figure of the multiplier with the one which comes on its right in the
-multiplicand, and carrying the tens to the next figure as usual, but
-without writing down the units. But both may be allowed for at once,
-with sufficient correctness, on the principle of (151), by carrying
-1 from 5 up to 15, 2 from 15 up to 25, &c.; that is, by carrying the
-nearest ten. Thus, for 37, 4 would be carried, 37 being nearer to 40
-than to 30. This will not always give the last place quite correctly,
-but the error may be avoided by setting out so as to keep one more
-place of decimals in the product than is absolutely required to be
-correct. The rule, then, is as follows:
-
-[20] The 1′ here means that the 1 is in the multiplier.
-
-154. To multiply two decimals together, retaining only _n_ decimal
-places.
-
-I. Reverse the multiplier, strike out the decimal points, and place the
-multiplier under the multiplicand, so that what was its units’ figure
-shall fall under the _n_ᵗʰ decimal place of the multiplicand, placing
-ciphers, if necessary, so that every place of the multiplier shall have
-a figure or cipher above it.
-
-II. Proceed to multiply as usual, beginning each figure of the
-multiplier with the one which is in the place to its right in the
-multiplicand: do not set down this first figure, but carry its
-_nearest_ ten to the next, and proceed.
-
-III. Place the first figures of all the lines under one another; add as
-usual; and mark off _n_ places from the right for decimals.
-
-It is required to multiply 136·4072 by 1·30609, retaining 7 decimal
-places.
-
- 1364072000
- 906031
- ----------
- 1364072000
- 409221600
- 8184432
- 122766
- -----------
- 178·1600798
-
-In the following examples the first two lines are the multiplicand and
-multiplier; and the number of decimals to be retained will be seen from
-the results.
-
- ·4471618 33·166248 3·4641016
- 3·7719214 1·4142136 1732·508
- ========= ========== ============
- 37719214 033166248 346410160
- 8161744 63124141 8052371
- -------- ---------- ------------
- 15087686 3316625 346410160
- 1508768 1326650 242487112
- 264034 33166 10392305
- 3772 13266 692820
- 2263 663 173205
- 38 33 2771
- 30 10 ------------
- --------- 2 6001·58373
- 1·6866591 --------
- 46·90415
-
-Exercises may be got from article (143).
-
-155. With regard to division, take any two numbers, for example,
-16·80437921 and 3·142, and divide the first by the second, as far as
-any required number of decimal places, for example, five. This gives
-the following:
-
- 3·142)16·80437921(5·34830
- 15·710
- -------
- 1·0943 |
- 9426 |
- -----|
- 15177|
- (A) 12568|
- ---- -----|-
- 2609 2609|9
- 2514 2513|6
- ---- ----|--
- 95 96|32
- 94 94|26
- -- --|---
- 1 2|061
-
-Now cut off by a vertical line, as in (153), all the figures which
-come on the right of the first figure 2, in the last remainder 2061.
-As in multiplication, we may obtain all that is on the left of the
-vertical line by an abbreviated method, as represented at (A). After
-what has been said on multiplication, it is useless to go further
-into the detail; the following rule will be sufficient: To divide one
-decimal by another, retaining only _n_ places: Proceed one step in
-the ordinary division, and determine, by (150), in what place is the
-quotient so obtained; proceed in the ordinary way, until the number of
-figures remaining to be found in the quotient is less than the number
-of figures in the divisor: if this should be already the case, proceed
-no further in the ordinary way. Instead of annexing a figure or cipher
-to the remainder, cut off a figure from the divisor, and proceed one
-step with this curtailed divisor as usual, remembering, however, in
-multiplying this divisor, to carry the _nearest ten_, as in (154), from
-the figure which was struck off; repeat this, striking off another
-figure of the divisor, and so on, until no figures are left. Since we
-know from the beginning in what place the first figure of the quotient
-is, and also how many decimals are required, we can tell from the
-beginning how many figures there will be in the whole quotient. If the
-divisor contain more figures than the quotient, it will be unnecessary
-to use them: and they may be rejected, the rest being corrected as in
-(151): if there be ciphers at the beginning of the divisor, if it be,
-for example,
-
- ·3178
- ·003178, since this is -----,
- 100
-
-divide by ·3178 in the usual way, and afterwards multiply the quotient
-by 100, or remove the decimal point two places to the right. If,
-therefore, six decimals be required, eight places must be taken in
-dividing by ·3178, for an obvious reason. In finding the last figure
-of the quotient, the nearest should be taken, as in the second of the
-subjoined examples.
-
- Places required, 2 8
- Divisor, ·41432 3·1415927
- Dividend, 673·1489 2·71828180
- 41432 2·51327416
- -------- ----------
- 258828 20500764
- 248592 18849556
- ------- --------
- 10237[21] 1651208
- 8286 1570796
- ----- -------
- 1951 80412
- 1657 62832
- ----- -----
- 294 17580
- 290 15708
- --- -----
- 4 1872
- 4 1571
- - ----
- 0 301
- 283
- ---
- 18
- 19
- --
- Quotient, 1624·71 ·86525596
-
-[21] This is written 7 instead of 6, because the figure which is
-abandoned in the dividend is 9 (151).
-
-Examples may be obtained from (143) and (150).
-
-
-
-
-SECTION VII.
-
-ON THE EXTRACTION OF THE SQUARE ROOT.
-
-
-156. We have already remarked (66), that a number multiplied by itself
-produces what is called the _square_ of that number. Thus, 169, or 13 ×
-13, is the square of 13. Conversely, 13 is called the _square root_ of
-169, and 5 is the square root of 25; and any number is the square root
-of another, which when multiplied by itself will produce that other.
-The square root is signified by the sign
- _
- √ or √ ;
- _______
- thus, √25 means the square root of 25, or 5; √(16 + 9)
-
-means the square root of 16 + 9, and is 5, and must not be confounded
-with √16 + √9, which is 4 + 3, or 7.
-
-
-157. The following equations are evident from the definition:
-
- ___ ___
- √_a_ × √_a_ = _a_
- ____
- √_aa_ = _a_
- ___ ___ ___
- √_ab_ × √_ab_ = _ab_
- ___ ___ ___ ___ ___ ___ ___ ___
- (√_a_ × √_b_) × (√_a_ × √_b_) = √_a_ × √_a_ × √_b_ × √_b_ = _ab_
- ___ ___ ____
- whence √_a_ × √_b_ = √_ab_
-
-158. It does not follow that a number has a square root because it
-has a square; thus, though 5 can be multiplied by itself, there is
-no number which multiplied by itself will produce 5. It is proved in
-algebra, that no fraction[22] multiplied by itself can produce a whole
-number, which may be found true in any number of instances; therefore
-5 has neither a whole nor a fractional square root; that is, it has
-no square root at all. Nevertheless, there are methods of finding
-fractions whose squares shall be as _near_ to 5 as we please, though
-not exactly equal to it. One of these methods gives ¹⁵¹²⁷/₆₇₆₅, whose
-square, viz.
-
- 15127 15127 228826129
- ----- × ----- or ---------,
- 6765 6765 45765225
-
-differs from 5 by only ⁴/₄₅₇₆₅₂₂₅, which is less than ·0000001: hence
-we are enabled to use √5 in arithmetical and algebraical reasoning: but
-when we come to the practice of any problem, we must substitute for
-√5 one of the fractions whose square is nearly 5, and on the degree
-of accuracy we want, depends what fraction is to be used. For some
-purposes, ¹²³/₅₅ may be sufficient, as its square only differs from 5
-by ⁴/₃₀₂₅; for others, the fraction first given might be necessary,
-or one whose square is even nearer to 5. We proceed to shew how to
-find the square root of a number, when it has one, and from thence how
-to find fractions whose squares shall be as near as we please to the
-number, when it has not. We premise, what is sufficiently evident, that
-of two numbers, the greater has the greater square; and that if one
-number lie between two others, its square lies between the squares of
-those others.
-
-[22] Meaning, of course, a really fractional number, such as ⅞ or
-¹⁵/₁₁, not one which, though fractional in form, is whole in reality,
-such as ¹⁰/₅ or ²⁷/₃.
-
-159. Let _x_ be a number consisting of any number of parts, for
-example, four, viz. _a_, _b_, _c_, and _d_; that is, let
-
- _x_ = _a_ + _b_ + _c_ + _d_
-
-The square of this number, found as in (68), will be
-
- _aa_ + 2_a_(_b_ + _c_ + _d_)
- + _bb_ + 2_b_(_c_ + _d_)
- + _cc_ + 2_cd_
- + _dd_
-
-The rule there found for squaring a number consisting of parts was:
-Square each part, and multiply all that come after by twice that part,
-the sum of all the results so obtained will be the square of the whole
-number. In the expression above obtained, instead of multiplying 2_a_
-by _each_ of the succeeding parts, _b_, _c_, and _d_, and adding the
-results, we multiplied 2_a_ by the _sum of all_ the succeeding parts,
-which (52) is the same thing; and as the parts, however disposed,
-make up the number, we may reverse their order, putting the last
-first, &c.; and the rule for squaring will be: Square each part, and
-multiply all that come before by twice that part. Hence a reverse rule
-for extracting the square root presents itself with more than usual
-simplicity. It is: To extract the square root of a number N, choose
-a number A, and see if N will bear the subtraction of the square of
-A; if so, take the remainder, choose a second number B, and see if
-the remainder will bear the subtraction of the square of B, and twice
-B multiplied by the preceding part A: if it will, there is a second
-remainder. Choose a third number C, and see if the second remainder
-will bear the subtraction of the square of C, and twice C multiplied by
-A + B: go on in this way either until there is no remainder, or else
-until the remainder will not bear the subtraction arising from any new
-part, even though that part were the least number, which is 1. In the
-first case, the square root is the sum of A, B, C, &c.; in the second,
-there is no square root.
-
-160. For example, I wish to know if 2025 has a square root. I choose 20
-as the first part, and find that 400, the square of 20, subtracted from
-2025, gives 1625, the first remainder. I again choose 20, whose square,
-together with twice itself, multiplied by the preceding part, is 20
-× 20 + 2 × 20 × 20, or 1200; which subtracted from 1625, the first
-remainder, gives 425, the second remainder. I choose 7 for the third
-part, which appears to be too great, since 7 × 7, increased by 2 × 7
-multiplied by the sum of the preceding parts 20 + 20, gives 609, which
-is more than 425. I therefore choose 5, which closes the process, since
-5 × 5, together with 2 × 5 multiplied by 20 + 20, gives exactly 425.
-The square root of 2025 is therefore 20 + 20 + 5, or 45, which will be
-found, by trial, to be correct; since 45 × 45 = 2025. Again, I ask if
-13340 has, or has not, a square root. Let 100 be the first part, whose
-square is 10000, and the first remainder is 3340. Let 10 be the second
-part. Here 10 × 10 + 2 × 10 × 100 is 2100, and the second remainder, or
-3340-2100, is 1240. Let 5 be the third part; then 5 × 5 + 2 × 5 × (100
-+ 10) is 1125, which, subtracted from 1240, leaves 115. There is, then,
-no square root; for a single additional unit will give a subtraction
-of 1 × 1 + 2 × 1 × (100 + 10 + 5), or 231, which is greater than 115.
-But if the number proposed had been less by 115, each of the remainders
-would have been 115 less, and the last remainder would have been
-nothing. Therefore 13340-115, or 13225, has the square root 100 + 10 +
-5, or 115; and the answer is, that 13340 has no square root, and that
-13225 is the next number below it which has one, namely, 115.
-
-161. It only remains to put the rule in such a shape as will guide us
-to those parts which it is most convenient to choose. It is evident
-(57) that any number which terminates with ciphers, as 4000, has double
-the number of ciphers in its square. Thus, 4000 × 4000 = 16000000;
-therefore, any square number,[23] as 49, with an even number of ciphers
-annexed, as 490000, is a square number. The root[24] of 490000 is 700.
-This being premised, take any number, for example, 76176; setting out
-from the right hand towards the left, cut off two figures; then two
-more, and so on, until one or two figures only are left: thus, 7,61,76.
-This number is greater than 7,00,00, of which the first figure is not
-a square number, the nearest square below it being 4. Hence, 4,00,00
-is the nearest square number below 7,00,00, which has four ciphers,
-and its square root is 200. Let this be the first part chosen: its
-square subtracted from 76176 leaves 36176, the first remainder; and
-it is evident that we have obtained the highest number of the highest
-denomination which is to be found in the square root of 76176; for
-300 is too great, its square, 9,00,00, being greater than 76176: and
-any denomination higher than hundreds has a square still greater. It
-remains, then, to choose a second part, as in the examples of (160),
-with the remainder 36176. This part cannot be as great as 100, by what
-has just been said; its highest denomination is therefore a number of
-tens. Let N stand for a number of tens, which is one of the simple
-numbers 1, 2, 3, &c.; that is, let the new part be 10N, whose square
-is 10N × 10N, or 100NN, and whose double multiplied by the former part
-is 20N × 200, or 4000N; the two together are 4000N + 100NN. Now, N
-must be so taken that this may not be greater than 36176: still more
-4000N must not be greater than 36176. We may therefore try, for N, the
-number of times which 36176 contains 4000, or that which 36 contains
-4. The remark in (80) applies here. Let us try 9 tens or 90. Then, 2 ×
-90 × 200 + 90 × 90, or 44100, is to be subtracted, which is too great,
-since the whole remainder is 36176. We then try 8 tens or 80, which
-gives 2 × 80 × 200 + 80 × 80, or 38400, which is likewise too great. On
-trying 7 tens, or 70, we find 2 × 70 × 200 + 70 × 70, or 32900, which
-subtracted from 36176 gives 3276, the second remainder. The rest of
-the square root can only be units. As before, let N be this number of
-units. Then, the sum of the preceding parts being 200 + 70, or 270,
-the number to be subtracted is 270 × 2N + NN, or 540N + NN. Hence, as
-before, 540N must be less than 3276, or N must not be greater than the
-number of times which 3276 contains 540, or (80) which 327 contains
-54. We therefore try if 6 will do, which gives 2 × 6 × 270 + 6 × 6, or
-3276, to be subtracted. This being exactly the second remainder, the
-third remainder is nothing, and the process is finished. The square
-root required is therefore 200 + 70 + 6, or 276.
-
-[23] By square number I mean, a number which has a square root. Thus,
-25 is a square number, but 26 is not.
-
-[24] The term ‘root’ is frequently used as an abbreviation of square
-root.
-
-The process of forming the numbers to be subtracted may be shortened
-thus. Let A be the sum of the parts already found, and N a new part:
-there must then be subtracted 2AN + NN, or (54) 2A + N multiplied by
-N. The rule, therefore, for forming it is: Double the sum of all the
-preceding parts, add the new part, and multiply the result by the new
-part.
-
-162. The process of the last article is as follows:
-
- 7,61,76(200 7,61,76(276
- 4 00 00 70 4
- ------- 6 ---
- 400)3,61,76 47)361
- 70)3 29 00 329
- ------- -----
- 400) 32 76 546)3276
- 140) 32 76 3276
- 6) ----- ----
- 0 0
-
-In the first of these, the numbers are written at length, as we found
-them; in the second, as in (79), unnecessary ciphers are struck off,
-and the periods 61, 76, are not brought down, until, by the continuance
-of the process, they cease to have ciphers under them. The following
-is another example, to which the reasoning of the last article may be
-applied.
-
- 34,86,78,44,01(50000 34,86,78,44,01(59049
- 25 00 00 00 00 9000 25
- -------------- 40 ----
- 100000) 9 86 78 44 01 9 109) 986
- 9000) 9 81 00 00 00 981
- ------------- -------
- 100000) 5 78 44 01 11804) 57844
- 18000) 4 72 16 00 47216
- 40) ----------- --------
- 100000) 1 06 28 01 118089)1062801
- 18000) 1 06 28 01 1062801
- 80) ---------- -------
- 9) 0 0
-
-163. The rule is as follows: To extract the square root of a number;--
-
-I. Beginning from the right hand, cut off periods of two figures each,
-until not more than two are left.
-
-II. Find the root of the nearest square number next below the number
-in the first period. This root is the first figure of the required
-root; subtract its square from the first period, which gives the first
-remainder.
-
-III. Annex the second period to the right of the remainder, which gives
-the first dividend.
-
-IV. Double the first figure of the root; see how often this is
-contained in the number made by cutting one figure from the right of
-the first dividend, attending to IX., if necessary; use the quotient as
-the second figure of the root; annex it to the right of the double of
-the first figure, and call this the first divisor.
-
-V. Multiply the first divisor by the second figure of the root; if the
-product be greater than the first dividend, use a lower number for the
-second figure of the root, and for the last figure of the divisor,
-until the multiplication just mentioned gives the product less than the
-first dividend; subtract this from the first dividend, which gives the
-second remainder.
-
-VI. Annex the third period to the second remainder, which gives the
-second dividend.
-
-VII. Double the first two figures of the root;[25] see how often the
-result is contained in the number made by cutting one figure from the
-right of the second dividend; use the quotient as the third figure of
-the root; annex it to the right of the double of the first two figures,
-and call this the second divisor.
-
-[25] Or, more simply, add the second figure of the root to the first
-divisor.
-
-VIII. Get a new remainder, as in V., and repeat the process until all
-the periods are exhausted; if there be then no remainder, the square
-root is found; if there be a remainder, the proposed number has no
-square root, and the number found as its square root is the square root
-of the proposed number diminished by the remainder.
-
-IX. When it happens that the double of the figures of the root is not
-contained at all in all the dividend except the last figure, or when,
-being contained once, 1 is found to give more than the dividend, put a
-cipher in the square root and in the divisor, and bring down the next
-period; should the same thing still happen, put another cipher in the
-root and divisor, and bring down another period; and so on.
-
-
-EXERCISES.
-
- Numbers proposed. | Square roots.
- 73441 | 271
- 2992900 | 1730
- 6414247921 | 80089
- 903687890625 | 950625
- 42420747482776576 | 205962976
- 13422659310152401 | 115856201
-
-164. Since the square of a fraction is obtained by squaring the
-numerator and the denominator, the square root of a fraction is found
-by taking the square root of both. Thus, the square root of ²⁵/₆₄ is ⅝,
-since 5 × 5 is 25, and 8 × 8 is 64. If the numerator or denominator,
-or both, be not square numbers, it does not therefore follow that the
-fraction has no square root; for it may happen that multiplication
-or division by the same number may convert both the numerator and
-denominator into square numbers (108). Thus, ²⁷/₄₈, which appears at
-first to have no square root, has one in reality, since it is the same
-as ⁹/₁₆, whose square root is ¾.
-
-165. We now proceed from (158), where it was stated that any number or
-fraction being given, a second may be found, whose square is as near to
-the first as we please. Thus, though we cannot solve the problem, “Find
-a fraction whose square is 2,” we can solve the following, “Find a
-fraction whose square shall not differ from 2 by so much as ·00000001.”
-Instead of this last, a still smaller fraction may be substituted;
-in fact, any one however small: and in this process we are said to
-approximate to the square root of 2. This can be done to any extent,
-as follows: Suppose we wish to find the square root of 2 within ¹/₅₇
-of the truth; by which I mean, to find a fraction _a_/_b_ whose square
-is less than 2, but such that the square of _a_/_b_ + ¹/₅₇ is greater
-than 2. Multiply the numerator and denominator of ²/₁ by the square
-of 57, or 3249, which gives ⁶⁴⁹⁸/₃₂₄₉. On attempting to extract the
-square root of the numerator, I find (163) that there is a remainder
-98, and that the square number next below 6498 is 6400, whose root is
-80. Hence, the square of 80 is less than 6498, while that of 81 is
-greater. The square root of the denominator is of course 57. Hence,
-the square of ⁸⁰/⁵⁷ is less than ⁶⁴⁹⁸/₃₂₄₉, or 2, while that of ⁸¹/₅₇
-is greater, and these two fractions only differ by ¹/₅₇; which was
-required to be done.
-
-166. In practice, it is usual to find the square root true to a certain
-number of places of decimals. Thus, 1·4142 is the square root of 2 true
-to four places of decimals, since the square of 1·4142, or 1·99996164,
-is less than 2, while an increase of only 1 in the fourth decimal
-place, giving 1·4143, gives the square 2·00024449, which is greater
-than 2. To take a more general case: Suppose it required to find the
-square root of 1·637 true to four places of decimals. The fraction is
-¹⁶³⁷/₁₀₀₀, whose square root is to be found within ·0001, or ¹/₁₀₀₀₀.
-Annex ciphers to the numerator and denominator, until the denominator
-becomes the square of ¹/₁₀₀₀₀, which gives ¹⁶³⁷⁰⁰⁰⁰⁰/₁₀₀₀₀₀₀₀₀,
-extract the square root of the numerator, as in (163), which shews
-that the square number nearest to it is 163700000-13564, whose root is
-12794. Hence, ¹²⁷⁹⁴/₁₀₀₀₀, or 1·2794, gives a square less than 1·637,
-while 1·2795 gives a square greater. In fact, these two squares are
-1·63686436 and 1·63712025.
-
-167. The rule, then, for extracting the square root of a number or
-decimal to any number of places is: Annex ciphers until there are twice
-as many places following the units’ place as there are to be decimal
-places in the root; extract the nearest square root of this number,
-and mark off the given number of decimals. Or, more simply: Divide the
-number into periods, so that the units’ figure shall be the last of
-a period; proceed in the usual way; and if, when decimals follow the
-units’ place, there is one figure on the right, in a period by itself,
-annex a cipher in bringing down that period, and afterwards let each
-new period consist of two ciphers. Place the decimal point after that
-figure in forming which the period containing the units was used.
-
-168. For example, what is the square root of (1⅜) to five places of
-decimals? This is (145) 1·375, and the process is the first example
-over leaf. The second example is the extraction of the root of ·081
-to seven places, the first period being 08, from which the cipher is
-omitted as useless.
-
- 1,37,5(1·17260
- 1
- ---
- 21) 37
- 21
- ----
- 227)1650
- 1589
- ------
- 2342) 6100
- 4684
- ------
- 23446)141600
- 140676
- --------
- 23452) 92400
-
- 8,1(·2846049
- 4
- ---
- 48)410
- 384
- ------
- 564) 2600
- 2256
- ------
- 5686) 34400
- 34116
- ---------
- 569204) 2840000
- 2276816
- ---------
- 569208) 56318400
-
- ·000002413672221(·001553599
- 1
- ---
- 25) 141
- 125
- -----
- 305) 1636
- 1525
- ------
- 3103) 11172
- 9309
- ------
- 31065) 186322
- 155325
- --------
- 310709) 3099710
- 2796381
- ---------
- 30332900
-
-169. When more than half the decimals required have been found, the
-others may be simply found by dividing the dividend by the divisor, as
-in (155). The extraction of the square root of 12 to ten places, which
-will be found in the next page, is an example. It must, however, be
-observed in this process, as in all others where decimals are obtained
-by approximation, that the last place cannot always be depended upon:
-on which account it is advisable to carry the process so far, that
-one or even two more decimals shall be obtained than are absolutely
-required to be correct.
-
- A
- 12(3·46410161513
- 9
- ---
- 64) 300
- 256
- -----
- 686) 4400
- 4116
- ------
- 6924) 28400
- 27696
- ------
- 69281) 70400
- 69281
- ----------
- 6928201) 11190000
- 6928201
- -------+--
- 69282026) 4261799|00
- 4156921|56
- -------+----
- 692820321) 104877|4400
- 69282|0321
- -----+------
- 6928203225) 35595|407900
- 34641|016125
- -----+--------
- 69282032301) 954|39177500
- 692|82032301
- ---+----------
- 692820323023) 261|5714519900
- 207|8460969069
- ---+----------
- 53|7253550831
-
- B
- 692820323026) 537253550831(77545870549
- 484974226118
- ------------
- 52279324713
- 48497422611
- -----------
- 3781902102
- 3464101615
- ----------
- 317800487
- 277128129
- ---------
- 40672358
- 34641016
- --------
- 6031342
- 5542562
- -------
- 488780
- 484974
- ------
- 3806
- 3464
- ----
- 342
- 277
- ---
- 65
- 62
- --
- 3
-
-If from any remainder we cut off the ciphers, and all figures which
-would come under or on the right of these ciphers, by a vertical line,
-we find on the left of that line a contracted division, such as those
-in (155). Thus, after having found the root as far as 3·464101, we
-have the remainder 4261799, and the divisor 6928202. The figures on
-the left of the line are nothing more than the contracted division of
-this remainder by the divisor, with this difference, however, that we
-have to begin by striking a figure off the divisor, instead of using
-the whole divisor once, and then striking off the first figure. By this
-alone we might have doubled our number of decimal places, and got the
-additional figures 615137, the last 7 being obtained by carrying the
-contracted division one step further with the remainder 53. We have,
-then, this rule: When half the number of decimal places have been
-obtained, instead of annexing two ciphers to the remainder, strike off
-a figure from what would be the divisor if the process were continued
-at length, and divide the remainder by this contracted divisor, as in
-(155).
-
-As an example, let us double the number of decimal places already
-obtained, which are contained in 3·46410161513. The remainder is
-537253550831, the divisor 692820323026, and the process is as in (B).
-Hence the square root of 12 is,
-
- 3·4641016151377545870549;
-
-which is true to the last figure, and a little too great; but the
-substitution of 8 instead of 9 on the right hand would make it too
-small.
-
-
-EXERCISES.
-
- Numbers. | Square roots.
- ·001728 | ·0415692194
- 64·34 | 8·02122185
- 8074 | 89·8554394
- 10 | 3·16227766
- 1·57 | 1·2529964086141667788495
-
-
-
-
-SECTION VIII.
-
-ON THE PROPORTION OF NUMBERS.
-
-
-170. When two numbers are named in any problem, it is usually
-necessary, in some way or other, to compare the two; that is, by
-considering the two together, to establish some connexion between
-them, which may be useful in future operations. The first method
-which suggests itself, and the most simple, is to observe which is
-the greater, and by how much it differs from the other. The connexion
-thus established between two numbers may also hold good of two other
-numbers; for example, 8 differs from 19 by 11, and 100 differs from
-111 by the same number. In this point of view, 8 stands to 19 in the
-same situation in which 100 stands to 111, the first of both couples
-differing in the same degree from the second. The four numbers thus
-noticed, viz.:
-
- 8, 19, 100, 111,
-
-are said to be in _arithmetical[26] proportion_. When four numbers are
-thus placed, the first and last are called the _extremes_, and the
-second and third the _means_. It is obvious that 111 + 8 = 100 + 19,
-that is, the sum of the extremes is equal to the sum of the means.
-And this is not accidental, arising from the particular numbers we
-have taken, but must be the case in every arithmetical proportion; for
-in 111 + 8, by (35), any diminution of 111 will not affect the sum,
-provided a corresponding increase be given to 8; and, by the definition
-just given, one mean is as much less than 111 as the other is greater
-than 8.
-
-[26] This is a very incorrect name, since the term ‘arithmetical’
-applies equally to every notion in this book. It is necessary, however,
-that the pupil should use words in the sense in which they will be used
-in his succeeding studies.
-
-171. A set or series of numbers is said to be in _continued_
-arithmetical proportion, or in arithmetical _progression_, when the
-difference between every two succeeding terms of the series is the
-same. This is the case in the following series:
-
- 1, 2, 3, 4, 5, &c.
- 3, 6, 9, 12, 15, &c.
- (1½), 2, (2½), 3, (3½), &c.
-
-The difference between two succeeding terms is called the common
-difference. In the three series just given, the common differences are,
-1, 3, and ½.
-
-172. If a certain number of terms of any arithmetical series be taken,
-the sum of the first and last terms is the same as that of any other
-two terms, provided one is as distant from the beginning of the series
-as the other is from the end. For example, let there be 7 terms, and
-let them be,
-
- _a_ _b_ _c_ _d_ _e_ _f_ _g_.
-
-Then, since, by the nature of the series, _b_ is as much above _a_ as
-_f_ is below _g_ (170), _a_ + _g_ = _b_ + _f_. Again, since _c_ is as
-much above _b_ as _e_ is below _f_ (170), _b_ + _f_ = _c_ + _e_. But
-_a_ + _g_ = _b_ + _f_; therefore _a_ + _g_ = _c_ + _e_, and so on.
-Again, twice the middle term, or the term equally distant from the
-beginning and the end (which exists only when the number of terms is
-odd), is equal to the sum of the first and last terms; for since _c_
-is as much below _d_ as _e_ is above it, we have _c_ + _e_ = _d_ + _d_
-= 2_d_. But _c_ + _e_ = _a_ + _g_; therefore, _a_ + _g_ = 2_d_. This
-will give a short rule for finding the sum of any number of terms of
-an arithmetical series. Let there be 7, viz. those just given. Since
-_a_ + _g_, _b_ + _f_, and _c_ + _e_, are the same, their sum is three
-times (_a_ + _g_), which with _d_, the middle term, or half _a_ + _g_,
-is three times and a half (_a_ + _g_), or the sum of the first and
-last terms multiplied by (3½), or ⁷/₂, or half the number of terms. If
-there had been an even number of terms, for example, six, viz. _a_,
-_b_, _c_, _d_, _e_, and _f_, we know now that _a_ + _f_, _b_ + _e_, and
-_c_ + _d_, are the same, whence the sum is three times (_a_ + _f_), or
-the sum of the first and last terms multiplied by half the number of
-terms, as before. The rule, then, is: To sum any number of terms of an
-arithmetical progression, multiply the sum of the first and last terms
-by half the number of terms. For example, what are 99 terms of the
-series 1, 2, 3, &c.? The 99th term is 99, and the sum is
-
- 99 100 × 99
- (99 + 1)---, or --------, or 4950.
- 2 2
-
-The sum of 50 terms of the series
-
- 1 2 4 5 ( 1 50 ) 50
- ---, ---, 1, ---, ---, 2, &c. is (--- + ---)---,
- 3 3 3 3 ( 3 3 ) 2
-
-or 17 × 25, or 425.
-
-173. The first term being given, and also the common difference and
-number of terms, the last term may be found by adding to the first term
-the common difference multiplied by one less than the number of terms.
-For it is evident that the second term differs from the first by the
-common difference, the _third_ term by _twice_, the _fourth_ term by
-_three_ times the common difference; and so on. Or, the passage from
-the first to the _n_th term is made by _n_-1 steps, at each of which
-the common difference is added.
-
-EXERCISES.
-
- _Given._ | _To find._
- Series. |No. of terms.| Last term. | Sum.
- 4, (6½), 9, &c. | 33 | 84 | 1452
- 1, 3, 5, &c. | 28 | 55 | 784
- 2, 20, 38, &c. | 100,000 | 1799984 | 89999300000
-
-174. The sum being given, the number of terms, and the first term,
-we can thence find the common difference. Suppose, for example, the
-first term of a series to be one, the number of terms 100, and the sum
-10,000. Since 10,000 was made by multiplying the sum of the first and
-last terms by ¹⁰⁰/₂, if we divide by this, we shall recover the sum
-of the first and last terms. Now, ¹⁰,⁰⁰⁰/₁ divided by ¹⁰⁰/₂ is (122)
-200, and the first term being 1, the last term is 199. We have then to
-pass from 1 to 199, or through 198, by 99 equal steps. Each step is,
-therefore, ¹⁹⁸/⁹⁹, or 2, which is the common difference; or the series
-is 1, 3, 5, &c., up to 199.
-
- _Given._ | _To find._
- Sum. |No. of terms.|First term.|Last term.|Common diff.
- 1809025 | 1345 | 1 | 2689 | 2
- 44 | 10 | 3 | ²⁹/₅ | ¹⁴/₄₅
- 7075600 | 1330 | 4 | 10636 | 8
-
-175. We now return to (170), in which we compared two numbers together
-by their difference. This, however, is not the method of comparison
-which we employ in common life, as any single familiar instance will
-shew. For example, we say of A, who has 10 thousand pounds, that he is
-much richer than B, who has only 3 thousand; but we do not say that
-C, who has 107 thousand pounds, is much richer than D, who has 100
-thousand, though the difference of fortune is the same in both cases,
-viz. 7 thousand pounds. In comparing numbers we take into our reckoning
-not only the differences, but the numbers themselves. Thus, if B and D
-both received 7 thousand pounds, B would receive 233 pounds and a third
-for every 100 pounds which he had before, while D for every 100 pounds
-would receive only 7 pounds. And though, in the view taken in (170), 3
-is as near to 10 as 100 is to 107, yet, in the light in which we now
-regard them, 3 is not so near to 10 as 100 is to 107, for 3 differs
-from 10 by more than twice itself, while 100 does not differ from 107
-by so much as one-fifth of itself. This is expressed in mathematical
-language by saying, that the _ratio_ or _proportion_ of 10 to 3 is
-greater than the _ratio_ or _proportion_ of 107 to 100. We proceed to
-define these terms more accurately.
-
-176. When we use the term _part_ of a number or fraction in the
-remainder of this section, we mean, one of the various sets of _equal_
-parts into which it may be divided, either the half, the third, the
-fourth, &c.: the term multiple has been already explained (102). By
-the term _multiple-part_ of a number we mean, the abbreviation of the
-words _multiple of a part_. Thus, 1, 2, 3, 4, and 6, are parts of 12;
-½ is also a part of 12, being contained in it 24 times; 12, 24, 36,
-&c., are multiples of 12; and 8, 9, ⁵/₂, &c. are multiple parts of 12,
-being multiples of some of its parts. And when multiple parts generally
-are spoken of, the parts themselves are supposed to be included, on
-the same principle that 12 is counted among the multiples of 12, the
-multiplier being 1. The multiples themselves are also included in this
-term; for 24 is also 48 halves, and is therefore among the multiple
-parts of 12. Each part is also in various ways a multiple-part; for
-one-fourth is two-eighths, and three-twelfths, &c.
-
-177. Every number or fraction is a multiple-part of every other number
-or fraction. If, for example, we ask what part 12 is of 7, we see
-that on dividing 7 into 7 parts, and repeating one of these parts 12
-times, we obtain 12; or, on dividing 7 into 14 parts, each of which
-is one-half, and repeating one of these parts 24 times, we obtain 24
-halves, or 12. Hence, 12 is ¹²/₇, or ²⁴/₁₄, or ³⁶/₂₁ of 7; and so on.
-Generally, when _a_ and _b_ are two whole numbers, _a_/_b_ expresses
-the multiple-part which _a_ is of _b_, and _b_/_a_ that which _b_ is
-of _a_. Again, suppose it required to determine what multiple-part
-(2⅐) is of (3⅕), or ¹⁵/₇ of ¹⁶/₅. These fractions, reduced to a common
-denominator, are ⁷⁵/₃₅ and ¹¹²/₃₅, of which the second, divided into
-112 parts, gives ¹/₃₅, which repeated 75 times gives ⁷⁵/₃₅, the first.
-Hence, the multiple-part which the first is of the second is ⁷⁵/₁₁₂,
-which being obtained by the rule given in (121), shews that _a_/_b_, or
-_a_ divided by _b_, according to the notion of division there given,
-expresses the multiple-part which _a_ is of _b_ in every case.
-
-178. When the first of four numbers is the same multiple-part of the
-second which the third is of the fourth, the four are said to be
-_geometrically[27] proportional_, or simply _proportional_. This is
-a word in common use; and it remains to shew that our mathematical
-definition of it, just given, is, in fact, the common notion attached
-to it. For example, suppose a picture is copied on a smaller scale,
-so that a line of two inches long in the original is represented by a
-line of one inch and a half in the copy; we say that the copy is not
-correct unless all the parts of the original are reduced in the same
-proportion, namely, that of 2 to (1½). Since, on dividing two inches
-into 4 parts, and taking 3 of them, we get (1½), the same must be done
-with all the lines in the original, that is, the length of any line in
-the copy must be three parts out of four of its length in the original.
-Again, interest being at 5 per cent, that is, £5 being given for the
-use of £100, a similar proportion of every other sum would be given;
-the interest of £70, for example, would be just such a part of £70 as
-£5 is of £100.
-
-[27] The same remark may be made here as was made in the note on the
-term ‘arithmetical proportion,’ page 101. The word ‘geometrical’ is,
-generally speaking, dropped, except when we wish to distinguish between
-this kind of proportion and that which has been called arithmetical.
-
-Since, then, the part which _a_ is of _b_ is expressed by the fraction
-_a_/_b_, or any other fraction which is equivalent to it, and that
-which _c_ is of _d_ by _c_/_d_, it follows, that when _a_, _b_, _c_,
-and _d_, are proportional, _a_/_b_ = _c_/_d_. This equation will be
-the foundation of all our reasoning on proportional quantities; and
-in considering proportionals, it is necessary to observe not only the
-quantities themselves, but also the order in which they come. Thus,
-_a_, _b_, _c_, and _d_, being proportionals, that is, _a_ being the
-same multiple-part of _b_ which _c_ is of _d_, it does not follow that
-_a_, _d_, _b_, and _c_ are proportionals, that is, that _a_ is the
-same multiple-part of _d_ which _b_ is of _c_. It is plain that _a_ is
-greater than, equal to, or less than _b_, according as _c_ is greater
-than, equal to, or less than _d_.
-
-179. Four numbers, _a_, _b_, _c_, and _d_, being proportional in the
-order written, _a_ and _d_ are called the _extremes_, and _b_ and _c_
-the _means_, of the proportion. For convenience, we will call the two
-extremes, or the two means, _similar_ terms, and an extreme and a mean,
-_dissimilar_ terms. Thus, _a_ and _d_ are similar, and so are _b_ and
-_c_; while _a_ and _b_, _a_ and _c_, _d_ and _b_, _d_ and _c_, are
-dissimilar. It is customary to express the proportion by placing dots
-between the numbers, thus:
-
- _a_ : _b_ ∷ _c_ : _d_
-
-180. Equal numbers will still remain equal when they have been
-increased, diminished, multiplied, or divided, by equal quantities.
-This amounts to saying that if
-
- _a_ = _b_ and _p_ = _q_,
-
- _a_ + _p_ = _b_ + _q_,
-
- _a_ - _p_ = _b_ - _q_,
-
- _ap_ = _bq_,
-
- _a_ _b_
- and --- = ---.
- _p_ _q_
-
-It is also evident, that _a_ + _p_-_p_, _a_ -_p_ + _p_, _ap_/_p_, and
-_a_/_p_ × _p_, are all equal to _a_.
-
-181. The product of the extremes is equal to the product of the means.
-Let _a_/_b_ = _c_/_d_, and multiply these equal numbers by the product
-_bd_. Then,
-
- _a_ _abd_
- --- × _bd_ = ----- (116) = _ad_,
- _b_ _b_
-
- _c_ _cbd_
- and --- × _bd_ = ----- = _cb_: hence (180), _ad_ = _bc_.
- _d_ _d_
-
-Thus, 6, 8, 21, and 28, are proportional, since
-
- 6 3 3 × 7 21
- --- = --- = ------ = --- (180);
- 8 4 4 × 7 28
-
-and it appears that 6 × 28 = 8 × 21, since both products are 168.
-
-182. If the product of two numbers be equal to the product of two
-others, these numbers are proportional in any order whatever, provided
-the numbers in the same product are so placed as to be similar terms;
-that is, if _ab_ = _pq_, we have the following proportions:--
-
- _a_ : _p_ ∷ _q_ : _b_
- _a_ : _q_ ∷ _p_ : _b_
- _b_ : _p_ ∷ _q_ : _a_
- _b_ : _q_ ∷ _p_ : _a_
- _p_ : _a_ ∷ _b_ : _q_
- _p_ : _b_ ∷ _a_ : _q_
- _q_ : _a_ ∷ _b_ : _p_
- _q_ : _b_ ∷ _a_ : _p_
-
-To prove any one of these, divide both _ab_ and _pq_ by the product of
-its second and fourth terms; for example, to shew the truth of _a_: _q_
-∷ _p_: _b_, divide both _ab_ and _pq_ by _bq_. Then,
-
- _ab_ _a_ _pq_ _p_
- ---- = ---, and ---- = ---; hence (180),
- _bq_ _q_ _bq_ _b_
-
- _a_ _p_
- --- = ---, or _a_ : _q_ ∷ _p_ : _b_.
- _q_ _b_
-
-The pupil should not fail to prove every one of the eight cases, and to
-verify them by some simple examples, such as 1 × 6 = 2 × 3, which gives
-1: 2 ∷ 3: 6, 3: 1 ∷ 6: 2, &c.
-
-183. Hence, if four numbers be proportional, they are also proportional
-in any other order, provided it be such that similar terms still remain
-similar. For since, when
-
- _a_ _c_
- --- = ---,
- _b_ _d_
-
-it follows (181) that _ad_ = _bc_, all the proportions which follow
-from _ad_ = _bc_, by the last article, follow also from
-
- _a_ _c_
- --- = ---,
- _b_ _d_
-
-184. From (114) it follows that
-
- _a_ _b_ + _a_
- 1 + --- = ---------,
- _b_ _b_
-
- _a_
- and if --- be less than 1,
- _b_
-
- _a_ _b_ - _a_
- 1 - --- = ---------,
- _b_ _b_
-
- _a_
- while if --- be greater than 1,
- _b_
-
- _a_ _a_ - _b_
- --- - 1 = ---------.
- _b_ _b_
-
- _a_ + _b_ _a_ - _b_
- Also (122), if --------- be divided by ---------
- _b_ _b_
-
- _a_ + _b_
- the result is ---------.
- _a_ - _b_
-
-Hence, _a_, _b_, _c_, and _d_, being proportionals, we may obtain other
-proportions, thus:
-
- _a_ _c_
- Let --- = ---
- _b_ _d_
-
- _a_ _c_
- Then (114) 1 + --- = 1 + ---
- _b_ _d_
-
- _a_ + _b_ _c_ + _d_
- or --------- = ---------
- _b_ _d_
-
-or _a_ + _b_: _b_ ∷ _c_ + _d_: _d_
-
-That is, the sum of the first and second is to the second as the sum of
-the third and fourth is to the fourth. For brevity, we shall not state
-in words any more of these proportions, since the pupil will easily
-supply what is wanting.
-
-Resuming the proportion _a_: _b_ ∷ _c_: _d_
-
- _a_ _c_
- or --- = ---
- _b_ _d_
-
- _a_ _c_ _a_
- 1 - --- = 1 - ---, if --- be less than 1,
- _b_ _d_ _b_
-
- _b_ - _a_ _d_ - _c_
- or --------- = ---------
- _b_ _d_
-
-that is, _b_-_a_: _b_ ∷ _d_-_c_: _d_ or, _a_-_b_: _b_ ∷ _c_-_d_: _d_,
-
- _a_
- if --- be greater than 1.
- _b_
-
- _a_ + _b_ _c_ + _d_
- Again, since --------- = ---------
- _b_ _d_
-
- _a_ - _b_ _c_ - _d_ _a_
- and --------- = --------- (--- being greater than 1)
- _b_ _d_ _b_
-
- _a_ + _b_ _c_ + _d_
- dividing the first by the second we have --------- = ----------,
- _a_ - _b_ _c_ - _d_
-
- or _a_ + _b_ : _a_ - _b_ ∷ _c_ + _d_ : _c_ - _d_
-
- and also _a_ + _b_ : _b_ - _a_ ∷ _c_ + _d_ : _d_ - _c_,
-
- _a_
- if --- be less than 1.
- _b_
-
-185. Many other proportions might be obtained in the same manner. We
-will, however, content ourselves with writing down a few which can be
-obtained by combining the preceding articles.
-
- _a_ + _b_ : _a_ ∷ _c_ + _d_ : _c_
- _a_ : _a_ - _b_ ∷ _c_ : _c_ - _d_
- _a_ + _c_ : _a_ - _c_ ∷ _b_ + _d_ : _b_ - _d_.
-
-In these and all others it must be observed, that when such expressions
-as _a_-_b_ and _c_-_d_ occur, it is supposed that _a_ is greater than
-_b_, and _c_ greater than _d_.
-
-186. If four numbers be proportional, and any two dissimilar terms be
-both multiplied, or both divided by the same quantity, the results are
-proportional. Thus, if _a_: _b_ ∷ _c_: _d_, and _m_ and _n_ be any two
-numbers, we have also the following:
-
- _ma_ : _b_ ∷ _mc_ : _d_
-
- _a_ : _mb_ ∷ _c_ : _md_
-
- _a_ _c_
- --- : _mb_ ∷ --- : _md_
- _n_ _n_
-
- _ma_ : _nb_ ∷ _mc_ : _nd_
-
- _a_ _b_ _c_ _d_
- --- : --- ∷ --- : ---
- _m_ _m_ _m_ _m_
-
- _a_ _b_ _c_ _d_
- --- : --- ∷ --- : ---
- _m_ _m_ _n_ _n_
-
-and various others. To prove any one of these, recollect that nothing
-more is necessary to make four numbers proportional except that the
-product of the extremes should be equal to that of the means. Take the
-third of those just given; the product of its extremes is
-
-
- _a_ _mad_
- --- × _md_, or -----,
- _n_ _n_
-
- _c_ _mbc_
- while that of the means is _mb_ × ---, or -----.
- _n_ _n_
-
- But since _a_ : _b_ ∷ _c_ : _d_, by (181) _ad_ = _bc_,
-
- _mad_ _mbc_
- whence, by (180), _mad_ = _mbc_, and ----- = -----.
- _n_ _n_
-
- _a_ _c_
- Hence, ---, _mb_, ---, and _md_, are proportionals.
- _n_ _n_
-
-187. If the terms of one proportion be multiplied by the terms of a
-second, the products are proportional; that is, if _a_: _b_ ∷ _c_:
-_d_, and _p_: _q_ ∷ _r_: _s_, it follows that _ap_: _bq_ ∷ _cr_: _ds_.
-For, since _ad_ = _bc_, and _ps_ = _qr_, by (180) _adps_ = _bcqr_, or
-_ap_ × _ds_ = _bq_ × _cr_, whence (182) _ap_: _bq_ ∷ _cr_: _ds_.
-
-188. If four numbers be proportional, any similar powers of these
-numbers are also proportional; that is, if
-
- _a_ : _b_ ∷ _c_ : _d_
- Then _aa_ : _bb_ ∷ _cc_ : _dd_
- _aaa_ : _bbb_ ∷ _ccc_ : _ddd_
- &c. &c.
-
-For, if we write the proportion twice, thus,
-
- _a_ : _b_ ∷ _c_ : _d_
- _a_ : _b_ ∷ _c_ : _d_
- by (187) _aa_ : _bb_ ∷ _cc_ : _dd_
- But _a_ : _b_ ∷ _c_ : _d_
- Whence (187) _aaa_ : _bbb_ ∷ _ccc_ : _ddd_; and so on.
-
-189. An expression is said to be homogeneous with respect to any two or
-more letters, for instance, _a_, _b_, and _c_, when every term of it
-contains the same number of letters, counting _a_, _b_, and _c_ only.
-Thus, _maab_ + _nabc_ + _rccc_ is homogeneous with respect to _a_, _b_,
-and _c_; and of the third degree, since in each term there is either
-_a_, _b_, and _c_, or one of these repeated alone, or with another, so
-as to make three in all. Thus, 8_aaabc_, 12_abccc_, _maaaaa_, _naabbc_,
-are all homogeneous, and of the fifth degree, with respect to _a_, _b_,
-and _c_ only; and any expression made by adding or subtracting these
-from one another, will be homogeneous and of the fifth degree. Again
-_ma_ + _mnb_ is homogeneous with respect to _a_ and _b_, and of the
-first degree; but it is not homogeneous with respect to _m_ and _n_,
-though it is so with respect to _a_ and _n_. This being premised, we
-proceed to a theorem,[28] which will contain all the results of (184),
-(185), and (188).
-
-[28] A theorem is a general mathematical fact: thus, that every number
-is divisible by four when its last two figures are divisible by four,
-is a theorem; that in every proportion the product of the extremes is
-equal to the product of the means, is another.
-
-190. If any four numbers be proportional, and if from the first two,
-_a_ and _b_, any two homogeneous expressions of the same degree be
-formed; and if from the last two, two other expressions be formed, in
-precisely the same manner, the four results will be proportional. For
-example, if _a_: _b_ ∷ _c_: _d_, and if 2_aaa_ + 3_aab_ and _bbb_ +
-_abb_ be chosen, which are both homogeneous with respect to _a_ and
-_b_, and both of the third degree; and if the corresponding expressions
-2_ccc_ + 3_ccd_ and _ddd_ + _cdd_ be formed, which are made from _c_
-and _d_ precisely in the same manner as the two former ones from _a_
-and _b_, then will
-
- 2_aaa_ + 3_aab_ : _bbb_ + _abb_ ∷ 2_ccc_ + 3_ccd_ : _ddd_ + _cdd_
-
- _a_
- To prove this, let --- be called _x_.
- _b_
-
- _a_ _a_ _c_
- Then, since --- = _x_, and --- = ---,
- _b_ _b_ _d_
-
- _c_
- it follows that --- = _x_.
- _d_
-
-But since _a_ divided by _b_ gives _x_, _x_ multiplied by _b_ will give
-_a_, or _a_ = _bx_. For a similar reason, _c_ = _dx_. Put _bx_ and _dx_
-instead of _a_ and _c_ in the four expressions just given, recollecting
-that when quantities are multiplied together, the result is the same
-in whatever order the multiplications are made; that, for example,
-_bxbxbx_ is the same as _bbbxxx_.
-
- Hence, 2_aaa_ + 3_aab_ = 2_bxbxbx_ + 3_bxbxb_
- = 2_bbbxxx_ + 3_bbbxx_
-
- which is _bbb_ multiplied by 2_xxx_ + 3_xx_
- or _bbb_ (2_xxx_ + 3_xx_)[29]
-
- Similarly, 2_ccc_ + 3_ccd_ = _ddd_ (2_xxx_ + 3_xx_)
- Also, _bbb_ + _abb_ = _bbb_ + _bxbb_
- = _bbb_ multiplied by 1 + _x_
- or _bbb_(1 + _x_)
-
- Similarly, _ddd_ + _cdd_ = _ddd_ (1 + _x_)
- Now, _bbb_ : _bbb_ ∷ _ddd_ : _ddd_
-
-[29] If _bx_ be substituted for _a_ in any expression which is
-homogeneous with respect to _a_ and _b_, the pupil may easily see
-that _b_ must occur in every term as often as there are units in the
-degree of the expression: thus, _aa_ + _ab_ becomes _bxbx_ + _bxb_ or
-_bb_(_xx_ + _x_); _aaa_ + _bbb_ becomes _bxbxbx_ + _bbb_ or _bbb_(_xxx_
-+ 1); and so on.
-
-Whence (186), _bbb_(2_xxx_ + 3_xx_): _bbb_(1 + _x_) ∷ _ddd_(2_xxx_ +
-3_xx_): _ddd_(1 + _x_), which, when instead of these expressions their
-equals just found are substituted, becomes 2_aaa_ + 3_aab_: _bbb_ +
-_abb_ ∷ 2_ccc_ + 3_ccd_: _ddd_ + _cdd_.
-
-The same reasoning may be applied to any other case, and the pupil may
-in this way prove the following theorems:
-
- If _a_ : _b_ ∷ _c_ : _d_
- 2_a_ + 3_b_ : _b_ ∷ 2_c_ + 3_d_ : _d_
- _aa_ + _bb_ : _aa_ - _bb_ ∷ _cc_ + _dd_ : _cc_ - _dd_
- _mab_ : 2_aa_ + _bb_ ∷ _mcd_ : 2_cc_ + _dd_
-
-191. If the two means of a proportion be the same, that is, if _a_ :
-_b_ ∷ _b_: _c_, the three numbers, _a_, _b_, and _c_, are said to be in
-_continued_ proportion, or in _geometrical progression_. The same terms
-are applied to a series of numbers, of which any three that follow one
-another are in continued proportion, such as
-
- 1 2 4 8 16 32 64 &c.
-
- 2 2 2 2 2 2
- 2 --- --- --- --- ---- ---- &c.
- 3 9 27 81 243 729
-
-Which are in continued proportion, since
-
- 2 2 2
- 1 : 2 ∷ 2 : 4 2 : --- ∷ --- : ---
- 3 3 9
-
- 2 2 2 2
- 2 : 4 ∷ 4 : 8 --- : --- ∷ --- : ---
- 3 9 9 27
- &c. &c.
-
-192. Let _a_, _b_, _c_, _d_, _e_ be in continued proportion; we have
-then
-
- _a_ _b_
- _a_ : _b_ ∷ _b_ : _c_ or --- = --- or _ac_ = _bb_
- _b_ _c_
-
- _b_ _c_
- _b_ : _c_ ∷ _c_ : _d_ --- = --- _bd_ = _cc_
- _c_ _d_
-
- _c_ _d_
- _c_ : _d_ ∷ _d_ : _e_ --- = --- _ce_ = _dd_
- _d_ _e_
-
-Each term is formed from the preceding, by multiplying it by the same
-number. Thus,
-
- _b_ _c_
- _b_ = --- × _a_ (180); _c_ = ---× _b_;
- _a_ _b_
-
- _a_ _b_ _b_ _c_ _b_
- and since --- = ---, --- = --- or _c_ = --- × _b_.
- _b_ _c_ _a_ _b_ _a_
-
- _d_ _d_ _c_ _b_
- Again, _d_ = --- × _c_, but --- = ---, which is = ---;
- _c_ _c_ _b_ _a_
-
- _b_
- therefore, _d_ = --- × _c_, and so on.
- _c_
-
- _b_
- If, then, ---
- _a_
-
-(which is called the _common ratio_ of the series) be denoted by _r_,
-we have
-
-_b_ = _ar_ _c_ = _br_ = _arr_ _d_ = _cr_ = _arrr_
-
-and so on; whence the series
-
- _a_ _b_ _c_ _d_ &c.
- is _a_ _ar_ _arr_ _arrr_ &c.
- Hence _a_ : _c_ ∷ _a_ : _arr_
- (186) ∷ _aa_ : _aarr_
- ∷ _aa_ : _bb_
-
-because, _b_ being _ar_, _bb_ is _arar_ or _aarr_. Again,
-
- _a_ : _d_ ∷ _a_ : _arrr_
- (186) ∷ _aaa_ : _aaarrr_
- ∷ _aaa_ : _bbb_
- Also _a_ : _e_ ∷ _aaaa_ : _bbbb_, and so on;
-
-that is, the first bears to the _n_ᵗʰ term from the first the same
-proportion as the _n_ᵗʰ power of the first to the _n_ᵗʰ power of the
-second.
-
-193. A short rule may be found for adding together any number of terms
-of a continued proportion. Let it be first required to add together the
-terms 1, _r_, _rr_, &c. where _r_ is greater than unity. It is evident
-that we do not alter any expression by adding or subtracting any
-numbers, provided we afterwards subtract or add the same. For example,
-
-_p_ = _p_-_q_ + _q_-_r_ + _r_- _s_ + _s_
-
-Let us take four terms of the series, 1, _r_, _rr_, &c. or,
-
-1 + _r_ + _rr_ + _rrr_
-
-It is plain that
-
-_rrrr_-1 = _rrrr_-_rrr_ + _rrr_-_rr_ + _rr_-_r_ + _r_-1
-
-Now (54), _rr_-_r_ = _r_(_r_-1), _rrr_ -_rr_ = _rr_(_r_-1),
-_rrrr_-_rrr_ = _rrr_(_r_-1), and the above equation becomes _rrrr_ -1 =
-_rrr_(_r_-1) + _rr_ (_r_-1) + _r_ (_r_-1) + _r_-1; which is (54) _rrr_
-+ _rr_ + _r_ + 1 taken _r_-1 times. Hence, _rrrr_-1 divided by _r_-1
-will give 1 + _r_ + _rr_ + _rrr_, the sum of the terms required. In
-this way may be proved the following series of equations:
-
- _rr_ - 1
- 1 + _r_ = --------
- _r_ - 1
-
- _rrr_ - 1
- 1 + _r_ + _rr_ = ---------
- _r_ - 1
-
- _rrrr_ - 1
- 1 + _r_ + _rr_ + _rrr_ = ----------
- _r_ - 1
-
- _rrrrr_ - 1
- 1 + _r_ + _rr_ + _rrr_ + _rrrr_ = -----------
- _r_ - 1
-
-If _r_ be less than unity, in order to find 1 + _r_ + _rr_ + _rrr_,
-observe that
-
- 1 - _rrrr_ = 1 - _r_ + _r_ - _rr_ + _rr_ - _rrr_ + _rrr_ - _rrrr_
-
- = 1 - _r_ + _r_(1 - _r_) + _rr_(1 - _r_) + _rrr_(1 - _r_);
-
-whence, by similar reasoning, 1 + _r_ + _rr_ + _rrr_ is found by
-dividing 1-_rrrr_ by 1-_r_; and equations similar to these just given
-may be found, which are,
-
- 1 - _rr_
- 1 + _r_ = --------
- 1 - _r_
-
- 1 - _rrr_
- 1 + _r_ + _rr_ = ---------
- 1 - _r_
-
- 1 - _rrrr_
- 1 + _r_ + _rr_ + _rrr_ = ----------
- 1 - _r_
-
- 1 - _rrrrr_
- 1 + _r_ + _rr_ + _rrr_ + _rrrr_ = -----------
- 1 - _r_
-
-The rule is: To find the sum of n terms of the series, 1 + _r_ + _rr_
-+ &c., divide the difference between 1 and the (_n_ + 1)ᵗʰ term by the
-difference between 1 and _r_.
-
-194. This may be applied to finding the sum of any number of terms of
-a continued proportion. Let _a_, _b_, _c_, &c. be the terms of which
-it is required to sum four, that is, to find _a_ + _b_ + _c_ + _d_, or
-(192) _a_ + _ar_ + _arr_ + _arrr_, or (54) a(1 + _r_ + _rr_ + _rrr_),
-which (193) is
-
- _rrrr_ - 1 1 - _rrrr_
- ---------- × _a_, or ---------- × _a_,
- _r_ - 1 1 - _r_
-
-according as _r_ is greater or less than unity. The first fraction is
-
- _arrrr_ - _a_ _e_ - _a_
- -------------, or (192) ---------.
- _r_ - 1 _r_ - 1
-
- _a_ - _e_
- Similarly, the second is ---------.
- 1 - _r_
-
-The rule, therefore, is: To sum _n_ terms of a continued proportion,
-divide the difference of the (_n_ + 1)ᵗʰ and first terms by the
-difference between unity and the common measure. For example, the
-sum of 10 terms of the series 1 + 3 + 9 + 27 + &c. is required. The
-eleventh term is 59049, and ⁽⁵⁹⁰⁴⁹ ⁻ ¹⁾/₍₃₋₁₎ is 29524. Again, the sum
-of 18 terms of the series 2 + 1 + ½ + ½ + &c. of which the nineteenth
-term is ¹/₁₃₁₀₇₂, is
-
- 1
- 2 - ------
- 131072 131070
- ----------- = 3 ------.
- 1 - ½ 131072
-
-EXAMPLES.
-
- 9 terms of 1 + 4 + 16 + &c. are 87381
-
- 6 12 847422675
- 10 ...... 3 + --- + ---- + &c. ... ---------
- 7 49 201768035
-
- 1 1 1 1048575
- 20 ...... --- + --- + --- + &c. ... -------
- 2 4 8 1048576
-
-195. The powers of a number or fraction greater than unity increase;
-for since 2½ is greater than 1, 2½ × 2½ is 2½ taken more than once,
-that is, is greater than 2½, and so on. This increase goes on without
-limit; that is, there is no quantity so great but that some power of
-2½ is greater. To prove this, observe that every power of 2½ is made
-by multiplying the preceding power by 2½, or by 1 + 1½, that is, by
-adding to the former power that power itself and its half. There will,
-therefore, be more added to the 10th power to form the 11th, than was
-added to the 9th power to form the 10th. But it is evident that if any
-given quantity, however small, be continually added to 2½, the result
-will come in time to exceed any other quantity that was also given,
-however great; much more, then, will it do so if the quantity added to
-2½ be increased at each step, which is the case when the successive
-powers of 2½ are formed. It is evident, also, that the powers of 1
-never increase, being always 1; thus, 1 × 1 = 1, &c. Also, if _a_ be
-greater than _m_ times _b_, the square of _a_ is greater than _mm_
-times the square of _b_. Thus, if _a_ = 2_b_ + _c_, where _a_ is
-greater than 2_b_, the square of _a_, or _aa_, which is (68) 4_bb_ +
-4_bc_ + _cc_ is greater than 4_bb_, and so on.
-
-196. The powers of a fraction less than unity continually decrease;
-thus, the square of ⅖, or ⅖ × ⅖, is less than ⅖, being only two-fifths
-of it. This decrease continues without limit; that is, there is no
-quantity so small but that some power of ⅖ is less. For if
-
- 5 2 1 1 1
- --- = _x_, --- = ---, and the powers of ⅖ are ----, -----,
- 2 5 _x_ _xx_ _xxx_
-
-and so on. Since _x_ is greater than 1 (195), some power of _x_ may be
-found which shall be greater than a given quantity. Let this be called
-_m_; then 1/_m_ is the corresponding power of ⅖; and a fraction whose
-denominator can be made as great as we please, can itself be made as
-small as we please (112).
-
-197. We have, then, in the series
-
-1 _r_ _rr_ _rrr_ _rrrr_ &c.
-
-I. A series of increasing terms, if _r_ be greater than 1. II. Of
-terms having the same value, if _r_ be equal to 1. III. A series of
-decreasing terms, if _r_ be less than 1. In the first two cases, the sum
-
-1 + _r_ + _rr_ + _rrr_ + &c.
-
-may evidently be made as great as we please, by sufficiently increasing
-the number of terms. But in the third this may or may not be the case;
-for though something is added at each step, yet, as that augmentation
-diminishes at every step, we may not certainly say that we can, by any
-number of such augmentations, make the result as great as we please. To
-shew the contrary in a simple instance, consider the series,
-
-1 + ½ + ¼ + ⅛ + ¹/₁₆ + &c.
-
-Carry this series to what extent we may, it will always be necessary to
-add the last term in order to make as much as 2. Thus,
-
- (1 + ½ + ¼) + ¼ = 1 + ½ + ½ = 1 + 1 = 2
- (1 + ½ + ¼ + ⅛) + ⅛ = 2.
- (1 + ½ + ¼ + ⅛ + ¹/₁₆) + ¹/₁₆ = 2, &c.
-
-But in the series, every term is only the half of the preceding;
-consequently no number of terms, however great, can be made as great as
-2 by adding one more. The sum, therefore, of 1, ½, ¼, ⅛ &c. continually
-approaches to 2, diminishing its distance from 2 at every step, but
-never reaching it. Hence, 2 is celled the _limit_ of 1 + ½ + ¼ + &c. We
-are not, therefore, to conclude that _every_ series of decreasing terms
-has a limit. The contrary may be shewn in the very simple series, 1 + ½
-+ ⅓ + ¼ + &c. which may be written thus:
-
- 1 + ½ + (⅓ + ¼) + (⅕ + ... up to ⅛) + (⅑ + ... up to ¹/₁₆)
- + (¹/₁₇ + ... up to ¹/₃₂) + &c.
-
-We have thus divided all the series, except the first two terms, into
-lots, each containing half as many terms as there are units in the
-denominator of its last term. Thus, the fourth lot contains 16 or ³²/₂2
-terms. Each of these lots may be shewn to be greater than ½. Take the
-third, for example, consisting of ⅑, ¹/₁₀, ¹/₁₁, ¹/₁₂, ¹/₁₃, ¹/₁₄,
-¹/₁₅, and ¹/₁₆. All except ¹/₁₆, the last, are greater than ¹/₁₆;
-consequently, by substituting ¹/₁₆ for each of them, the amount of the
-whole lot would be lessened; and as it would then become ⁸/₁₆, or ½,
-the lot itself is greater than ½. Now, if to 1 + ½, ½ be continually
-added, the result will in time exceed any given number. Still more will
-this be the case if, instead of ½, the several lots written above be
-added one after the other. But it is thus that the series 1 + ½ + ⅓,
-&c. is composed, which proves what was said, that this series has no
-limit.
-
-198. The series 1 + _r_ + _rr_ + _rrr_ + &c. always has a limit when
-_r_ is less than 1. To prove this, let the term succeeding that at
-which we stop be _a_, whence (194) the sum is
-
- 1 - _a_ 1 _a_
- -------, or (112) ------- - ------.
- 1 - _r_ 1 - _r_ 1 - _r_
-
-The terms decrease without limit (196), whence we may take a term so
-far distant from the beginning, that _a_, and therefore
-
- _a_
- -------,
- 1 - _r_
-
-shall be as small as we please. But it is evident that in this case
-
- 1 _a_
- ------- - ------- though always less than
- 1 - _r_ 1 - _r_
-
- 1 1
- -------- may be brought as near to -------
- 1 - _r_ 1 - _r_
-
-
-as we please; that is, the series 1 + _r_ + _rr_ + &c. continually
-approaches to the limit
-
- 1
- --------.
- 1 - _r_
-
-Thus 1 + ½ + ¼ + ⅛ + &c. where _r_ = ½, continually approaches to
-
- 1
- ----- or 2, as was shewn in the last article.
- 1 - ½
-
-EXERCISES.
-
- 2 2
- The limit of 2 + --- + --- + &c.
- 3 9
-
- 1 1
- or 2(1 + --- + --- + &c.) is 3
- 3 9
-
- 9 81
- ... 1 + --- + ---- + &c. ... 10
- 10 100
-
- 15 45
- ... 5 + ---- + ---- + &c. ... 8¾
- 7 49
-
-199. When the fraction _a_/_b_ is not equal to _c_/_d_, but greater,
-_a_ is said to have to _b_ a greater ratio than _c_ has to _d_; and
-when _a_/_b_ is less than _c_/_d_, _a_ is said to have to _b_ a less
-ratio than _c_ has to _d_. We propose the following questions as
-exercises, since they follow very simply from this definition.
-
-I. If _a_ be greater than _b_, and _c_ less than or equal to _d_, _a_
-will have a greater ratio to _b_ than _c_ has to _d_.
-
-II. If _a_ be less than _b_, and _c_ greater than or equal to _d_, _a_
-has a less ratio to _b_ than _c_ has to _d_.
-
-III. If _a_ be to _b_ as _c_ is to _d_, and if _a_ have a greater ratio
-to _b_ than _c_ has to _x_, _d_ is less than _x_; and if _a_ have a
-less ratio to _b_ than _c_ to _x_, _d_ is greater than _x_.
-
-IV. _a_ has to _b_ a greater ratio than _ax_ to _bx_ + _y_, and a less
-ratio than _ax_ to _bx_- _y_.
-
-200. If _a_ have to _b_ a greater ratio than _c_ has to _d_, _a_ + _c_
-has to _b_ + _d_ a less ratio than _a_ has to _b_, but a greater ratio
-than _c_ has to _d_; or, in other words, if _a_/_b_ be the greater of
-the two fractions _a_/_b_ and _c_/_d_,
-
- _a_ + _c_
- ---------
- _b_ + _d_
-
-will be greater than _c_/_d_, but less than _a_/_b_. To shew this,
-observe that (_mx_ + _ny_)/(_m_ + _n_) must lie between _x_ and _y_,
-if _x_ and _y_ be unequal: for if _x_ be the less of the two, it is
-certainly greater than
-
- _mx_ + _nx_
- ----------- or than _x_;
- _m_ + _n_
-
-and if _y_ be the greater of the two, it is certainly less than
-
- _my_ + _ny_
- -----------, or than _y_.
- _m_ + _n_
-
-It therefore lies between _x_ and _y_. Now let _a_/_b_ be _x_, and let
-_c_/_d_ be _y_: then _a_ = _bx_, _c_ = _dy_. Now
-
- _bx_ + _dy_
- -----------
- _b_ + _d_
-
-is something between _x_ and _y_, as was just proved; therefore
-
- _a_ + _c_
- ---------
- _b_ + _d_
-
-is something between _a_/_b_ and _c_/_d_. Again, since _a_/_b_ and
-_c_/_d_ are respectively equal to _ap_/_bp_ and _cq_/_dq_, and since,
-as has just been proved,
-
- _ap_ + _cq_
- -----------
- _bp_ + _dq_
-
-lies between the two last, it also lies between the two first; that is,
-if _p_ and _q_ be any numbers or fractions whatsoever,
-
- _ap_ + _cq_
- -----------
- _bp_ + _dq_
-
-lies between _a_/_b_ and _c_/_d_.
-
-201. By the last article we may often form some notion of the value of
-an expression too complicated to be easily calculated. Thus,
-
- 1 + _x_ 1 _x_ 1
- -------- lies between --- and ----, or 1 and ---;
- 1 + _xx_ 1 _xx_ _x_
-
- _ax_ + _by_ _ax_ _by_
- -------------- lies between ----- and ------,
- _axx_ + _bbyy_ _axx_ _bbyy_
-
-that is, between 1/_x_ and 1/_by_. And it has been shewn that (_a_ +
-_b_)/2 lies between _a_ and _b_, the denominator being considered as 1
-+ 1.
-
-202. It may also be proved that a fraction such as
-
- _a_ + _b_ + _c_ + _d_
- ---------------------
- _p_ + _q_ + _r_ + _s_
-
- _a_ _b_ _c_ _d_
- always lies among ---, ---, ---, and ---,
- _p_ _q_ _r_ _s_
-
-that is, is less than the greatest of them, and greater than the
-least. Let these fractions be arranged in order of magnitude; that is,
-let _a_/_p_ be greater than _b_/_q_, _b_/_q_ be greater than _c_/_r_,
-and _c_/_r_ greater than _d_/_s_. Then by (200)
-
- is and
- less greater
- _a_ + _b_ _a_ than than _b_ _c_
- --------- --- --- and ---
- _p_ + _q_ _p_ _q_ _r_
-
- _a_ + _b_ + _c_ _a_ + _b_ _a_ _c_ _d_
- --------------- --------- and --- --- and ---
- _p_ + _q_ + _r_ _p_ + _q_ _p_ _r_ _s_
-
- _a_ + _b_ + _c_ + _d_ _a_ + _b_ + _c_ _a_ _d_
- --------------------- --------------- and --- ---
- _p_ + _q_ + _r_ + _s_ _p_ + _q_ + _r_ _p_ _s_
-
-whence the proposition is evident.
-
-203. It is usual to signify “_a_ is greater than _b_” by _a_ > _b_ and
-“_a_ is less than _b_” by _a_ < _b_; the opening of V being turned
-towards the greater quantity. The pupil is recommended to make himself
-familiar with these signs.
-
-
-
-
-SECTION IX.
-
-ON PERMUTATIONS AND COMBINATIONS.
-
-
-204. If a number of counters, distinguished by different letters, be
-placed on the table, and any number of them, say four, be taken away,
-the question is, to determine in how many different ways this can be
-done. Each way of doing it gives what is called a _combination_ of
-four, but which might with more propriety be called a _selection_
-of four. Two combinations or selections are called different, which
-differ in any way whatever; thus, _abcd_ and _abce_ are different,
-_d_ being in one and _e_ in the other, the remaining parts being the
-same. Let there be six counters, _a_, _b_, _c_, _d_, _e_, and _f_;
-the combinations of three which can be made out of them are twenty in
-number, as follow:
-
- _abc_ _ace_ _bcd_ _bef_
-
- _abd_ _acf_ _bce_ _cde_
-
- _abe_ _ade_ _bcf_ _cdf_
-
- _abf_ _adf_ _bde_ _cef_
-
- _acd_ _aef_ _bdf_ _def_
-
-The combinations of four are fifteen in number, namely,
-
- _abcd_ _abde_ _acde_ _adef_ _bcef_
-
- _abce_ _abdf_ _acdf_ _bcde_ _bdcf_
-
- _abcf_ _abef_ _acef_ _bcdf_ _cdef_
-
-and so on.
-
-205. Each of these combinations may be written in several different
-orders; thus, _abcd_ may be disposed in any of the following ways:
-
- _abcd_ _acbd_ _acdb_ _abdc_ _adbc_ _adcb_
-
- _bacd_ _cabd_ _cadb_ _badc_ _dabc_ _dacb_
-
- _bcad_ _cbad_ _cdab_ _bdac_ _dbac_ _dcab_
-
- _bcda_ _cbda_ _cdba_ _bdca_ _dbca_ _dcba_
-
-of which no two are entirely in the same order. Each of these is
-said to be a distinct _permutation_ of _abcd_. Considered as a
-_combination_, they are all the same, as each contains _a_, _b_, _c_,
-and _d_.
-
-206. We now proceed to find how many _permutations_, each containing
-one given number, can be made from the counters in another given
-number, six, for example. If we knew how to find all the permutations
-containing four counters, we might make those which contain five
-thus: Take any one which contains four, for example, _abcf_ in which
-_d_ and _e_ are omitted; write _d_ and _e_ successively at the end,
-which gives _abcfd_, _abcfe_, and repeat the same process with every
-other permutation of four; thus, _dabc_ gives _dabce_ and _dabcf_.
-No permutation of five can escape us if we proceed in this manner,
-provided only we know those of four; for any given permutation of five,
-as _dbfea_, will arise in the course of the process from _dbfe_, which,
-according to our rule, furnishes _dbfea_. Neither will any permutation
-be repeated twice, for _dbfea_, if the rule be followed, can only
-arise from the permutation _dbfe_. If we begin in this way to find the
-permutations of two out of the six,
-
- _a_ _b_ _c_ _d_ _e_ _f_
-
-each of these gives five; thus,
-
- _a_ gives _ab_ _ac_ _ad_ _ae_ _af_
- _b_ ... _ba_ _bc_ _bd_ _be_ _bf_
-
-and the whole number is 6 × 5, or 30.
-
- Again, _ab_ gives _abc_ _abd_ _abe_ _abf_
- _ac_ ... _acb_ _acd_ _ace_ _acf_
-
-and here are 30, or 6 × 5 permutations of 2, each of which gives 4
-permutations of 3; the whole number of the last is therefore 6 × 5 × 4,
-or 120.
-
- Again, _abc_ gives _abcd_ _abce_ _abcf_
- _abd_ ... _abdc_ _abde_ _abdf_
-
-and here are 120, or 6 × 5 × 4, permutations of three, each of which
-gives 3 permutations of four; the whole number of the last is therefore
-6 × 5 × 4 × 3, or 360.
-
-In the same way, the number of permutations of 5 is 6 × 5 × 4 × 3 ×
-2, and the number of permutations of six, or the number of different
-ways in which the whole six can be arranged, is 6 × 5 × 4 × 3 × 2
-× 1. The last two results are the same, which must be; for since a
-permutation of five only omits one, it can only furnish one permutation
-of six. If instead of six we choose any other number, _x_, the number
-of permutations of two will be _x_(_x_-1), that of three will be
-_x_(_x_-1)(_x_-2), that of four _x_(_x_ -1)(_x_-2)(_x_-3), the rule
-being: Multiply the whole number of counters by the next less number,
-and the result by the next less, and so on, until as many numbers
-have been multiplied together as there are to be counters in each
-permutation: the product will be the whole number of permutations of
-the sort required. Thus, out of 12 counters, permutations of four may
-be made to the number of 12 × 11 × 10 × 9, or 11880.
-
-EXERCISES.
-
-207. In how many different ways can eight persons be arranged on eight
-seats?
-
-_Answer_, 40320.
-
-In how many ways can eight persons be seated at a round table, so that
-all shall not have the same neighbours in any two arrangements?[30]
-
-_Answer_, 5040.
-
-[30] The difference between this problem and the last is left to the
-ingenuity of the pupil.
-
-If the hundredth part of a farthing be given for every different
-arrangement which can be made of fifteen persons, to how much will the
-whole amount?
-
-_Answer_, £13621608.
-
-Out of seventeen consonants and five vowels, how many words can be
-made, having two consonants and one vowel in each?
-
-_Answer_, 4080.
-
-208. If two or more of the counters have the same letter upon them, the
-number of distinct permutations is less than that given by the last
-rule. Let there be _a_, _a_, _a_, _b_, _c_, _d_, and, for a moment,
-let us distinguish between the three as thus, _a_, _a′_, _a″_. Then,
-_abca′a″d_, and _a″bcaa′d_ are reckoned as distinct permutations in
-the rule, whereas they would not have been so, had it not been for the
-accents. To compute the number of distinct permutations, let us make
-one with _b_, _c_, and _d_, leaving places for the _a_s, thus, ( ) _bc_
-( ) ( ) _d_. If the _a_s had been distinguished as _a_, _a′_, _a″_,
-we might have made 3 × 2 × 1 distinct permutations, by filling up the
-vacant places in the above, all which six are the same when the _a_s
-are not distinguished. Hence, to deduce the number of permutations of
-_a_, _a_, _a_, _b_, _c_, _d_, from that of _aa′a″bcd_, we must divide
-the latter by 3 × 2 × 1, or 6, which gives
-
- 6 × 5 × 4 × 3 × 2 × 1
- --------------------- or 120.
- 3 × 2 × 1
-
-Similarly, the number of permutations of _aaaabbbcc_ is
-
- 9 × 8 × 7 × 6 × 5 × 4 × 3 × 2 × 1
- ---------------------------------
- 4 × 3 × 2 × 1 × 3 × 2 × 1 × 2 × 1.
-
-EXERCISE.
-
-How many variations can be made of the order of the letters in the word
-antitrinitarian?
-
-_Answer_, 126126000.
-
-209. From the number of permutations we can easily deduce the number of
-combinations. But, in order to form these combinations independently,
-we will shew a method similar to that in (206). If we know the
-combinations of two which can be made out of _a_, _b_, _c_, _d_, _e_,
-we can find the combinations of three, by writing successively at the
-end of each combination of two, the letters which come after the last
-contained in it. Thus, _ab_ gives _abc_, _abd_, _abe_; _ad_ gives _ade_
-only. No combination of three can escape us if we proceed in this
-manner, provided only we know the combinations of two; for any given
-combination of three, as _acd_, will arise in the course of the process
-from _ac_, which, according to our rule, furnishes _acd_. Neither will
-any combination be repeated twice, for _acd_, if the rule be followed,
-can only arise from _ac_, since neither _ad_ nor _cd_ furnishes it. If
-we begin in this way to find the combinations of the five,
-
- _a_ _b_ _c_ _d_ _e_
-
- _a_ gives _ab_ _ac_ _ad_ _ae_
- _b_ ···· _bc_ _bd_ _be_
- _c_ ···· _cd_ _ce_
- _d_ ···· _de_
-
- Of these, _ab_ gives _abc_ _abd_ _abe_
- _ac_ ···· _acd_ _ace_
- _ad_ ···· _ade_
- _bc_ ···· _bcd_ _bce_
- _bd_ ···· _bde_
- _cd_ ···· _cde_
- _ae_ _be_ _ce_ and _de_ give none.
-
- Of these, _abc_ gives _abcd_ _abce_
- _abd_ ···· _abde_
- _acd_ ···· _acde_
- _bcd_ ···· _bcde_
- Those which contain _e_ give none, as before.
-
-Of the last, _abcd_ gives _abcde_, and the others none, which is
-evidently true, since only one selection of five can be made out of
-five things.
-
-210. The rule for calculating the number of combinations is derived
-directly from that for the number of permutations. Take 7 counters;
-then, since the number of permutations of two is 7 × 6, and since two
-permutations, _ba_ and _ab_, are in any combination _ab_, the number of
-combinations is half that of the permutations, or (7 × 6)/2. Since the
-number of permutations of three is 7 × 6 × 5, and as each combination
-_abc_ has 3 × 2 × 1 permutations, the number of combinations of three is
-
- 7 × 6 × 5
- ----------.
- 1 × 2 × 3
-
-Also, since any combination of four, _abcd_, contains 4 × 3 × 2 × 1
-permutations, the number of combinations of four is
-
- 7 × 6 × 5 × 4
- -------------,
- 1 × 2 × 3 × 4
-
-and so on. The rule is: To find the number of combinations, each
-containing _n_ counters, divide the corresponding number of
-permutations by the product of 1, 2, 3, &c. up to _n_. If _x_ be the
-whole number, the number of combinations of two is
-
- _x_(_x_ - 1)
- -------------;
- 1 × 2
-
- that of three is
-
- _x_(_x_ - 1)(_x_ - 2)
- ---------------------;
- 1 × 2 × 3
-
- that of four is
-
- _x_(_x_ - 1)(_x_ - 2)(_x_ - 3)
- ------------------------------; and so on.
- 1 × 2 × 3 × 4
-
-211. The rule may in half the cases be simplified, as follows. Out of
-ten counters, for every distinct selection of seven which is taken, a
-distinct combination of 3 is left. Hence, the number of combinations
-of seven is as many as that of three. We may, therefore, find the
-combinations of three instead of those of seven; and we must moreover
-expect, and may even assert, that the two formulæ for finding these two
-numbers of combinations are the same in result, though different in
-form. And so it proves; for the number of combinations of seven out of
-ten is
-
- 10 × 9 × 8 × 7 × 6 × 5 × 4
- --------------------------,
- 1 × 2 × 3 × 4 × 5 × 6 × 7
-
-in which the product 7 × 6 × 5 × 4 occurs in both terms, and therefore
-may be removed from both (108), leaving
-
- 10 × 9 × 8
- ----------,
- 1 × 2 × 3
-
-which is the number of combinations of three out of ten. The same may
-be shewn in other cases.
-
-EXERCISES.
-
-How many combinations of four can be made out of twelve things?
-
-_Answer_, 495.
-
- What number { 6 } { 8 } { 28
- of combinations { 4 } out of { 11 } _Answer_, { 330
- can be made of { 26 } { 28 } { 378
- { 6 } { 15 } { 5005
-
-How many combinations can be made of 13 out of 52; or how many
-different hands may a person hold at the game of whist?
-
-_Answer_, 635013559600.
-
-
-
-
-BOOK II.
-
-COMMERCIAL ARITHMETIC.
-
-
-SECTION I.
-
-WEIGHTS, MEASURES, &C.
-
-
-212. In making the calculations which are necessary in commercial
-affairs, no more processes are required than those which have been
-explained in the preceding book. But there is still one thing
-wanted--not to insure the accuracy of our calculations, but to enable
-us to compare and judge of their results. We have hitherto made use of
-a single unit (15), and have treated of other quantities which are made
-up of a number of units, in Sections II., III., and IV., and of those
-which contain parts of that unit in Sections V. and VI. Thus, if we are
-talking of distances, and take a mile as the unit, any other length may
-be represented,[31] either by a certain number of miles, or a certain
-number of parts of a mile, and (1 meaning one mile) may be expressed
-either by a whole number or a fraction. But we can easily see that in
-many cases inconveniences would arise. Suppose, for example, I say,
-that the length of one room is ¹/₁₈₀ of a mile, and of another ¹/₁₇₄
-of a mile, what idea can we form as to how much the second is longer
-than the first? It is necessary to have some smaller measure; and if
-we divide a mile into 1760 equal parts, and call each of these parts a
-yard, we shall find that the length of the first room is 9 yards and
-⁷/₉ of a yard, and that of the second 10 yards and ¹⁰/₈₇ of a yard.
-From this we form a much better notion of these different lengths,
-but still not a very perfect one, on account of the fractions ⁷/₉ and
-¹⁰/₈₇. To get a clearer idea of these, suppose the yard to be divided
-into three equal parts, and each of these parts to be called a foot;
-then ⁷/₉ of a yard contains 2⅓ feet, and ¹⁰/₈₇ of a yard contains ³⁰/₈₇
-of a foot, or a little more than ⅓ of a foot. Therefore the length of
-the first room is now 9 yards, 2 feet, and ⅓ of a foot; that of the
-second is 10 yards and a little more than ⅓ of a foot. We see, then,
-the convenience of having large measures for large quantities, and
-smaller measures for small ones; but this is done for convenience only,
-for it is _possible_ to perform calculations upon any sort of quantity,
-with one measure alone, as certainly as with more than one; and not
-only possible, but more convenient, as far as the mere calculation is
-concerned.
-
-[31] It is not true, that if we choose any quantity as a unit, _any_
-other quantity of the same kind can be exactly represented either by
-a certain number of units, or of parts of a unit. To understand how
-this is proved, the pupil would require more knowledge than he can be
-supposed to have; but we can shew him that, for any thing he knows
-to the contrary, there may be quantities which are neither units nor
-parts of the unit. Take a mathematical line of one foot in length,
-divide it into ten parts, each of those parts into ten parts, and so
-on continually. If a point A be taken at hazard in the line, it does
-not appear self-evident that if the decimal division be continued
-ever so far, one of the points of division must at last fall exactly
-on A: neither would the same appear necessarily true if the division
-were made into sevenths, or elevenths, or in any other way. There may
-then possibly be a part of a foot which is no exact numerical fraction
-whatever of the foot; and this, in a higher branch of mathematics, is
-found to be the case times without number. What is meant in the words
-on which this note is written, is, that any part of a foot can be
-represented as nearly as we please by a numerical fraction of it; and
-this is sufficient for practical purposes.
-
-The measures which are used in this country are not those which would
-have been chosen had they been made all at one time, and by a people
-well acquainted with arithmetic and natural philosophy. We proceed
-to shew how the results of the latter science are made useful in
-our system of measures. Whether the circumstances introduced are
-sufficiently well known to render the following methods exact enough
-for the recovery of _astronomical_ standards, may be matter of opinion;
-but no doubt can be entertained of their being amply correct for
-commercial purposes.
-
-It is evidently desirable that weights and measures should always
-continue the same, and that posterity should be able to replace any
-one of them when the original measure is lost. It is true that a yard,
-which is now exact, is kept by the public authorities; but if this were
-burnt by accident,[32] how are those who shall live 500 years hence to
-know what was the length which their ancestors called a yard? To ensure
-them this knowledge, the measure must be derived from something which
-cannot be altered by man, either from design or accident. We find such
-a quantity in the time of the daily revolution of the earth, and also
-in the length of the year, both of which, as is shewn in astronomy,
-will remain the same, at least for an enormous number of centuries,
-unless some great and totally unknown change take place in the solar
-system. So long as astronomy is cultivated, it is impossible to suppose
-that either of these will be lost, and it is known that the latter is
-365·24224 mean solar days, or about 365¼ of the average interval which
-elapses between noon and noon, that is, between the times when the sun
-is highest in the heavens. Our year is made to consist of 365 days,
-and the odd quarter is allowed for by adding one day to every fourth
-year, which gives what we call leap-year. This is the same as adding ¼
-of a day to each year, and is rather too much, since the excess of the
-year above 365 days is not ·25 but ·24224 of a day. The difference is
-·00776 of a day, which is the quantity by which our average year is too
-long. This amounts to a day in about 128 years, or to about 3 days in 4
-centuries. The error is corrected by allowing only one out of four of
-the years which close the centuries to be leap-years. Thus, A.D. 1800
-and 1900 are not leap-years, but 2000 is so.
-
-[32] Since this was first written, the accident has happened. The
-_standard yard_ was so injured as to be rendered useless by the fire at
-the Houses of Parliament.
-
-213. The day is therefore the first measure obtained, and is divided
-into 24 parts or hours, each of which is divided into 60 parts or
-minutes, and each of these again into 60 parts or seconds. One second,
-marked thus, 1″,[33] is therefore the 86400ᵗʰ part of a day, and the
-following is the
-
-
-MEASURE OF TIME.[34]
-
- 60 _seconds_ are 1 _minute_ 1 m.
-
- 60 _minutes_ ” 1 _hour_ 1 h.
-
- 24 _hours_ ” 1 _day_ 1 d.
-
- 7 _days_ ” 1 _week_ 1 wk.
-
- 365 _days_ ” 1 _year_ 1 yr.
-
-214. The _second_ having been obtained, a pendulum can be constructed
-which shall, when put in motion, perform one vibration in exactly
-one second, in the latitude of Greenwich.[35] If we were inventing
-measures, it would be convenient to call the length of this pendulum a
-yard, and make it the standard of all our measures of length. But as
-there is a yard already established, it will do equally well to tell
-the length of the pendulum in yards. It was found by commissioners
-appointed for the purpose, that this pendulum in London was 39·1393
-inches, or about one yard, three inches, and ⁵/₃₆ of an inch. The
-following is the division of the yard.
-
-
-MEASURES OF LENGTH.
-
-The lowest measure is a barleycorn.[36]
-
- 3 _barleycorns_ are 1 _inch_ 1 in.
-
- 12 _inches_ 1 _foot_ 1 ft.
-
- 3 _feet_ 1 _yard_ 1 yd.
-
- 5½ _yards_ 1 _pole_ 1 po.
-
- 40 _poles_ or 220 _yards_ 1 _furlong_ 1 fur.
-
- 8 _furlongs_ or 1760 _yards_ 1 _mile_ 1 mi.
-
- Also 6 _feet_ 1 _fathom_ 1 fth.
-
- 69⅓ _miles_ 1 _degree_ 1 deg. or 1°.
-
-[33] The minute and second are often marked thus, 1′, 1″: but this
-notation is now almost entirely appropriated to the minute and second
-of _angular_ measure.
-
-[34] The measures in italics are those which it is most necessary that
-the student should learn by heart.
-
-[35] The lengths of the pendulums which will vibrate in one second are
-slightly different in different latitudes. Greenwich is chosen as the
-station of the Royal Observatory. We may add, that much doubt is now
-entertained as to the system of standards derived from nature being
-capable of that extreme accuracy which was once attributed to it.
-
-[36] The inch is said to have been originally obtained by putting
-together three grains of barley.
-
-A geographical mile is ¹/₆₀th of a degree, and three such miles are one
-nautical league.
-
-In the measurement of cloth or linen the following are also used:
-
- 2¼ inches are 1 nail 1 nl.
- 4 nails 1 quarter (of a yard) 1 qr.
- 3 quarters 1 Flemish ell 1 Fl. e.
- 5 quarters 1 English ell 1 E. e.
- 6 quarters 1 French ell 1 Fr. e.
-
-
-215. MEASURES OF SURFACE, OR SUPERFICIES.
-
-All surfaces are measured by square inches, square feet, &c.; the
-square inch being a square whose side is an inch in length, and so on.
-The following measures may be deduced from the last, as will afterwards
-appear.
-
- 144 square inches are 1 square foot 1 sq. ft.
- 9 square feet 1 square yard 1 sq. yd.
- 30¼ square yards 1 square pole 1 sq. p.
- 40 square poles 1 rood 1 rd.
- 4 roods 1 acre 1 ac.
-
-Thus, the acre contains 4840 square yards, which is ten times a square
-of 22 yards in length and breadth. This 22 yards is the length which
-land-surveyors’ chains are made to have, and the chain is divided into
-100 links, each ·22 of a yard or 7·92 inches. An acre is then 10 square
-chains. It may also be noticed that a square whose side is 69⁴/₇ yards
-is nearly an acre, not exceeding it by ⅕ of a square foot.
-
-
-216. MEASURES OF SOLIDITY OR CAPACITY.[37]
-
-Cubes are solids having the figure of dice. A cubic inch is a cube each
-of whose sides is an inch, and so on.
-
- 1728 cubic inches are 1 cubic foot 1 c. ft.
- 27 cubic feet 1 cubic yard 1 c. yd.
-
-[37] ‘Capacity’ is a term which cannot be better explained than by its
-use. When one measure holds more than another, it is said to be more
-capacious, or to have a greater capacity.
-
-This measure is not much used, except in purely mathematical questions.
-In the measurements of different commodities various measures were
-used, which are now reduced, by act of parliament, to one. This is
-commonly called the imperial measure, and is as follows:
-
-
-MEASURE OF LIQUIDS AND OF ALL DRY GOODS.
-
- 4 _gills_ are 1 _pint_ 1 pt.
- 2 _pints_ 1 _quart_ 1 qt.
- 4 _quarts_ 1 _gallon_ 1 gall.
- 2 _gallons_ 1 _peck_[38] 1 pk.
- 4 _pecks_ 1 _bushel_ 1 bu.
- 8 _bushels_ 1 _quarter_ 1 qr.
- 5 _quarters_ 1 _load_ 1 ld.
-
-The gallon in this measure is about 277·274 cubic inches; that is, very
-nearly 277¼ cubic inches.[39]
-
-217. The smallest weight in use is the grain, which is thus determined.
-A vessel whose interior is a cubic inch, when filled with water,[40]
-has its weight increased by 252·458 grains. Of the grains so
-determined, 7000 are a pound _averdupois_, and 5760 a pound _troy_.
-The first pound is always used, except in weighing precious metals and
-stones, and also medicines. It is divided as follows:
-
-[38] This measure, and those which follow, are used for dry goods only.
-
-[39] Since the publication of the third edition, the _heaped_ measure,
-which was part of the new system, has been abolished. The following
-paragraph from the third edition will serve for reference to it:
-
-“The other imperial measure is applied to goods which it is customary
-to sell by _heaped measure_, and is as follows:
-
- 2 gallons 1 peck
- 4 pecks 1 bushel
- 3 bushels 1 sack
- 12 sacks 1 chaldron.
-
-The gallon and bushel in this measure hold the same when only just
-filled, as in the last. The bushel, however, heaped up as directed by
-the act of parliament, is a little more than one-fourth greater than
-before.”
-
-[40] Pure water, cleared from foreign substances by distillation, at a
-temperature of 62° Fahr.
-
-
-AVERDUPOIS WEIGHT.
-
- 27¹¹/₃₂ _grains_ are 1 _dram_ 1 dr.
- 6 _drams_, or _drachms_ 1 _ounce_[41] 1 oz.
- 16 _ounces_ 1 _pound_ 1 lb.
- 28 _pounds_ 1 _quarter_ 1 qr.
- 4 _quarters_ 1 _hundred-weight_ 1 cwt.
- 20 _hundred-weight_ 1 _ton_ 1 ton.
-
-[41] It is more common to divide the ounce into four quarters than into
-sixteen drams.
-
-The pound averdupois contains 7000 grains. A cubic foot of water weighs
-62·3210606 pounds averdupois, or 997·1369691 ounces.
-
-For the precious metals and for medicines, the pound troy, containing
-5760 grains, is used, but is differently divided in the two cases. The
-measures are as follow:
-
-
-TROY WEIGHT.
-
- 24 _grains_ are 1 _pennyweight_ 1 dwt.
- 20 _pennyweights_ 1 _ounce_ 1 oz.
- 12 _ounces_ 1 _pound_ 1 lb.
-
-The pound troy contains 5760 grains. A cubic foot of water weighs
-75·7374 pounds troy, or 908·8488 ounces.
-
-
-APOTHECARIES’ WEIGHT.
-
- 20 _grains_ are 1 _scruple_ ℈
- 3 _scruples_ 1 _dram_ ʒ
- 8 _drams_ 1 _ounce_ ℥
- 12 _ounces_ 1 _pound_ lb
-
-218. The standard coins of copper, silver, and gold, are,--the penny,
-which is 10⅔ drams of copper; the shilling, which weighs 3 pennyweights
-15 grains, of which 3 parts out of 40 are alloy, and the rest pure
-silver; and the sovereign, weighing 5 pennyweights and 3¼ grains, of
-which 1 part out of 12 is copper, and the rest pure gold.
-
-
-MEASURES OF MONEY.
-
-The lowest coin is a farthing, which is marked thus, ¼, being one
-fourth of a penny.
-
- 2 _farthings_ are 1 _halfpenny_ ½_d_.
- 2 _halfpence_ 1 _penny_ 1_d_.
- 12 _pence_ 1 _shilling_ 1_s_.
- 20 _shillings_ 1 _pound_[42] or _sovereign_ £1
- 21 _shillings_ 1 _guinea_.[43]
-
-219. When any quantity is made up of several others, expressed in
-different units, such as £1. 14. 6, or 2cwt. 1qr. 3lbs., it is called a
-_compound quantity_. From these tables it is evident that any compound
-quantity of any substance can be measured in several different ways.
-For example, the sum of money which we call five pounds four shillings
-is also 104 shillings, or 1248 pence, or 4992 farthings. It is easy to
-reduce any quantity from one of these measurements to another; and the
-following examples will be sufficient to shew how to apply the same
-process, usually called REDUCTION, to all sorts of quantities.
-
-I. How many farthings are there in £18. 12. 6¾?[44]
-
-[42] The English pound is generally called a _pound sterling_, which
-distinguishes it from the weight called a pound, and also from foreign
-coins.
-
-[43] The coin called a guinea is now no longer in use, but the name is
-still given, from custom, to 21 shillings. The pound, which was not a
-coin, but a note promising to pay 20 shillings to the bearer, is also
-disused for the present, and the sovereign supplies its place; but the
-name pound is still given to 20 shillings.
-
-[44] Farthings are never written but as parts of a penny. Thus, three
-farthings being 3/4 of a penny, is written 3/4, or ¾. One halfpenny may
-be written either as 2/4 or ½; the latter is most common.
-
-Since there are 20 shillings in a pound, there are, in £18, 18 × 20, or
-360 shillings; therefore, £18. 12 is 360 + 12, or 372 shillings. Since
-there are 12 pence in a shilling, in 372 shillings there are 372 × 12,
-or 4464 pence; and, therefore, in £18. 12. 6 there are 4464 + 6, or
-4470 pence.
-
-Since there are 4 farthings in a penny, in 4470 pence there are 4470 ×
-4, or 17880 farthings; and, therefore, in £18. 12. 6¾ there are 17880
-+ 3, or 17883 farthings. The whole of this process may be written as
-follows:
-
- £18 . 12 . 6¾
- 20
- --------
- 360 + 12 = 372
- 12
- -----
- 4464 + 6 = 4470
- 4
- -----
- 17880 + 3 = 17883
-
-II. In 17883 farthings, how many pounds, shillings, pence, and
-farthings are there?
-
-Since 17883, divided by 4, gives the quotient 4470, and the remainder
-3, 17883 farthings are 4470 pence and 3 farthings (218).
-
-Since 4470, divided by 12, gives the quotient 372, and the remainder 6,
-4470 pence is 372 shillings and 6 pence.
-
-Since 372, divided by 20, gives the quotient 18, and the remainder 12,
-372 shillings is 18 pounds and 12 shillings.
-
-Therefore, 17883 farthings is 4470¾_d_., which is 372s. 6¾_d_., which
-is £18. 12. 6¾.
-
-The process may be written as follows:
-
- 4)17883
- -----
- 12)4470 ... 3
- ----
- 20)372 ... 6
- £18 . 12 . 6¾
-
-EXERCISES.
-
-A has £100. 4. 11½, and B has 64392 farthings. If A receive 1492
-farthings, and B £1. 2. 3½, which will then have the most, and by how
-much?--_Answer_, A will have £33. 12. 3 more than B.
-
-In the following table the quantities written opposite to each other
-are the same: each line furnishes two exercises.
-
- £15 . 18 . 9½ | 15302 farthings.
- 115ˡᵇˢ 1ᵒᶻ 8ᵈᵚᵗ | 663072 grains.
- 3ˡᵇˢ 14ᵒᶻ 9ᵈʳ | 1001 drams.
- 3ᵐ 149 yds 2ᶠᵗ 9 in | 195477 inches.
- 19ᵇᵘ 2ᵖᵏˢ 1 gall 2 qᵗˢ | 1260 pints.
- 16 ʰ 23ᵐ 47ˢ | 59027 seconds.
-
-220. The same may be done where the number first expressed is
-fractional. For example, how many shillings and pence are there in ⁴/₁₅
-of a pound? Now, ⁴/₁₅ of a pound is ⁴/₁₅ of 20 shillings; ⁴/₁₅ of 20 is
-
- 4 × 20 4 × 4 16
- ------, or ----- (110), or ---,
- 15 3 3
-
-or (105) 5⅓ of a shilling. Again, ⅓ of a shilling is ⅓ of 12 pence, or
-4 pence. Therefore, £⁴/₁₅ = 5_s._ 4_d._
-
-Also, ·23 of a day is ·23 × 24 in hours, or 5ʰ·52; and ·52 of an hour
-is ·52 × 60 in minutes, or 3ᵐ·2; and ·2 of a minute is ·2 × 60 in
-seconds, or 12ˢ; whence ·23 of a day is 5ʰ 31ᵐ 12ˢ.
-
-Again, suppose it required to find what part of a pound 6_s_. 8_d_. is.
-Since 6_s._ 8_d._ is 80 pence, and since the whole pound contains 20
-× 12 or 240 pence, 6_s._ 8_d._ is made by dividing the pound into 240
-parts, and taking 80 of them. It is therefore £⁸⁰/₂₄₀ (107), but ⁸⁰/₂₄₀
-= ⅓ (108); therefore, 6_s._ 8_d._ = £⅓.
-
-EXERCISES.
-
- ⅖ of a day is 9ʰ 36ᵐ
- ·12841 of a day 3ʰ 4ᵐ 54ᔆ·624[45]
- ·257 of a cwt. 28ˡᵇˢ 12ᵒᶻ 8ᵈʳ·704
- £·14936 2ˢ 11ᵈ 3ᶠ·3856
-
-[45] When a decimal follows a whole number, the decimal is always of
-the same unit as the whole number. Thus, 5ᔆ·5 is five _seconds_ and
-five-tenths of a _second_. Thus, 0ᔆ·5 means five-tenths of a second;
-0ʰ·3, three-tenths of an hour.
-
-221, 222. I have thought it best to refer the mode of converting
-shillings, pence, and farthings into decimals of a pound to the
-Appendix (See Appendix _On Decimal Money_). I should strongly recommend
-the reader to make himself perfectly familiar with the modes given in
-that Appendix. To prevent the subsequent sections from being altered in
-their numbering, I have numbered this paragraph as above.
-
-223. The rule of addition[46] of two compound quantities of the same
-sort will be evident from the following example. Suppose it required to
-add £192. 14. 2½ to £64. 13. 11¾. The sum of these two is the whole of
-that which arises from adding their several parts. Now
-
-
- ¾_d._ + ½_d._ = ⁵/₄_d._ = £0 . 0 . 1¼ (219)
-
-
- 11_d._ + 2_d._ = 13_d._ = 0 . 1 . 1
- 13_s._ + 14_s._ = 27_s._ = 1 . 7 . 0
- £64 + £192 = 256 . 0 . 0
- -----------
- The sum of all of which is £257. 8 . 2¼
-
-This may be done at once, and written as follows:
-
- £192 . 14 . 2½
- 64 . 13 . 11¾
- ----------------
- £257 . 8 . 2¼
-
-[46] Before reading this article and the next, articles (29) and (42)
-should be read again carefully.
-
-Begin by adding together the farthings, and reduce the result to pence
-and farthings. Set down the last only, carry the first to the line
-of pence, and add the pence in both lines to it. Reduce the sum to
-shillings and pence; set down the last only, and carry the first to the
-line of shillings, and so on. The same method must be followed when the
-quantities are of any other sort; and if the tables be kept in memory,
-the process will be easy.
-
-224. SUBTRACTION is performed on the same principle as in (40), namely,
-that the difference of two quantities is not altered by adding the same
-quantity to both. Suppose it required to subtract £19 . 13. 10¾ from
-£24. 5. 7½. Write these quantities under one another thus:
-
- £24. 5. 7½
- 19. 13. 10¾
-
-Since ¾ cannot be taken from ½ or ²/₄, add 1_d._ to both quantities,
-which will not alter their difference; or, which is the same thing,
-add 4 farthings to the first, and 1_d._ to the second. The pence and
-farthings in the two lines then stand thus: 7⁶/₄_d._ and 11¾_d._ Now
-subtract ¾ from ⁶/₄, and the difference is ¾ which must be written
-under the farthings. Again, since 11_d._ cannot be subtracted from
-7_d._, add 1_s._ to both quantities by adding 12_d._ to the first, and
-1_s._ to the second. The pence in the first line are then 19, and in
-the second 11, and the difference is 8, which write under the pence.
-Since the shillings in the lower line were increased by 1, there are
-now 14_s._ in the lower, and 5_s._ in the upper one. Add 20_s._ to the
-upper and £1 to the lower line, and the subtraction of the shillings in
-the second from those in the first leaves 11_s._ Again, there are now
-£20 in the lower, and £24 in the upper line, the difference of which is
-£4; therefore the whole difference of the two sums is £4. 11. 8¾. If we
-write down the two sums with all the additions which have been made,
-the process will stand thus:
-
- £24 . 25 . 19⁶/₄
- 20 . 14 . 11¾
- ------------------
- Difference £4 . 11 . 8¾
-
-225. The same method may be applied to any of the quantities in the
-tables. The following is another example:
-
- From 7 cwt. 2 qrs. 21 lbs. 14 oz.
- Subtract 2 cwt. 3 qrs. 27 lbs. 12 oz.
-
-After alterations have been made similar to those in the last article,
-the question becomes:
-
- From 7 cwt. 6 qrs. 49 lbs. 14 oz.
- Subtract 3 cwt. 4 qrs. 27 lbs. 12 oz.
- ----------------------------
- The difference is 4 cwt. 2 qrs. 22 lbs. 2 oz.
-
-In this example, and almost every other, the process may be a little
-shortened in the following way. Here we do not subtract 27 lbs. from 21
-lbs., which is impossible, but we increase 21 lbs. by 1 qr. or 28 lbs.
-and then subtract 27 lbs. from the sum. It would be shorter, and lead
-to the same result, first to subtract 27 lbs. from 1 qr. or 28 lbs. and
-add the difference to 21 lbs.
-
-226. EXERCISES.
-
-A man has the following sums to receive: £193. 14. 11¼, £22. 0. 6¾,
-£6473. 0. 0, and £49. 14. 4½; and the following debts to pay: £200 .
-19. 6¼, £305. 16. 11, £22, and £19. 6. 0½. How much will remain after
-paying the debts?
-
-_Answer_, £6190. 7. 4¾.
-
-There are four towns, in the order A, B, C, and D. If a man can go from
-A to B in 5ʰ 20ᵐ 33ˢ, from B to C in 6ʰ 49ᵐ 2ˢ and from A to D in 19ʰ
-0ᵐ 17ˢ, how long will he be in going from B to D, and from C to D?
-
-_Answer_, 13ʰ 39ᵐ 44ˢ, and 6ʰ 50ᵐ 42ˢ.
-
-227. In order to perform the process of MULTIPLICATION, it must be
-recollected that, as in (52), if a quantity be divided into several
-parts, and each of these parts be multiplied by a number, and the
-products be added, the result is the same as would arise from
-multiplying the whole quantity by that number.
-
-It is required to multiply £7. 13. 6¼ by 13. The first quantity is made
-up of 7 pounds, 13 shillings, 6 pence, and 1 farthing. And
-
- 1 farth. × 13 is 13 farth. or £0 . 0 . 3¼ (219)
- 6 pence × 13 is 78 pence, or 0 . 6 . 6
- 13 shill. × 13 is 169 shill. or 8 . 9 . 0
- 7 pounds × 13 is 91 pounds, or 91 . 0 . 0
- --------------
- The sum of all these is £99 . 15 . 9¼
-
-which is therefore £7. 13. 6¼ × 13.
-
-This process is usually written as follows:
-
- £7 . 13 . 6¼
- 13
- -------------
- £99 . 15 . 9¼
-
-228. DIVISION is performed upon the same principle as in (74), viz.
-that if a quantity be divided into any number of parts, and each part
-be divided by any number, the different quotients added together will
-make up the quotient of the whole quantity divided by that number.
-Suppose it required to divide £99. 15. 9¼ by 13. Since 99 divided by 13
-gives the quotient 7, and the remainder 8, the quantity is made up of
-£13 × 7, or £91, and £8. 15. 9¼. The quotient of the first, 13 being
-the divisor, is £7: it remains to find that of the second. Since £8 is
-160_s._, £8. 15. 9¼ is 175_s._ 9¼_d._, and 175 divided by 13 gives the
-quotient 13, and the remainder 6; that is, 175_s._ 9¼_d._ is made up of
-169_s._ and 6_s._ 9¼_d._, the quotient of the first of which is 13_s._,
-and it remains to find that of the second. Since 6_s._ is 72_d._,
-6_s._ 9¼_d._ is 81¼_d._, and 81 divided by 13 gives the quotient 6
-and remainder 3; that is, 81¼_d._ is 78_d._ and 3¼_d._, of the first
-of which the quotient is 6_d._ Again, since 3_d._ is ¹²/₄, or 12
-farthings, 3¼_d._ is 13 farthings, the quotient of which is 1 farthing,
-or ¼, without remainder. We have then divided £99. 15. 9¼ into four
-parts, each of which is divisible by 13, viz. £91, 169_s._, 78_d._, and
-13 farthings; so that the thirteenth part of this quantity is £7. 13.
-6¼. The whole process may be written down as follows; and the same sort
-of process may be applied to the exercises which follow:
-
- £ _s._ _d._ £ _s._ _d._
- 13)99 15 9¼( 7 13 6¼
- 91
- --
- 8
- 20
- ---
- 160 + 15 = 175
- 13
- ---
- 45
- 39
- --
- 6
- 12
- --
- 72 + 9 = 81
- 78
- --
- 3
- 4
- --
- 12 + 1 = 13
- 13
- --
- 0
-
-Here, each of the numbers 99, 175, 81, and 13, is divided by 13 in the
-usual way, though the divisor is only written before the first of them.
-
-EXERCISES.
-
- 2 cwt. 1 qr. 21 lbs. 7 oz. × 53 = 129 cwt. 1 qr. 16 lbs. 3 oz.
- 2ᵈ 4ʰ 3ᵐ 27ˢ × 109 = 236ᵈ 10ʰ 16ᵐ 3ˢ
- £27 . 10 . 8 × 569 = £15666 . 9 . 4
- £7 . 4 . 8 × 123 = £889 . 14
- £166 × ₈/₃₃ = £40 . 4 . 10⁶/₃₃
- £187 . 6 . 7 × ³/₁₀₀ = £5 . 12 . 4¾ ²/₂₅
- 4_s._ 6½_d._ × 1121 = £254 . 11 . 2½
- 4_s._ 4_d._ × 4260 = 6_s._ 6_d._ × 2840
-
-229. Suppose it required to find how many times 1s. 4¼_d._ is contained
-in £3. 19. 10¾. The way to do this is to find the number of farthings
-in each. By 219, in the first there are 65, and in the second 3835
-farthings. Now, 3835 contains 65 59 times; and therefore the second
-quantity is 59 times as great as the first. In the case, however, of
-pounds, shillings, and pence, it would be best to use decimals of a
-pound, which will give a sufficiently exact answer. Thus 1s. 4¼_d._ is
-£·067, and £3. 19. 10¾ is £3·994, and 3·994 divided by ·067 is 3994 by
-67, or 59⁴¹/₆₇. This is an extreme case, for the smaller the divisor,
-the greater the effect of an error in a given place of decimals.
-
-EXERCISES.
-
-How many times does 6 cwt. 2 qrs. contain 1 qr. 14 lbs. 1 oz.? and 1ᵈ
-2ʰ 0ᵐ 47ˢ contain 3ᵐ 46ˢ?
-
-_Answer_, 17·30758 and 414·367257.
-
-If 2 cwt. 3 qrs. 1 lb. cost £150. 13. 10, how much does 1 lb. cost?
-
-_Answer_, 9_s._ 9_d._ ¹³/₃₀₉.
-
-A grocer mixes 2 cwt. 15 lbs. of sugar at 11_d._ per pound with 14
-cwt. 3 lbs. at 5_d._ per pound. At how much per pound must he sell the
-mixture so as not to lose by mixing them?
-
-_Answer_, 5_d._ ¾ ¹⁵³/₉₀₅.
-
-230. There is a convenient method of multiplication called PRACTICE.
-Suppose I ask, How much do 153 tons cost if each ton cost £2. 15. 7½?
-It is plain that if this sum be multiplied by 153, the product is the
-price of the whole. But this is also evident, that, if I buy 153 tons
-at £2. 15. 7½ each ton, payment may be made by first putting down £2
-for each ton, then 10s. for each, then 5_s._, then 6_d._, and then
-1½_d._ These sums together make up £2. 15. 7½, and the reason for this
-separation of £2. 15 . 7½ into different parts will be soon apparent.
-The process may be carried on as follows:
-
- 1. 153 tons, at £2 each ton, will cost £306 0 0
-
- 2. Since 10s. is £½, 153 tons, at 10_s._ each,
- will cost £15³/₂, which is 76 10 0
-
- 3. Since 5_s._ is ½ of 10_s._, 153 tons, at 5_s._,
- will cost half as much as the same number at
- 10_s._ each, that is, ½ of £76 . 10, which is 38 5 0
-
- 4. Since 6_d._ is ⅒ of 5_s._, 153 tons, at 6_d._
- each, will cost ⅒ of what the same number
- costs at 5_s._each, that is, ⅒ of £38 . 5,
- which is 3 16 6
-
- 5. Since 1½ or 3 halfpence is ¼ of 6_d._ or 12
- halfpence, 153 tons, at 1½_d._ each, will cost
- ¼ of what the same number costs at 6_d._ each,
- that is, ¼ of£3 . 16 . 6, which is 0 19 1½
- -----------
- The sum of all these quantities is 425 10 7½
- which is, therefore, £2 . 15 . 7½ × 153.
-
-The whole process may be written down as follows:
-
- or what
- 153 tons
- would
- | £153 0 0 cost at £1 per ton.
- | ----------- -----------
- £2 is 2 × £1 | 306 0 0 2 0 0
- 10_s._ is ½ of £1 | 76 10 0 0 10 0
- 5_s._ is ½ of 10_s._ | 38 5 0 0 5 0
- 6_d._ is ⅒ of 5_s._ | 3 16 6 0 0 6
- 1½_d._ is ¼ of 6_d._ | 0 19 1½ 0 0 1½
- | ------------ ----------
- Sum | £425 10 7½ £2 15 7½
-
-ANOTHER EXAMPLE.
-
-What do 1735 lbs. cost at 9_s._ 10¾_d._ per lb.? The price 9_s._
-10¾_d_. is made up of 5_s._, 4_s._, 10_d._, ½_d._, and ¼_d._; of which
-5_s._ is ¼ of £1, 4_s._ is ⅕ of £1, 10_d._ is ⅙ of 5_s._, ½_d._ is ¹/₂₀
-of 10_d._, and ¼_d._ is ½ of ½_d._ Follow the same method as in the
-last example, which gives the following:
-
- or what
- 1735 tons
- would
- | £1735 0 0 cost at £1 per lb.
- | ------------ -----------
- 5_s._ is ¼ of £1 | 433 15 0 0 5 0
- |
- 4_s._ is ⅕ of £1 | 347 0 0 0 4 0
- |
- 10_d._ is ⅙ of 5_s._ | 72 5 10 0 0 10
- |
- ½_d._ is ¹/₂₀ of 10_d._ | 3 12 3½ 0 0 0½
- |
- ¼_d._ is ½ of ½_d._ | 1 16 1¾ 0 0 0¼
- | ------------- ------------
- by addition ... | £858 9 3¼ £0 9 10¾
-
-In all cases, the price must first be divided into a number of parts,
-each of which is a simple fraction[47] of some one which goes before.
-No rule can be given for doing this, but practice will enable the
-student immediately to find out the best method for each case. When
-that is done, he must find how much the whole quantity would cost if
-each of these parts were the price, and then add the results together.
-
-[47] Any fraction of a unit, whose numerator is unity, is generally
-called an _aliquot part_ of that unit. Thus, 2_s._ and 10_s._ are both
-aliquot parts of a pound, being £⅒ and £½.
-
-EXERCISES.
-
- What is the cost of
-
- 243 cwt. at £14 . 18 . 8¼ per cwt.?--_Answer_, £3629 . 1 . 0¾.
-
- 169 bushels at £2 . 1 . 3¼ per bushel?--_Answer_, £348 . 14 . 9¼.
-
- 273 qrs. at 19_s._ 2_d._ per quarter?--_Answer_, £261 . 12. 6.
-
- 2627 sacks at 7_s._ 8½_d._ per sack?--_Answer_, £1012 . 9 . 9½.
-
-231. Throughout this section it must be observed, that the rules can be
-applied to cases where the quantities given are expressed in common or
-decimal fractions, instead of the measures in the tables. The following
-are examples:
-
-What is the price of 272·3479 cwt. at £2. 1. 3½ per cwt.?
-
-_Answer_, £562·2849, or £562. 5. 8¼.
-
-66½lbs. at 1_s._ 4½_d._ per lb. cost £4. 11. 5¼.
-
-How many pounds, shillings, and pence, will 279·301 acres let for if
-each acre lets for £3·1076?--_Answer_, £867·9558, or £867. 19. 1¼.
-
-What does ¼ of ³/₁₃ of 17 bush. cost at ⅙ of ⅔ of £17. 14 per bushel?
-
-_Answer_, £2·3146, or £2. 6. 3½.
-
-What is the cost of 19lbs. 8oz. 12dwt. 8gr. at £4. 4. 6 per
-ounce?--_Answer_, £999. 14. 1¼ ⅙.
-
-232. It is often required to find to how much a certain sum per day
-will amount in a year. This may be shortly done, since it happens that
-the number of days in a year is 240 + 120 + 5; so that a penny per day
-is a pound, half a pound, and 5 pence per year. Hence the following
-rule: To find how much any sum per day amounts to in a year, turn it
-into pence and fractions of a penny; to this add the half of itself,
-and let the pence be pounds, and each farthing five shillings; then
-add five times the daily sum, and the total is the yearly amount. For
-example, what does 12_s._ 3¾_d._ amount to in a year? This is 147¾_d._,
-and its half is 73⅞_d._, which added to 147¾_d._ gives 221⅝_d._, which
-turned into pounds is £221. 12. 6. Also, 12_s._ 3¾_d._ × 5 is £3. 1.
-6¾, which added to the former sum gives £224. 14. 0¾ for the yearly
-amount. In the same way the yearly amount of 2_s._ 3½_d._ is £41. 16.
-5½; that of 6¾_d._ is £10. 5. 3¾; and that of 11_d._ is £16. 14. 7.
-
-233. An inverse rule may be formed, sufficiently correct for every
-purpose, in the following way: If the year consisted of 360 days, or
-³/₂ of 240, the subtraction of one-third from any sum per year would
-give the proportion which belongs to 240 days; and every pound so
-obtained would be one penny per day. But as the year is not 360, but
-365 days, if we divide each day’s share into 365 parts, and take 5
-away, the whole of the subtracted sum, or 360 × 5 such parts, will
-give 360 parts for each of the 5 days which we neglected at first.
-But 360 such parts are left behind for each of the 360 first days;
-therefore, this additional process divides the whole annual amount
-equally among the 365 days. Now, 5 parts out of 365 is one out of
-73, or the 73d part of the first result must be subtracted from it
-to produce the true result. Unless the daily sum be very large, the
-72d part will do equally well, which, as 72 farthings are 18 pence,
-is equivalent to subtracting at the rate of one farthing for 18_d._,
-or ½_d._ for 3_s._, or 10_d._ for £3. The rule, then, is as follows:
-To find how much per day will produce a given sum per year, turn
-the shillings, &c. in the given sum into decimals of a pound (221);
-subtract one-third; consider the result as pence; and diminish it by
-one farthing for every eighteen pence, or ten pence for every £3. For
-example, how much per day will give £224. 14. 0¾ per year? This is
-224·703, and its third is 74·901, which subtracted from 224·703, gives
-149·802, which, if they be pence, amounts to 12_s._ 5·802_d._, in which
-1_s._ 6_d._ is contained 8 times. Subtract 8 farthings, or 2_d._, and
-we have 12_s._ 3·802_d._, which differs from the truth only about ¹/₂₀
-of a farthing. In the same way, £100 per year is 5_s._ 5¾_d._ per day.
-
-234. The following connexion between the measures of length and the
-measures of surface is the foundation of the application of arithmetic
-to geometry.
-
-[Illustration]
-
-Suppose an oblong figure, A, B, C, D, as here drawn (which is called
-a _rectangle_ in geometry), with the side A B 6 inches, and the side
-A C 4 inches. Divide A B and C D (which are equal) each into 6 inches
-by the points _a, b, c, l, m_, &c.; and A C and B D (which are also
-equal) into 4 inches by the points _f, g, h, x, y_, and _z_. Join _a_
-and l, _b_ and _m_, &c., and _f_ and _x_, &c. Then, the figure A B C D
-is divided into a number of squares; for a square is a rectangle whose
-sides are equal, and therefore A _a f_ E is square, since A _a_ is of
-the same length as A _f_, both being 1 inch. There are also four rows
-of these squares, with six squares in each row; that is, there are 6
-× 4, or 24 squares altogether. Each of these squares has its sides 1
-inch in length, and is what was called in (215) _a square inch_. By the
-same reasoning, if one side had contained 6 _yards_, and the other 4
-_yards_, the surface would have contained 6 × 4 _square yards_; and so
-on.
-
-[Illustration]
-
-235. Let us now suppose that the sides of A B C D, instead of being
-a whole number of inches, contain some inches and a fraction. For
-example, let A B be 3½ inches, or (114) ⁷/₂ of an inch, and let A C
-contain 2½ inches, or ⁹/₄ of an inch. Draw A E twice as long as A B,
-and A F four times as long as A C, and complete the rectangle A E F G.
-The rest of the figure needs no description. Then, since A E is twice
-A B, or twice ⁷/₂ inches, it is 7 inches. And since A F is four times
-A C, or four times ⁹/₄ inches, it is 9 inches. Therefore, the whole
-rectangle A E F G contains, by (234), 7 × 9 or 63 square inches. But
-the rectangle A E F G contains 8 rectangles, all of the same figure
-as A B C D; and therefore A B C D is one-eighth part of A E F G, and
-contains ⁶³/₈ square inches. But ⁶³/₈ is made by multiplying ⁹/₄ and
-⁷/₂ together (118). From this and the last article it appears, that,
-whether the sides of a rectangle be a whole or a fractional number of
-inches, the number of square inches in its surface is the product of
-the numbers of inches in its sides. The square itself is a rectangle
-whose sides are all equal, and therefore the number of square inches
-which a square contains is found by multiplying the number of inches in
-its side by itself. For example, a square whose side is 13 inches in
-length contains 13 × 13 or 169 square inches.
-
-236. EXERCISES.
-
-What is the content, in square feet and inches, of a room whose sides
-are 42 ft. 5 inch. and 31 ft. 9 inch.? and supposing the piece from
-which its carpet is taken to be three quarters of a yard in breadth,
-what length of it must be cut off?--_Answer_, The content is 1346
-square feet 105 square inches, and the length of carpet required is 598
-feet 6⁵/₉ inches.
-
-The sides of a rectangular field are 253 yards and a quarter of a mile;
-how many acres does it contain?--_Answer_, 23.
-
-What is the difference between 18 _square miles_, and a square of 18
-miles long, or 18 _miles square_?--_Answer_, 306 square miles.
-
-237. It is by this rule that the measure in (215) is deduced from
-that in (214); for it is evident that twelve inches being a foot, the
-square foot is 12 × 12 or 144 square inches, and so on. In a similar
-way it may be shewn that the content in cubic inches of a cube, or
-parallelepiped,[48] may be found by multiplying together the number of
-inches in those three sides which meet in a point. Thus, a cube of 6
-inches contains 6 × 6 × 6, or 216 cubic inches; a chest whose sides are
-6, 8, and 5 feet, contains 6 × 8 × 5, or 240 cubic feet. By this rule
-the measure in (216) was deduced from that in (214).
-
-[48] A parallelepiped, or more properly, a _rectangular_
-parallelepiped, is a figure of the form of a brick; its sides, however,
-may be of any length; thus, the figure of a plank has the same name. A
-cube is a parallelepiped with equal sides, such as is a die.
-
-
-SECTION II.
-
-RULE OF THREE.
-
-238. Suppose it required to find what 156 yards will cost, if 22 yards
-cost 17_s._ 4_d._ This quantity, reduced to pence, is 208_d._; and if
-22 yards cost 208_d._, each yard costs ²⁰⁸/₂₂_d_. But 156 yards cost
-156 times the price of one yard, and therefore cost
-
- 208 208 × 156
- ---- × 156 pence, or --------- pence (117).
- 22 22
-
-Again, if 25½ French francs be 20 shillings sterling, how many francs
-are in £20. 15? Since 25½ francs are 20 shillings, twice the number of
-francs must be twice the number of shillings; that is, 51 francs are
-40 shillings, and one shilling is the fortieth part of 51 francs, or
-⁵¹/₄₀ francs. But £20 15_s._ contain 415 shillings (219); and since 1
-shilling is ⁵¹/₄₀ francs, 415 shillings is
-
- 51 × 415
- ⁵¹/₄₀ × 415 francs, or (117) -------- francs.
- 40
-
-239. Such questions as the last two belong to the most extensive rule
-in Commercial Arithmetic, which is called the RULE OF THREE, because in
-it three quantities are given, and a fourth is required to be found.
-From both the preceding examples the following rule may be deduced,
-which the same reasoning will shew to apply to all similar cases.
-
-It must be observed, that in these questions there are two quantities
-which are of the same sort, and a third of another sort, of which last
-the answer must be. Thus, in the first question there are 22 and 156
-yards and 208 pence, and the thing required to be found is a number
-of pence. In the second question there are 20 and 415 shillings and
-25½ francs, and what is to be found is a number of francs. Write the
-three quantities in a line, putting that one last which is the only one
-of its kind, and that one first which is connected with the last in
-the question.[49] Put the third quantity in the middle. In the first
-question the quantities will be placed thus:
-
- 22 yds. 156 yds. 17_s._ 4_d._
-
-In the second question they will be placed thus:
-
- 20_s._ £20 15_s._ 25½ francs.
-
-[49] This generally comes in the same member of the sentence. In some
-cases the ingenuity of the student must be employed in detecting it.
-The reasoning of (238) is the best guide. The following may be very
-often applied. If it be evident that the answer must be less than the
-given quantity of its kind, multiply that given quantity by the less of
-the other two; if greater, by the greater. Thus, in the first question,
-156 yards must cost more than 22; multiply, therefore, by 156.
-
-Reduce the first and second quantities, if necessary, to quantities of
-the same denomination. Thus, in the second question, £20 15_s._ must
-be reduced to shillings (219). The third quantity may also be reduced
-to any other denomination, if convenient; or the first and third may
-be multiplied by any quantity we please, as was done in the second
-question; and, on looking at the answer in (238), and at (108), it
-will be seen that no change is made by that multiplication. Multiply
-the second and third quantities together, and divide by the first. The
-result is a quantity of the same sort as the third in the line, and is
-the answer required. Thus, to the first question the answer is (238)
-
- 208 × 156 17_s._ 4_d_. × 156
- ----------pence, or, which is the same thing, -------------------.
- 22 22
-
-240. The whole process in the first question is as follows:[50]
-
- yds. yds. _s._ _d._
- 22 : 156 ∷ 17 . 4
- 12
- ---
- 208 pence.
- 156
- ----
- 1248
- 1040
- 208
- -----
- 22)32448(1474¾_d._ and ¹⁴/₂₂, or ⁷/₁₁ of a farthing,
- 22 or (219) £6 . 2 . 10¾-⁷/₁₁.
- ---
- 104
- 88
- ----
- 164
- 154
- ----
- 108
- 88
- --
- 20
- (228) 4
- --
- 80
- 66
- --
- 14
-
-[50] It is usual to place points, in the manner here shewn, between the
-quantities. Those who have read Section VIII. will see that the Rule
-of Three is no more than the process for finding the fourth term of a
-proportion from the other three.
-
-The question might have been solved without reducing 17_s._ 4_d._ to
-pence, thus:
-
- yds. yds. _s._ _d._
- 22 : 156 ∷ 17 . 4
- 156 (227)
- ----------
- 22)£135 . 4 . 0(£6 . 2 . 10¾-⁷/₁₁ (228)
- 132
- ---
- 3 × 20 + 4 = 64
- 44
- --
- 20 × 12 = 240
- 220
- ---
- 20 × 4 = 80
- 66
- --
- 14
-
-The student must learn by practice which is the most convenient method
-for any particular case, as no rule can be given.
-
-241. It may happen that the three given quantities are all of one
-denomination; nevertheless it will be found that two of them are of
-one, and the third of another sort. For example: What must an income
-of £400 pay towards an income-tax of 4_s._ 6_d._ in the pound? Here
-the three given quantities are, £400, 4_s._ 6_d._, and £1, which are
-all of the same species, viz. money. Nevertheless, the first and third
-are income; the second is a tax, and the answer is also a tax; and
-therefore, by (152), the quantities must be placed thus:
-
- £1 : £400 ∷ 4_s._ 6_d._
-
-242. The following exercises either depend directly upon this rule,
-or can be shewn to do so by a little consideration. There are many
-questions of the sort, which will require some exercise of ingenuity
-before the method of applying the rule can be found.
-
-EXERCISES.
-
-If 15 cwt. 2 qrs. cost £198. 15. 4, what does 1 qr. 22 lbs. cost?
-
- _Answer_, £5 . 14 . 5 ¾ ¹⁸⁵/₂₁₇.
-
-If a horse go 14 m. 3 fur. 27 yds. in 3ʰ 26ᵐ 12ˢ, how long will he be
-in going 23 miles?
-
-_Answer_, 5ʰ 29ᵐ 34ˢ(²⁴⁶²/₂₅₃₂₇).
-
-Two persons, A and B, are bankrupts, and owe exactly the same sum; A
-can pay 15_s._ 4½_d._ in the pound, and B only 7_s._ (6¾)_d._ At the
-same time A has in his possession £1304. 17 more than B; what do the
-debts of each amount to?
-
- _Answer_, £3340 . 8 . 3 ¾ ⁹/₂₅.
-
-For every (12½) acres which one country contains, a second contains
-(56¼). The second country contains 17,300 square miles. How much does
-the first contain? Again, for every 3 people in the first, there are 5
-in the second; and there are in the first 27 people on every 20 acres.
-How many are there in each country?--_Answer_, The number of square
-miles in the first is 3844⁴/₉, and its population 3,321,600; and the
-population of the second is 5,536,000.
-
-If (42½) yds. of cloth, 18 in. wide, cost £59. 14. 2, how much will
-(118¼) yds. cost, if the width be 1 yd.?
-
-_Answer_, £332. 5. (2⁴/₁₇).
-
-If £9. 3. 6 last six weeks, how long will £100 last?
-
-_Answer_, (65¹⁴⁵/₃₆₇) weeks.
-
-How much sugar, worth (9¾d). a pound, must be given for 2 cwt. of tea,
-worth 10_d._ an ounce?
-
-_Answer_, 32 cwt. 3 qrs. 7 lbs. ³⁵/₃₉.
-
-243. Suppose the following question asked: How long will it take 15 men
-to do that which 45 men can finish in 10 days? It is evident that one
-man would take 45 × 10, or 450 days, to do the same thing, and that 15
-men would do it in one-fifteenth part of the time which it employs one
-man, that is, in (450 ÷ 15) or 30 days. By this and similar reasoning
-the following questions can be solved.
-
-EXERCISES.
-
-If 15 oxen eat an acre of grass in 12 days, how long will it take 26
-oxen to eat 14 acres? _Answer_, (96¹²/₁₃) days.
-
-If 22 masons build a wall 5 feet high in 6 days, how long will it take
-43 masons to build 10 feet? _Answer_, (6⁶/₄₃) days.
-
-244. The questions in the preceding article form part of a more general
-class of questions, whose solution is called the DOUBLE RULE OF THREE,
-but which might, with more correctness, be called the Rule of _Five_,
-since five quantities are given, and a sixth is to be found. The
-following is an example: If 5 men can make 30 yards of cloth in 3 days,
-how long will it take 4 men to make 68 yards? The first thing to be
-done is to find out, from the first part of the question, the time it
-will take one man to make one yard. Now, since one man, in 3 days, will
-do the fifth part of what 5 men can do, he will in 3 days make ³⁰/₅,
-or 6 yards. He will, therefore, make one yard in ³/₆6 or (3 × 5)/30 of
-a day. From this we are to find how long it will take 4 men to make 68
-yards. Since one man makes a yard in
-
- 3 × 5 3 × 5
- ----- of a day, he will make 68 yards in ----- × 68 days,
- 30 30
-
- 3 × 5 × 68
- or (116) in ---------- days; and 4 men will do this in one-fourth
- 30
-
- 3 × 5 × 68
- of the time, that is (123), in ---------- days, or in 8½ days.
- 30 × 4
-
-Again, suppose the question to be: If 5 men can make 30 yards in 3
-days, how much can 6 men do in 12 days? Here we must first find the
-quantity one man can do in one day, which appears, on reasoning similar
-to that in the last example, to be 30/(3 × 5) yards. Hence, 6 men, in
-one day, will make
-
- 6 × 30 12 × 6 × 30
- ------ yards, and in 12 days will make ----------- or 144 yards.
- 5 × 3 5 × 3
-
-From these examples the following rule may be drawn. Write the given
-quantities in two lines, keeping quantities of the same sort under one
-another, and those which are connected with each other, in the same
-line. In the two examples above given, the quantities must be written
-thus:
-
-[Illustration]
-
-SECOND EXAMPLE.
-
-[Illustration]
-
-Draw a curve through the middle of each line, and the extremities of
-the other. There will be three quantities on one curve and two on the
-other. Divide the product of the three by the product of the two, and
-the quotient is the answer to the question.
-
-If necessary, the quantities in each line must be reduced to more
-simple denominations (219), as was done in the common Rule of Three
-(238).
-
-EXERCISES.
-
-If 6 horses can, in 2 days, plough 17 acres, how many acres will 93
-horses plough in 4½ days?
-
-_Answer_, 592⅞.
-
-If 20 men, in 3¼ days, can dig 7 rectangular fields, the sides of each
-of which are 40 and 50 yards, how long will 37 men be in digging 53
-fields, the sides of each of which are 90 and 125½ yards?
-
- 2451
- _Answer_, 75----- days.
- 20720
-
-If the carriage of 60 cwt. through 20 miles cost £14 10_s._, what
-weight ought to be carried 30 miles for £5. 8. 9?
-
-_Answer_, 15 cwt.
-
-If £100 gain £5 in a year, how much will £850 gain in 3 years and 8
-months?
-
-_Answer_, £155. 16. 8.
-
-
-SECTION III.
-
-INTEREST, ETC.
-
-245. In the questions contained in this Section, almost the only
-process which will be employed is the taking a fractional part of a
-sum of money, which has been done before in several cases. Suppose it
-required to take 7 parts out of 40 from £16, that is, to divide £16
-into 40 equal parts, and take 7 of them. Each of these parts is
-
- 16 16 16 × 7
- £----, and 7 of them make ---- × 7, or ------ pounds (116).
- 40 40 40
-
-The process may be written as below:
-
- £16
- 7
- -----
- 40)112(£2 . 16_s._
- 80
- --
- 32
- 20
- ---
- 640
- 40
- ---
- 240
- 240
- ---
- 0
-
-Suppose it required to take 13 parts out of a hundred from £56. 13. 7½.
-
- 56 . 13 . 7½
- 13
- ----------------
- 100) 736 . 17 . 1½ ( £7 . 7 . 4 ¼ ¹/₄₁
- 700
- ---
- 36 × 20 + 17 = 737
- 700
- ---
- 37 × 12 + 1 = 445
- 400
- ---
- 45 × 4 × 2 = 182
- 100
- ---
- 82
-
-Let it be required to take 2½ parts out of a hundred from £3 12_s._ The
-result, by the same rule is
-
- £3 12_s._ × 2½ 5
- -------------------, or 123 £3 12_s._ × ---;
- 100 200
-
-so that taking 2½ out of a hundred is the same as taking 5 parts out of
-200.
-
-EXERCISES.
-
-Take 7⅓ parts out of 53 from £1 10_s._
-
- 129
- _Answer_, 4_s._ 1---_d._
- 159
-
-Take 5 parts out of 100 from £107 13_s._ 4¾_d._
-
-_Answer_, £5. 7. 8 and ³/₂₀ of a farthing.
-
-£56 3_s._ 2_d._ is equally divided among 32 persons. How much does the
-share of 23 of them exceed that of the rest?
-
-_Answer_, £24. 11. 4½ ½.
-
-246. It is usual, in mercantile business, to mention the fraction which
-one sum is of another, by saying how many parts out of a hundred must
-be taken from the second in order to make the first. Thus, instead of
-saying that £16 12_s._ is the half of £33 4_s._, it is said that the
-first is 50 per cent of the second. Thus, £5 is 2½ per cent of £200;
-because, if £200 be divided into 100 parts, 2½ of those parts are £5.
-Also, £13 is 150 per cent of £8. 13. 4, since the first is the second
-and half the second. Suppose it asked, How much per cent is 23 parts
-out of 56 of any sum? The question amounts to this: If he who has £56
-gets £100 for them, how much will he who has 23 receive? This, by 238,
-is 23 × ¹⁰⁰/₅₆ or ²³⁰⁰/₅₆ or 41¹/₁₄. Hence, 23 out of 56 is 41¹/₁₄ per
-cent.
-
-Similarly 16 parts out of 18 is 16 × ¹⁰⁰/₁₈, or 88⁸/₉ per cent, and 2
-parts out of 5 is 2 × ¹⁰⁰/₅, or 40 per cent.
-
-From which the method of reducing other fractions to the rate per cent
-is evident.
-
-Suppose it asked, How much per cent is £6. 12. 2 of £12. 3? Since the
-first contains 1586_d._, and the second 2916_d._, the first is 1586
-out of 2916 parts of the second; that is, by the last rule, it is
-¹⁵⁸⁶⁰⁰/₂₉₁₆, or 54¹¹³⁶/₂₉₁₆, or £54. 7. 9½ per cent, very nearly. The
-more expeditious way of doing this is to reduce the shillings, &c.
-to decimals of a pound. Three decimal places will give the rate per
-cent to the nearest shilling, which is near enough for all practical
-purposes. For instance, in the last example, which is to find how much
-£6·608 is of £12·15, 6·608 × 100 is 660·8, which divided by 12·15 gives
-£54·38, or £54. 7. Greater correctness may be had, if necessary, as in
-the Appendix.
-
-EXERCISES.
-
-How much per cent is 198¼ out of 233 parts?--_Ans._ £85. 1. 8¾.
-
-Goods which are bought for £193. 12, are sold for £216. 13. 4; how much
-per cent has been gained by them?
-
-_Answer_, A little less than £11. 18. 6.
-
-A sells goods for B to the amount of £230. 12, and is allowed a
-commission[51] of 3 per cent; what does that amount to?
-
- _Answer_, £6 . 18. 4¼ ⁷/₂₅.
-
-[51] Commission is what is allowed by one merchant to another for
-buying or selling goods for him, and is usually a per-centage on the
-whole sum employed. Brokerage is an allowance similar to commission,
-under a different name, principally used in the buying and selling of
-stock in the funds.
-
-Insurance is a per-centage paid to those who engage to make good to the
-payers any loss they may sustain by accidents from fire, or storms,
-according to the agreement, up to a certain amount which is named,
-and is a per-centage upon this amount. Tare, tret, and cloff, are
-allowances made in selling goods by wholesale, for the weight of the
-boxes or barrels which contain them, waste, &c.; and are usually either
-the price of a certain number of pounds of the goods for each box or
-barrel, or a certain allowance on each cwt.
-
-A stockbroker buys £1700 stock, brokerage being at £⅛ per cent; what
-does he receive?--_Answer_, £2. 2. 6.
-
-A ship whose value is £15,423 is insured at 19⅔ per cent; what does the
-insurance amount to?--_Answer_, £3033. 3. 9½ ²/₅.
-
-247. In reckoning how much a bankrupt is able to pay his creditors, as
-also to how much a tax or rate amounts, it is usual to find how many
-shillings in the pound is paid. Thus, if a person who owes £100 can
-only pay £50, he is said to pay 10_s._ in the pound. The rule is easily
-derived from the same reasoning as in 246. For example, £50 out of £82
-is
-
- 50 50×20
- £---- out of £1, or ----- shillings,
- 82 82
-
-or 12_s._ 2½ ¹⁵/₄₁ in the pound.
-
-248. INTEREST is money paid for the use of other money, and is always
-a per-centage upon the sum lent. It may be paid either yearly,
-half-yearly, or quarterly; but when it is said that £100 is lent at 4
-per cent, it must be understood to mean 4 per cent per annum; that is,
-that 4 pounds are paid every year for the use of £100.
-
-The sum lent is called the _principal_, and the interest upon it is
-of two kinds. If the borrower pay the interest as soon as, from the
-agreement, it becomes due, it is evident that he has to pay the same
-sum every year; and that the whole of the interest which he has to pay
-in any number of years is one year’s interest multiplied by the number
-of years. But if he do not pay the interest at once, but keeps it in
-his hands until he returns the principal, he will then have more of
-his creditor’s money in his hands every year, and if it were so agreed
-will have to pay interest upon each year’s interest for the time during
-which he keeps it after it becomes due. In the first case, the interest
-is called _simple_, and in the second _compound_. The interest and
-principal together are called the _amount_.
-
-249. What is the simple interest of £1049. 16. 6 for 6 years and
-one-third, at 4½ per cent? This interest must be 6⅓ times the interest
-of the same sum for one year, which (245) is found by multiplying the
-sum by 4½, and dividing by 100. The process is as follows:
-
- (230) (_a_) |£1049 . 16 . 6
- +--------------
- _a_ × 4 | 4199 . 6 . 0
- _a_ × ½ | 524 . 18 . 3
- +--------------
-
- (82) 100) 47,24 . 4 . 3(£47 . 4 . 10¹¹/₁₀₀
-
- 20
- ----
- (228) 4,84[52]
- 12
- ------
- 10,11[53]
-
- (_b_) £47 . 4 . 10¹¹/₁₀₀ Int. for one yr.
- +------------------
- _b_ × 6 | 283 . 9 . 0⁶⁶/₁₀₀
- _b_ × ⅓ | 15 . 14 . 11³⁷/₁₀₀
- +---------------------
- £299 . 4 . 0³/₁₀₀ Int. for 6⅓ yrs.
-
-[52] Here the 4_s._ from the dividend is taken in.
-
-[53] Here the 3_d._ from the dividend is taken in.
-
-EXERCISES.
-
-What is the interest of £105. 6. 2 for 19 years and 7 weeks at 3 per
-cent?
-
-_Answer_, £60. 9, very nearly.
-
-What is the difference between the interest of £50. 19 for 7 years at 3
-per cent, and for 8 years at 2½ per cent? _Answer_, 10_s._ (2½)_d._
-
-What is the interest of £157. 17. 6 for one year at 5 per cent?
-
-_Answer_, £7. 17. 10½.
-
-Shew that the interest of any sum for 9 years at 4 per cent is the same
-as that of the same sum for 4 years at 9 per cent.
-
-250. In order to find the interest of any sum at compound interest,
-it is necessary to find the amount of the principal and interest at
-the end of every year; because in this case (248) it is the amount of
-both principal and interest at the end of the first year, upon which
-interest accumulates during the second year. Suppose, for example, it
-is required to find the interest, for 3 years, on £100, at 5 per cent,
-compound interest. The following is the process:
-
- £100 First principal.
- 5 First year’s interest.
- ---
- 105 Amount at the end of the first year.
- (249) 5 . 5 Interest for the second year on £105.
- --------
- 110 . 5 Amount at the end of two years.
- 5 . 10 . 3 Interest due for the third year.
- ------------
- 115 . 15 . 3 Amount at the end of three years.
- 100 . 0 . 0 First principal.
- ------------
- 15 . 15 . 3 Interest gained in the three years.
-
-When the number of years is great, and the sum considerable, this
-process is very troublesome; on which account tables[54] are
-constructed to shew the amount of one pound, for different numbers of
-years, at different rates of interest. To make use of these tables in
-the present example, look into the column headed “5 per cent;” and
-opposite to the number 3, in the column headed “Number of years,” is
-found 1·157625; meaning that £1 will become £1·157625 in 3 years. Now,
-£100 must become 100 times as great; and 1·157625 × 100 is 115·7625
-(141); but (221) £·7625 is 15_s._ 3_d._; therefore the whole amount of
-£100 is £115. 15. 3, as before.
-
-[54] Sufficient tables for all common purposes are contained in
-the article on Interest in the Penny Cyclopædia; and ample ones in
-the Treatise on Annuities and Reversions, in the Library of Useful
-Knowledge.
-
-251. Suppose that a sum of money has lain at simple interest 4 years,
-at 5 per cent, and has, with its interest, amounted to £350; it is
-required to find what the sum was at first. Whatever the sum was, if we
-suppose it divided into 100 parts, 5 of those parts were added every
-year for 4 years, as interest; that is, 20 of those parts have been
-added to the first sum to make £350. If, therefore, £350 be divided
-into 120 parts, 100 of those parts are the principal which we want to
-find, and 20 parts are interest upon it; that is, the principal is
-£(350 × 100)/150, or £291. 13. 4.
-
-252. Suppose that A was engaged to pay B £350 at the end of four years
-from this time, and that it is agreed between them that the debt shall
-be paid immediately; suppose, also, that money can be employed at 5 per
-cent, simple interest; it is plain that A ought not to pay the whole
-sum, £350, because, if he did, he would lose 4 years’ interest of the
-money, and B would gain it. It is fair, therefore, that he should only
-pay to B as much as will, _with interest_, amount in four years to
-£350, that is (251), £291. 13. 4. Therefore, £58. 6. 8 must be struck
-off the debt in consideration of its being paid before the time. This
-is called DISCOUNT;[55] and £291. 13. 4 is called the _present value_
-of £350 due four years hence, discount being at 5 per cent. The rule
-for finding the present value of a sum of money (251) is: Multiply the
-sum by 100, and divide the product by 100 increased by the product of
-the rate per cent and number of years. If the time that the debt has
-yet to run be expressed in years and months, or months only, the months
-must be reduced to the equivalent fraction of a year.
-
-[55] This rule is obsolete in business. When a bill, for instance, of
-£100 having a year to run, is _discounted_ (as people now say) at 5 per
-cent, this means that 5 per cent of £100, or £5, is struck off.
-
-EXERCISES.
-
-What is the discount on a bill of £138. 14. 4, due 2 years hence,
-discount being at 4½ per cent?
-
-_Answer_, £11. 9. 1.
-
-What is the present value of £1031. 17, due 6 months hence, interest
-being at 3 per cent?
-
-_Answer_, £1016. 12.
-
-253. If we multiply by _a_ + _b_, or by _a_-_b_, when we should
-multiply by _a_, the result is wrong by the fraction
-
- _b_ _b_
- --- + _b_, or ---------,
- _a_ _a_ - _b_
-
-of itself: being too great in the first case, and too small in the
-second. Again, if we divide by _a_ + _b_, where we should have divided
-by _a_, the result is too small by the fraction _b_/_a_ of itself;
-while, if we divide by _a_-_b_ instead of _a_, the result is too great
-by the same fraction of itself. Thus, if we divide by 20 instead of
-17, the result is ³/₁₇ of itself too small; and if we divide by 360
-instead of 365, the result is too great by ⁵/₃₆₅, or ¹/₇₃ of itself.
-
-If, then, we wish to find the interest of a sum of money for a portion
-of a year, and have not the assistance of tables, it will be found
-convenient to suppose the year to contain only 360 days, in which case
-its 73d part (the 72d part will generally do) must be subtracted from
-the result, to make the alteration of 360 into 365. The number 360 has
-so large a number of divisors, that the rule of Practice (230) may
-always be readily applied. Thus, it is required to find the portion
-which belongs to 274 days, the yearly interest being £18. 9. 10, or
-18·491.
-
- 274 18·491
- ------
- 180 is ½ of 360 9·246
- ---
- 94
- 90 is ½ of 180 4·623
- --
- 4 is ¹/₉₀ of 360 ·205
- ------
- 9)14·074
- ------
- 8)1·564
- -----
- ·196
- 13·878 = £13 . 17 . 7 _Answer._
-
-But if the nearest farthing be wanted, the best way is to take 2-tenths
-of the number of days as a multiplier, and 73 as a divisor; since _m_ ÷
-365 is 2_m_ ÷ 730, or (²/₁₀)_m_ ÷ 73. Thus, in the preceding instance,
-we multiply by 54·8 and divide by 73; and 54·8 × 18·491 = 1013·3068,
-which divided by 73 gives 13·881, very nearly agreeing with the former,
-and giving £13. 17. 7½, which is certainly within a farthing of the
-truth.
-
-254. Suppose it required to divide £100 among three persons in such a
-way that their shares may be as 6, 5, and 9; that is, so that for every
-£6 which the first has, the second may have £5, and the third £9. It is
-plain that if we divide the £100 into 6 + 5 + 9, or 20 parts, the first
-must have 6 of those parts, the second 5, and the third 9. Therefore
-(245) their shares are respectively,
-
- 100 × 6 100 × 5 100 × 9
- £-------, £------- and £-------, or £30, £25, and £45.
- 20 20 20
-
-EXERCISES.
-
-Divide £394. 12 among four persons, so that their shares may be as 1,
-6, 7, and 18.--_Answer_, £12. 6. 7½; £73. 19. 9; £86. 6. 4½; £221. 19.
-3.
-
-Divide £20 among 6 persons, so that the share of each may be as much
-as those of all who come before put together.--_Answer_, The first two
-have 12_s._ 6_d._; the third £1. 5; the fourth £2. 10; the fifth £5;
-and the sixth £10.
-
-255. When two or more persons employ their money together, and gain
-or lose a certain sum, it is evidently not fair that the gain or loss
-should be equally divided among them all, unless each contributed the
-same sum. Suppose, for example, A contributes twice as much as B, and
-they gain £15, A ought to gain twice as much as B; that is, if the
-whole gain be divided into 3 parts, A ought to have two of them and B
-one, or A should gain £10 and B £5. Suppose that A, B, and C engage in
-an adventure, in which A embarks £250, B £130, and C £45. They gain
-£1000. How much of it ought each to have? Each one ought to gain as
-much for £1 as the others. Now, since there are 250 + 130 + 45, or 425
-pounds embarked, which gain £1000, for each pound there is a gain of
-£¹⁰⁰⁰/₄₂₄. Therefore A should gain 1000 × ²⁵⁰/₄₂₅ pounds, B should gain
-1000 × ¹³⁰/₄₂₅ pounds, and C 1000 × ⁴⁵/₄₂₅ pounds. On these principles,
-by the process in (245), the following questions may be answered.
-
-A ship is to be insured, in which A has ventured £1928, and B £4963.
-The expense of insurance is £474. 10. 2. How much ought each to pay of
-it?
-
-_Answer_, A must pay £132. 15. (2½).
-
-A loss of £149 is to be made good by three persons, A, B, and C. Had
-there been a gain, A would have gained 4 times as much as B, and C as
-much as A and B together. How much of the loss must each bear?
-
-_Answer_, A pays £59. 12, B £14. 18, and C £74. 10.
-
-256. It may happen that several individuals employ several sums of
-money together for different times. In such a case, unless there be
-a special agreement to the contrary, it is right that the more time
-a sum is employed, the more profit should be made upon it. If, for
-example, A and B employ the same sum for the same purpose, but A’s
-money is employed twice as long as B’s, A ought to gain twice as much
-as B. The principle is, that one pound employed for one month, or one
-year, ought to give the same return to each. Suppose, for example, that
-A employs £3 for 6 months, B £4 for 7 months, and C £12 for 2 months,
-and the gain is £100; how much ought each to have of it? Now, since
-A employs £3 for six months, he must gain 6 times as much as if he
-employed it one month only; that is, as much as if he employed £6 × 3,
-or £18, for one month; also, B gains as much as if he had employed £4 ×
-7 for one month; and C as if he had employed £12 × 2 for one month. If,
-then, we divide £100 into 6 × 3 + 4 × 7 + 12 × 2, or 70 parts, A must
-have 6 × 3, or 18, B must have 4 × 7, or 28, and C 12 × 2, or 24 of
-those parts. The shares of the three are, therefore,
-
- 6 × 3 × 100 4 × 7 × 100
- £----------------------, £----------------------,
- 6 × 3 + 4 × 7 + 12 × 2 6 × 3 + 4 × 7 + 12 × 2
-
- 12 × 2 × 100
- and £----------------------.
- 6 × 3 + 4 × 7 + 12 × 2
-
-EXERCISES.
-
-A, B, and C embark in an undertaking; A placing £3. 6 for 2 years, B
-£100 for 1 year, and C £12 for 1½ years. They gain £4276. 7 How much
-must each receive of the gain?
-
-_Answer_, A £226. 10. 4; B £3432. 1. 3; C £617. 15. 5.
-
-A, B, and C rent a house together for 2 years, at £150 per annum. A
-remains in it the whole time, B 16 months, and C 4½ months, during the
-occupancy of B. How much must each pay of the rent?[56]
-
-_Answer_, A should pay £190. 12. 6; B £90. 12. 6; C £18. 15.
-
-[56] This question does not at first appear to fall under the rule. A
-little thought will serve to shew that what probably will be the first
-idea of the proper method of solution is erroneous.
-
-257. These are the principal rules employed in the application of
-arithmetic to commerce. There are others, which, as no one who
-understands the principles here laid down can fail to see, are
-virtually contained in those which have been given. Such is what is
-commonly called the Rule of Exchange, for such questions as the
-following: If 20 shillings be worth 25½ francs, in France, what is £160
-worth? This may evidently be done by the Rule of Three. The rules here
-given are those which are most useful in common life; and the student
-who understands them need not fear that any ordinary question will be
-above his reach. But no student must imagine that from this or any
-other book of arithmetic he will learn precisely the modes of operation
-which are best adapted to the wants of the particular kind of business
-in which his future life may be passed. There is no such thing as a set
-of rules which are at once most convenient for a butcher and a banker’s
-clerk, a grocer and an actuary, a farmer and a bill-broker; but a
-person with a good knowledge of the _principles_ laid down in this
-work, will be able to examine and meet his own future wants, or, at
-worst, to catch with readiness the manner in which those who have gone
-before him have done so for themselves.
-
-
-
-
-APPENDIX TO THE FIFTH EDITION OF
-
-DE MORGAN’S ELEMENTS OF ARITHMETIC.
-
-
-
-
-I. ON THE MODE OF COMPUTING.
-
-
-The rules in the preceding work are given in the usual form, and the
-examples are worked in the usual manner. But if the student really wish
-to become a ready computer, he should strictly follow the methods laid
-down in this Appendix; and he may depend upon it that he will thereby
-save himself trouble in the end, as well as acquire habits of quick and
-accurate calculation.
-
-I. In numeration learn to connect each primary decimal number, 10,
-100, 1000, &c. not with the place in which the unit falls, but with
-the number of ciphers following. Call ten a _one-cipher_ number, a
-hundred a _two-cipher_ number, a million a _six-cipher_ number, and so
-on. If _five_ figures be cut off from a number, those that are left
-are hundred-thousands; for 100,000 is a _five-cipher_ number. Learn
-to connect tens, hundreds, thousands, tens of thousands, hundreds of
-thousands, millions, &c. with 1, 2, 3, 4, 5, 6, &c. in the mind. What
-is a _seventeen-cipher_ number? For every 6 in seventeen say _million_,
-for the remaining 5 say _hundred-thousand_: the answer is a hundred
-thousand millions of millions. If twelve places be cut off from the
-right of a number, what does the remaining number stand for?--_Answer_,
-As many millions of millions as there are units in it when standing by
-itself.
-
-II. After learning to count forwards and backwards with rapidity, as
-in 1, 2, 3, 4, &c. or 30, 29, 28, 27, &c., learn to count forwards or
-backwards by twos, threes, &c. up to nines at least, beginning from
-any number. Thus, beginning from four and proceeding by sevens, we
-have 4, 11, 18, 25, 32, &c., along which series you must learn to go
-as easily as along the series 1, 2, 3, 4, &c.; that is, as quick as
-you can pronounce the words. The act of addition must be made in the
-mind without assistance: you must not permit yourself to say, 4 and 7
-are 11, 11 and 7 are 18, &c.; but only 4, 11, 18, &c. And it would be
-desirable, though not so necessary, that you should go back as readily
-as forward; by sevens for instance, from sixty, as in 60, 53, 46, 39,
-&c.
-
-III. Seeing a number and another both of one figure, learn to catch
-instantly the number you must add to the smaller to get the greater.
-Seeing 3 and 8, learn by practice to think of 5 without the necessity
-of saying 3 _from_ 8 _and there remains_ 5. And if the second number be
-the less, as 8 and 3, learn also by practice how to pass _up_ from 8 to
-the next number which ends with 3 (or 13), and to catch the necessary
-augmentation, _five_, without the necessity of formally undertaking in
-words to subtract 8 from 13. Take rows of numbers, such as
-
- 4 2 6 0 5 0 1 8 6 4
-
-and practise this rule upon every figure and the next, not permitting
-yourself in this simple case ever to name the higher one. Thus, say 4
-and 8 (4 first, 2 second, 4 from the next number that ends with 2, or
-12, leaves 8), 2 and 4, 6 and 4, 0 and 5, 5 and 5, 0 and 1, 1 and 7, 8
-and 8, 6 and 8.
-
-IV. Study the same exercise as the last one with two figures and one.
-Thus, seeing 27 and 6, pass from 27 up to the next number that ends
-with 6 (or 36), catch the 9 through which you have to pass, and allow
-yourself to repeat as much as “27 and 9 are 36.” Thus, the row of
-figures 17729638109 will give the following practice: 17 and 0 are 17;
-77 and 5 are 82; 72 and 7 are 79; 29 and 7 are 36; 96 and 7 are 103; 63
-and 5 are 68; 38 and 3 are 41; 81 and 9 are 90; 10 and 9 are 19.
-
-V. In a number of two figures, practise writing down the units at the
-moment that you are keeping the attention fixed upon the tens. In the
-preceding exercise, for instance, write down the results, repeating the
-tens with emphasis at the instant of writing down the units.
-
-VI. Learn the multiplication table so well as to name the product the
-instant the factors are seen; that is, until 8 and 7, or 7 and 8,
-suggest 56 at once, without the necessity of saying “7 times 8 are 56.”
-Thus looking along a row of numbers, as 39706548, learn to name the
-products of every successive pair of digits as fast as you can repeat
-them, namely, 27, 63, 0, 0, 30, 20, 32.
-
-VII. Having thoroughly mastered the last exercise, learn further, on
-seeing three numbers, to augment the product of the first and second
-by the third without any repetition of words. Practise until 3, 8, 4,
-for instance, suggest 3 times 8 and 4, or 28, without the necessity of
-saying “3 times 8 are 24, and 4 is 28.” Thus, 179236408 will suggest
-the following practice, 16, 65, 21, 12, 22, 24, 8.
-
-VIII. Now, carry the last still further, as follows: Seeing four
-figures, as 2, 7, 6, 9, catch up the product of the first and second,
-increased by the third, as in the last, without a helping word; name
-the result, and add the next figure, name the whole result, laying
-emphasis upon the tens. Thus, 2, 7, 6, 9, must immediately suggest “20
-and 9 are 29.” The row of figures 773698974 will give the instances 52
-and 6 are 58; 27 and 9 are 36; 27 and 8 are 35; 62 and 9 are 71; 81 and
-7 are 88; 79 and 4 are 83.
-
-IX. Having four numbers, as 2, 4, 7, 9, vary the last exercise as
-follows: Catch the product of the first and second, increased by the
-third; but instead of adding the fourth, go up to the next number
-that ends with the fourth, as in exercise IV. Thus, 2, 4, 7, 9, are
-to suggest “15 and 4 are 19.” And the row of figures 1723968929 will
-afford the instances 9 and 4 are 13; 17 and 2 are 19; 15 and 1 are 16;
-33 and 5 are 38; 62 and 7 are 69; 57 and 5 are 62; 74 and 5 are 79.
-
-X. Learn to find rapidly the number of times a digit is contained
-in given units and tens, with the remainder. Thus, seeing 8 and 53,
-arrive at and repeat “6 and 5 over.” Common short division is the best
-practice. Thus, in dividing 236410792 by 7,
-
- 7)236410792
- ---------
- 33772970, remainder 2.
-
-All that is repeated should be 3 and 2; 3 and 5; 7 and 5; 7 and 2; 2
-and 6; 9 and 4; 7 and 0; 0 and 2.
-
-In performing the several rules, proceed as follows:
-
-ADDITION. Not one word more than repeating the numbers written in the
-following process: the accented figure is the one to be written down;
-the doubly accented figure is carried (and don’t _say_ “carry 3,” but
-do it).
-
- 47963
- 1598
- 26316
- 54792
- 819
- 6686
- ------
- 138174
-
-6, 15, 17, 23, 31, 3″ 4′; 11, 12, 21, 22, 31, 3″7′; 9, 17, 24, 27, 32,
-4″1′; 10, 14, 20, 21, 2″8′; 7, 9, 1′3′.
-
-In verifying additions, instead of the usual way of omitting one line,
-adding without it, and then adding the line omitted, verify each column
-by adding it both upwards and downwards.
-
-SUBTRACTION. The following process is enough. The carriages, being
-always of _one_, need not be mentioned.
-
- From 79436258190
- Take 58645962738
- -----------
- 20790295452
-
-8 and 2′, 4 and 5′, 7 and 4′, 3 and 5′, 6 and 9′, 10 and 2′, 6 and 0′,
-4 and 9′, 7 and 7′, 9 and 0′, 5 and 2′. It is useless to stop and say,
-8 and 2 make 10; for as soon as the 2 is obtained, there is no occasion
-to remember what it came from.
-
-MULTIPLICATION. The following, put into words, is all that need be
-repeated in the multiplying part; the addition is then done as usual.
-The unaccented figures are carried.
-
- 670383
- 9876
- -------
- 4022298 18′, 49′, 22′, 2′, 42′, 4′0′,
- 4692681 21′, 58′, 26′, 2′, 49′, 4′6′,
- 5363064 24′, 66′, 30′, 3′, 56′, 5′3′,
- 6033447 27′, 74′, 34′, 3′, 63′, 6′0′.
- ----------
- 6620702508
-
-Verify each line of the multiplication and the final result by casting
-out the nines. (_Appendix_ II. p. 166.)
-
-It would be almost as easy, for a person who has well practised the 8th
-exercise, to add each line to the one before in the process, thus:
-
- 670383
- 9876
- -------
- 4022298
- 50949108
- 587255508
- 6620702508
-
-8; 21 and 9 are 30′; 59 and 2 are 61′; 27 and 2 are 29; 2 and 2 are 4′;
-49 and 0 are 49′; 46 and 4 are 5′0′.
-
-On the right is all the process of forming the second line, which
-completes the multiplication by 76, as the third line completes that by
-876, and the fourth line that by 9876.
-
-DIVISION. Make each multiplication and the following subtraction in one
-step, by help of the process in the 9th exercise, as follows:
-
- 27693)441972809662(15959730
- 165042
- 265778
- 165410
- 269459
- 202226
- 83756
- 6772
-
-The number of words by which 26577 is obtained from 165402 (the
-multiplier being 5) is as follows: 15 and 7′ are 2″2; 47 and 7′ are
-5″4; 35 and 5′ are 4″0; 39 and 6′ are 4″5; 14 and 2′ are 16.
-
-The processes for extracting the square root, and for the solution of
-equations (_Appendix_ XI.), should be abbreviated in the same manner as
-the division.[57]
-
-[57] The teacher will find further remarks on this subject in the
-_Companion to the Almanac_ for 1844, and in the _Supplement to the
-Penny Cyclopædia_, article _Computation_.
-
-
-
-
-APPENDIX II.
-
-ON VERIFICATION BY CASTING OUT NINES AND ELEVENS.
-
-
-The process of _casting out the nines_, as it is called, is one which
-the young computer should learn and practise, as a check upon his
-computations. It is not a complete check, since if one figure were
-made too small, and another as much too great, it would not detect
-this double error; but as it is very unlikely that such a double error
-should take place, the check furnishes a strong presumption of accuracy.
-
-The proposition upon which this method depends is the following: If _a,
-b, c, d_ be four numbers, such that
-
-_a_ = _bc_ + _d_,
-
-and if _m_ be any other number whatsoever, and if _a, b, c, d_,
-severally divided by _m_, give the remainders _p, q, r, s_, then
-
-_p_ and _qr_ + _s_
-
-give the same remainder when divided by _m_ (and perhaps are themselves
-equal).
-
-For instance, 334 = 17 × 19 + 11;
-
-divide these four numbers by 7, the remainders are 5, 3, 5, and 4. And
-5 and 5 × 3 + 4, or 5 and 19, both leave the remainder 5 when divided
-by 7.
-
-Any number, therefore, being used as a divisor, may be made a check
-upon the correctness of an operation. To provide a check which may be
-most fit for use, we must take a divisor the remainder to which is most
-easily found. The most convenient divisors are 3, 9, and 11, of which 9
-is far the most useful.
-
-As to the numbers 3 and 9, the remainder is always the same as that
-of the sum of the digits. For instance, required the remainder of
-246120377 divided by 9. The sum of the digits is 2 + 4 + 6 + 1 + 2 + 0
-+ 3 + 7 + 7, or 32, which gives the remainder 5. But the easiest way
-of proceeding is by throwing out nines as fast as they arise in the
-sum. Thus, repeat 2, 6 (2 + 4), 12 (6 + 6), say 3 (throwing out 9),
-4, 6, 9 (throw this away), 7, 14, (or throwing out the 9) 5. This is
-the remainder required, as would appear by dividing 246120377 by 9. A
-proof may be given thus: It is obvious that each of the numbers, 1,
-10, 100, 1000, &c. divided by 9, leaves a remainder 1, since they are
-1, 9 + 1, 99 + 1, &c. Consequently, 2, 20, 200, &c. leave the remainder
-2; 3, 30, 300, the remainder 3; and so on. If, then, we divide, say
-1764 by 9 in parcels, 1000 will be one more than an exact number of
-nines, 700 will be seven more, and 60 will be six more. So, then, from
-1, 7, 6, 4, put together, and the nines taken out, comes the only
-remainder which can come from 1764.
-
-To apply this process to a multiplication: It is asserted, in page 32,
-that
-
-10004569 × 3163 = 31644451747.
-
-In casting out the nines from the first, all that is necessary to
-repeat is, one, five, ten, one, _seven_; in the second, three, four,
-ten, one, _four_; in the third, three, four, ten, one, five, nine,
-four, nine, eight, twelve, three, ten, _one_. The remainders then are,
-7, 4, 1. Now, 7 × 4 is 28, which, casting out the nines, gives 1, the
-same as the product.
-
-Again, in page 43, it is asserted that
-
-23796484 = 130000 × 183 + 6484.
-
-Cast out the nines from 13000, 183, 6484, and we have 4, 3, and 4. Now,
-4 × 3 + 4, with the nines cast out, gives 7; and so does 23796484.
-
-To avoid having to remember the result of one side of the equation,
-or to write it down, in order to confront it with the result of the
-other side, proceed as follows: Having got the remainder of the more
-complicated side, into which two or more numbers enter, subtract it
-from 9, and carry the remainder into the simple side, in which there is
-only one number. Then the remainder of that side ought to be 0. Thus,
-having got 7 from the left-hand of the preceding, take 2, the rest
-of 9, forget 7, and carry in 2 as a beginning to the left-hand side,
-giving 2, 4, 7, 14, 5, 11, 2, 6, 14, 5, 9, 0.
-
-Practice will enable the student to cast out nines with great rapidity.
-
-This process of casting out the nines does not detect any errors
-in which the remainder to 9 happens to be correct. If a process be
-tedious, and some additional check be desirable, the method of casting
-out _elevens_ may be followed after that of casting out the nines.
-Observe that 10 + 1, 100-1, 1000 + 1, 10000-1, &c. are all divisible by
-eleven. From this the following rule for the remainder of division by
-11 may be deduced, and readily used by those who know the algebraical
-process of subtraction. For those who have not got so far, it may be
-doubted whether the rule can be made easier than the actual division by
-11.
-
-Subtract the first figure from the second, the result from the third,
-the result from the fourth, and so on. The final result, or the rest
-of 11 if the figure be negative, is the remainder required. Thus, to
-divide 1642915 by 11, and find the remainder, we have 1 from 6, 5; 5
-from 4,-1;-1 from 2, 3; 3 from 9, 6; 6 from 1,-5;-5 from 5, 10; and
-10 is the remainder. But 164 gives-1, and 10 is the remainder; 164291
-gives-5, and 6 is the remainder. With very little practice these
-remainders may be read as rapidly as the number itself. Thus, for
-127619833424 need only be repeated, 1, 6, 0, 1, 8, 0, 3, 0, 4,-2, 6,
-and 6 is the remainder.
-
-When a question has been tried both by nines and elevens, there can be
-no error unless it be one which makes the result wrong by a number of
-times 99 exactly.
-
-
-
-
-APPENDIX III.
-
-ON SCALES OF NOTATION.
-
-
-We are so well accustomed to 10, 100, &c., as standing for ten, ten
-tens, &c., that we are not apt to remember that there is no reason why
-10 might not stand for five, 100 for five fives, &c., or for twelve,
-twelve twelves, &c. Because we invent different columns of numbers, and
-let units in the different columns stand for collections of the units
-in the preceding columns, we are not therefore bound to allow of no
-collections except in tens.
-
-If 10 stood for 2, that is, if every column had its unit double of the
-unit in the column on the right, what we now represent by 1, 2, 3,
-4, 5, 6, &c., would be represented by 1, 10, 11, 100, 101, 110, 111,
-1000, 1001, 1010, 1011, 1100, &c. This is the _binary_ scale. If we
-take the _ternary_ scale, in which 10 stands for 3, we have 1, 2, 10,
-11, 12, 20, 21, 22, 100, 101, 102, 110, &c. In the _quinary_ scale, in
-which 10 is five, 234 stands for 2 twenty-fives, 3 fives, and 4, or
-sixty-nine. If we take the _duodenary_ scale, in which 10 is twelve, we
-must invent new symbols for ten and eleven, because 10 and 11 now stand
-for twelve and thirteen; use the letters _t_ and _e_. Then 176 means 1
-twelve-twelves, 7 twelves, and 6, or two hundred and thirty-four; and
-1_te_ means two hundred and seventy-five.
-
-The number which 10 stands for is called the _radix_ of the _scale of
-notation_. To change a number from one scale into another, divide the
-number, written as in the first scale, by the number which is to be the
-radix of the new scale; repeat this division again and again, and the
-remainders are the digits required. For example, what, in the quinary
-scale, is that number which, in the decimal scale, is 17036?
-
- 5)17036
- -----
- 5)3407 Remʳ. 1
- ----
- 5)681 2
- ---
- 5)136 1
- ---
- 5)27 1
- --
- 5)5 2
- -
- 5)1 0
- -
- 0 1
-
- _Answer_ 1021121
-
- Quinary. Decimal.
- _Verification_, 1000000 means 15625
- 20000 1250
- 1000 125
- 100 25
- 20 10
- 1 1
- ------ -----
- 1021121 17036
-
-The reason of this rule is easy. Our process of division is nothing but
-telling off 17036 into 3407 fives and 1 over; we then find 3407 fives
-to be 681 fives of fives and 2 _fives_ over. Next we form 681 fives of
-fives into 136 fives of fives of fives and 1 five of fives over; and so
-on.
-
-It is a useful exercise to multiply and divide numbers represented in
-other scales of notation than the common or decimal one. The rules are
-in all respects the same for all systems, _the number carried being
-always the radix of the system_. Thus, in the quinary system we carry
-fives instead of tens. I now give an example of multiplication and
-division:
-
- Quinary. Decimal.
- 42143 means 2798
- 1234 194
- ------ -----
- 324232 11192
- 232034 25182
- 134341 2798
- 42143
- --------- ------
- 114332222 542812
-
- Duodecimal. Decimal.
- 4_t_9)76_t_4_e_08(16687 705)22610744(32071
- 4_t_9 1460
- ----- 5074
- 2814 1394
- 2546 689
- -----
- 28_te_
- 2546
- ------
- 3650
- 3320
- -----
- 3308
- 2_t_33
- ------
- 495
-
-Another way of turning a number from one scale into another is as
-follows: Multiply the first digit by the _old_ radix _in the new
-scale_, and add the next digit; multiply the result again by the old
-radix in the new scale, and take in the next digit, and so on to the
-end, always using the radix of the scale you want to leave, and the
-notation of the scale you want to end in.
-
-Thus, suppose it required to turn 16687 (duodecimal) into the decimal
-scale, and 16432 (septenary) into the quaternary scale:
-
- 16687 16432
- Duodecimals into Decimals. Septenaries into Quaternaries.
- 1 × 12 + 6 = 18 1 × 7 + 6 = 31
- × 12 + 6 × 7 + 4
- --- ----
- 222 1133
- × 12 + 8 × 7 + 3
- ---- -----
- 2672 22130
- × 12 + 7 × 7 + 2
- ------ -------
- _Answer_ 32071 1021012
-
-Owing to our division of a foot into 12 equal parts, the duodecimal
-scale often becomes very convenient. Let the square foot be also
-divided into 12 parts, each part is 12 square inches, and the 12th of
-the 12th is one square inch. Suppose, now, that the two sides of an
-oblong piece of ground are 176 feet 9 inches 7-12ths of an inch, and
-65 feet 11 inches 5-12ths of an inch. Using the duodecimal scale, and
-_duodecimal fractions_, these numbers are 128·97 and 55·_e_5. Their
-product, the number of square feet required, is thus found:
-
- 128·97
- 55·_e_5
- ---------
- 617_ee_
- 116095
- 617_ee_
- 617_ee_
- ------------
- 68_e_8144_e_
-
-_Answer_, 68_e_8·144_e_ (duod.) square feet, or 11660 square feet 16
-square inches ⁴/₁₂ and ¹¹/₁₄₄ of a square inch.
-
-It would, however, be exact enough to allow 2-hundredths of a foot
-for every quarter of an inch, an additional hundredth for every 3
-inches,[58] and 1-hundredth more if there be a 12th or 2-12ths above
-the quarter of an inch. Thus, 9⁷/₁₂ inches should be ·76 + ·03 + ·01,
-or ·80, and 11⁵/₁₂ would be ·95; and the preceding might then be found
-decimally as 176·8 × 65·95 as 11659·96 square feet, near enough for
-every practical purpose.
-
-[58] And at discretion one hundredth more for a large fraction of three
-inches.
-
-
-
-
-APPENDIX IV.
-
-ON THE DEFINITION OF FRACTIONS.
-
-
-The definition of a fraction given in the text shews that ⁷/₉, for
-instance, is the _ninth_ part of _seven_, which is shewn to be the
-same thing as _seven-ninths_ of a unit. But there are various modes of
-speech under which a fraction may be signified, all of which are more
-or less in use.
-
- 1. In ⁷/₉ we have the 9th part of 7.
-
- 2. 7-9ths of a unit.
-
- 3. The fraction which 7 is of 9.
-
- 4. The times and parts of a time (in this case part of a time only)
- which 7 contains 9.
-
- 5. The multiplier which turns _nines_ into _sevens_.
-
- 6. The _ratio_ of 7 to 9, or the _proportion_ of 7 to 9.
-
- 7. The multiplier which alters a number in the ratio of 9 to 7.
-
- 8. The 4th proportional to 9, 1, and 7.
-
-The first two views are in the text. The third is deduced thus: If
-we divide 9 into 9 equal parts, each is 1, and 7 of the parts are 7;
-consequently the fraction which 7 is of 9 is ⁷/₉. The fourth view
-follows immediately: For _a time_ is only a word used to express one
-of the repetitions which take place in multiplication, and we allow
-ourselves, by an easy extension of language, to speak of a portion
-of a number as being that number taken a _part of a time_. The fifth
-view is nothing more than a change of words: A number reduced to ⁷/₉
-of its amount has every 9 converted into a 7, and any fraction of a
-9 which may remain over into the corresponding fraction of 7. This
-is completely proved when we prove the equation ⁷/₉ of _a_ = 7 times
-_a_/9. The sixth, seventh, and eighth views are illustrated in the
-chapter on proportion.
-
-When the student comes to algebra, he will find that, in all the
-applications of that science, fractions such as _a_/_b_ most frequently
-require that _a_ and _b_ should be themselves supposed to be fractions.
-It is, therefore, of importance that he should learn to accommodate his
-views of a fraction to this more complicated case.
-
- 2½
- Suppose we take -----.
- 4³/₅
-
-We shall find that we have, in this case, a better idea of the views
-from and after the third inclusive, than of the first and second, which
-are certainly the most simple ways of conceiving ⁷/₉. We have no notion
-of the (4³/₅)th part of 2½,
-
- 1 ( 3 )
- nor of 2 ---(4---)ths
- 2 ( 5 )
-
-of a unit; indeed, we coin a new species of adjective when we talk of
-the (4³/₅)th part of anything. But we can readily imagine that 2½ is
-some fraction of 4³/₅; that the first is _some_ part of a time the
-second; that there must be _some_ multiplier which turns every 4³/₅ in
-a number into 2½; and so on. Let us now see whether we can invent a
-distinct mode of applying the first and second views to such a compound
-fraction as the above.
-
-We can easily imagine a fourth part of a length, and a fifth part,
-meaning the lines of which 4 and 5 make up the length in question;
-and there is also in existence a length of which four lengths and
-two-fifths of a length make up the original length in question. For
-instance, we might say that 6, 6, 2 is a division of 14 into 2⅓ equal
-parts--2 equal parts, 6, 6, and a third of a part, 2. So we might agree
-to say, that the (2⅓)th, or (2⅓)rd, or (2⅓)st (the reader may coin the
-adjective as he pleases) part of 14 is 6. If we divide the line A B
-into eleven equal parts in C, D, E, &c., we must then say that A C is
-the 11th part,
-
-[Illustration]
-
-A D the (5½)th, A E the (3⅔)th, A F the (2¾)th, A G the (2⅕)th, A H
-the (1⅚)th, A I the (1⁴/₇)th, A K the (1⅜)th, A L the (1²/₉)th, A M
-the (1⅒)th, and A B itself the 1st part of A B. The reader may refuse
-the language if he likes (though it is not so much in defiance of
-etymology as talking of _multiplying_ by ½); but when A B is called 1,
-he must either call A F 1/(2¾), or make one definition of one class
-of fractions and another of another. Whatever abbreviations they may
-choose, all persons will agree that _a_/_b_ is a direction to find such
-a fraction as, repeated _b_ times, will give 1, and then to take that
-fraction _a_ times.
-
-So, to get 2½/4⅗, the simplest way is to divide the whole unit into 46
-parts; 10 of these parts, repeated 4⅗ times, give the whole. The
-
-[Illustration]
-
-4⅗th is then ¹⁰/₄₆, and 2½ such parts is ²⁵/₄₆, or A C. The student
-should try several examples of this mode of interpreting complex
-fractions.
-
-But what are we to say when the denominator itself is less than unity,
-as in 3¼/⅖? Are we to have a (⅖)th part of a unit? and what is it?
-Had there been a 5 in the denominator, we should have taken the part
-of which 5 will make a unit. As there is ⅖ in the denominator, we must
-take the part of which ⅖ will be a unit. That part is larger than a
-unit; it is 2½ units; 2½ is that of which ⅖ is 1. The above fraction
-then directs us to repeat 2½ units 3¼ times. By extending our word
-‘multiplication’ to the taking of a part of a time, all multiplications
-are also divisions, and all divisions multiplications, and all the
-terms connected with either are subject to be applied to the results of
-the other.
-
-If 2⅓ yards cost 3½ shillings, how much does one yard cost? In such a
-case as this, the student looks at a more simple question. If 5 yards
-cost 10 shillings, he sees that each yard costs ¹⁰/₅, or 2 shillings,
-and, concluding that the same process will give the true result when
-the data are fractional, he forms 3½/2⅓, reduces it by rules to ³/₂
-or 1½, and concludes that 1 yard costs 18 pence. The answer happens
-to be correct; but he is not to suppose that this rule of copying for
-fractions whatever is seen to be true of integers is one which requires
-no demonstration. In the above question we want money which, repeated
-2⅓ times, shall give 3½ shillings. If we divide the shilling into 14
-equal parts, 6 of these parts repeated 2⅓ times give the shilling. To
-get 3½ times as much by the same repetition, we must take 3½ of these 6
-parts at each step, or 21 parts. Hence, ²¹/₁₄, or 1½, is the number of
-shillings in the price.
-
-
-
-
-APPENDIX V.
-
-ON CHARACTERISTICS.
-
-
-When the student comes to use logarithms, he will find what follows
-very useful. In the mean while, I give it merely as furnishing a rapid
-rule for finding the place of a decimal point in the quotient before
-the division is commenced.
-
-When a bar is written over a number, thus, 7︤ let the number be called
-negative, and let it be thus used: Let it be augmented by additions of
-its own species, and diminished by subtractions; thus, 7︤ and 2︤ give
-9︤, and let 7︤ with 2︤ subtracted give 5︤. But let the _addition_
-of a number without the bar _diminish_ the negative number, and the
-_subtraction increase_ it. Thus, 7︤ and 4 are 3︤, 7︤ and 12 make 5, 7︤
-with 8 subtracted is 1︦5. In fact, consider 1, 2, 3, &c., as if they
-were gains, and 1︤, 2︤, 3︤, as if they were losses: let the addition
-of a gain or the removal of a loss be equivalent things, and also the
-removal of a gain and the addition of a loss. Thus, when we say that
-4︤ diminished by 1︦1 gives 7, we say that a loss of 4 incurred at the
-moment when a loss of 11 is removed, is, on the whole, equivalent to a
-gain of 7; and saying that 4︤ diminished by 2 is 6︤, we say that a loss
-of 4, accompanied by the removal of a gain of 2, is altogether a loss
-of 6.
-
-By the _characteristic_ of a number understand as follows: When there
-are places before the decimal point, it is one less than the number
-of such places. Thus, 3·214, 1·0083, 8 (which is 8·00 ...) 9·999, all
-have 0 for their characteristics. But 17·32, 48, 93·116, all have 1;
-126·03 and 126 have 2; 11937264·666 has 7. But when there are no places
-before the decimal point, look at the first decimal place which is
-significant, and make the characteristic negative accordingly. Thus,
-·612, ·121, ·9004, in all of which significance begins in the first
-decimal place, have the characteristic 1︤; but ·018 and ·099 have 2︤;
-·00017 has 4︤; ·000000001 has 9︤.
-
-To find the characteristic of a quotient, subtract the characteristic
-of the divisor from that of the dividend, carrying one before
-subtraction if the first significant figures of the divisor are greater
-than those of the dividend. For instance, in dividing 146·08 by ·00279.
-The characteristics are 2 and 3︤; and 2 with 3︤ removed would be 5. But
-on looking, we see that the first significant figures of the divisor,
-27, taken by themselves, and without reference to their local value,
-mean a larger number than 14, the first two figures of the dividend.
-Consequently, to 3︤ we carry 1 before subtracting, and it then becomes
-2︤, which, taken from 2, gives 4. And this 4 is the characteristic of
-the quotient, so that the quotient has 5 places before the decimal
-point. Or, if _abcdef_ be the first figures of the quotient, the
-decimal point must be thus placed, _abcde·f_. But if it had been to
-divide ·00279 by 146·08, no carriage would have been required; and 3︤
-diminished by 2 is 5︤; that is, the first significant figure of the
-quotient is in the 5th place. The quotient, then, has ·0000 before
-any significant figure. A few applications of this rule will make it
-easy to do it in the head, and thus to assign the meaning of the first
-figure of the quotient even before it is found.
-
-
-
-
-APPENDIX VI.
-
-ON DECIMAL MONEY.
-
-
-Of all the simplifications of commercial arithmetic, none is comparable
-to that of expressing shillings, pence, and farthings as decimals of a
-pound. The rules are thereby put almost upon as good a footing as if
-the country possessed the advantage of a real decimal coinage.
-
-Any fraction of a pound sterling may be decimalised by rules which can
-be made to give the result at once.
-
- Two shillings is £·100 |
- One shilling is £·050 |
- Sixpence is £·025 |
- One farthing is £·001 | 04⅙
-
-Thus, every pair of shillings is a unit in the first decimal place;
-an odd shilling is a 50 in the second and third places; a farthing is
-so nearly the thousandth part of a pound, that to say one farthing is
-·001, two farthings is ·002, &c., is so near the truth that it makes
-no error in the first three decimals till we arrive at sixpence, and
-then 24 farthings is exactly ·025 or 25 thousandths. But 25 farthings
-is ·026, 26 farthings is ·027, &c. Hence the rule for the _first three
-places_ is
-
-_One in the first for every pair of shillings; 50 in the second
-and third for the odd shilling, if any; and 1 for every farthing
-additional, with 1 extra for sixpence._
-
- Thus, 0_s._ 3½_d._ = £·014
- 0_s._ 7¾_d._ = £·032
- 1_s._ 2½_d._ = £·060
- 1_s._ 11¼_d._ = £·096
- 2_s._ 6_d._ = £·125
- 2_s._ 9½_d._ = £·139
- 3_s._ 2¾_d._ = £·161
- 13_s._ 10¾_d._ = £·694
-
-In the fourth and fifth places, and those which follow, it is obvious
-that we have no produce from any farthings except those above sixpence.
-For at every sixpence, ·00004⅙ is converted into ·001, and this has
-been already accounted for. Consequently, to fill up the _fourth and
-fifth_ places,
-
-_Take 4 for every farthing[59] above the last sixpence, and an
-additional 1 for every six farthings, or three halfpence._
-
-[59] The student should remember all the multiples of 4 up to 4 × 25,
-or 100.
-
-The remaining places arise altogether from ·00000⅙ for every farthing
-above the last three halfpence; for at every three halfpence complete,
-·00000⅙ is converted into ·00001, and has been already accounted for.
-Consequently, to fill up _all the places after the fifth_,
-
-_Let the number of farthings above the last three halfpence be a
-numerator, 6 a denominator, and annex the figures of the corresponding
-decimal fraction._
-
-It may be easily remembered that
-
- The figures of ¹/₆ are 166666...
-
- ” ²/₆ ... 333333...
-
- ” ³/₆ ... 5
-
- ” ⁴/₆ ... 666666...
-
- ” ⁵/₆ ... 833333...
-
- 0_s._ 3½_d._ = ·014|58|3333...
-
- 0_s._ 7¾_d._ = ·032|29|1666...
-
- 1_s._ 2½_d._ = ·060|41|6666...
-
- 1_s._ 11¼_d._ = ·096|87|5
-
- 2_s._ 6_d._ = ·125|00|0000...
-
- 2_s._ 9½_d._ = ·139|58|3333...
-
- 3_s._ 2¾_d._ = ·161|45|83333...
-
- 13_s._ 10¾_d._ = ·694|79|1666...
-
-The following examples will shew the use of this rule, if the student
-will also work them in the common way.
-
-To turn pounds, &c., into farthings: Multiply the pounds by 960, or
-by 1000-40, or by 1000(1-⁴/₁₀₀); that is, from 1000 times the pounds
-subtract 4 per cent of itself. Thus, required the number of farthings
-in £1663. 11. 9¾.
-
- 1663·590625 × 1000 = 1663590·625
- 4 per cent of this, 66543·625
- -----------
- No. of farthings required, 1597047
-
-What is 47½ per cent of £166. 13. 10 and ·6148 of £2971. 16. 9?
-
- 166·691
- --------
- 40 p. c. 66·6764
- 5 p. c. 8·3346
- 2½ p. c. 4·1673
- --------
- 79·1783
- £79.3.6¾
-
- 2971·837
- ---------
- ·6 1783·1022
- ·01 29·7184
- ·004 11·8873
- ·0008 2·3775
- ---------
- 1827·0854
- £1827.1.8½
-
-The inverse rule for turning the decimal of a pound into shillings,
-pence, and farthings, is obviously as follows:
-
-_A pair of shillings for every unit in the first place; an odd shilling
-for 50 (if there be 50) in the second and third places; and a farthing
-for every thousandth left, after abating 1 if the number of thousandths
-so left exceed 24._
-
-The direct rule (with three places) gives too little, the inverse rule
-too much, except at the end of a sixpence, when both are accurate.
-Thus, £·183 is rather less than 3_s._ 8_d._, and 6_s._ 4¾_d._ is rather
-greater than £319; or when the two do not exactly agree, the _common
-money is the greatest_. But £·125 and £·35 are exactly 2_s._ 6_d._ and
-7_s._
-
-Required the price of 17 cwt. 81 lb. 13½ oz. at £3.11.9¾ per cwt. true
-to the hundredth of a farthing.
-
- 3·590625
- 17
- ---------
- 61·040625
- lb. 56 ½ 1·795313
- 16 ⅐ ·512946
- 7 ⅛ ·224414
- 2 ⅛ ·064118
- oz. 8 ¼ ·016029
- 4 ½ ·008015
- 1 ¼ ·002004
- ½ ½ ·001002
- ---------
- £63·664466
- £63.13.3½
-
-Three men, A, B, C, severally invest £191.12.7¾, £61.14.8, and
-£122.1.9½ in an adventure which yields £511.12.6½. How ought the
-proceeds to be divided among them?
-
- A, 191·63229
- B, 61·73333
- C, 122·08958 Produce of £1.
- ---------
- 375·45520)511·62708(1·362686
- 136·17188
- 23·53532
- 1·00801
- 25710
- 3183
- 180
-
- 1·362686 1·362686 1·362686
- 92·236191 33·33716 85·980221
- --------- --------- ---------
- 1·362686 8·17612 1·362686
- 1·226417 13627 272537
- 13627 9538 27254
- 8176 409 1090
- 409 41 122
- 27 4 7
- 3 -------- 1
- 1 8·41231 ---------
- --------- 1·663697
- 2·611346
-
- 261·1346 ... A’s share £261.2.8¼
- 84·1231 ... B’s ... 84.2.5¾
- 166·3697 ... C’s ... 166.7.4¾
- -------- -------------
- 511·6274 £511.2.6¾
-
-If ever the fraction of a farthing be wanted, remember that the
-_coinage_-result is larger than the decimal of a pound, when we use
-only three places. From 1000 times the decimal take 4 per cent, and we
-get the exact number of farthings, and we need only look at the decimal
-then left to set the preceding right. Thus, in
-
- 134·6 123·1 369·7
- 5·38 4·92 14·79
- ----- ------ ------
- ·22 ·18 ·91
-
-we see that (if we use four decimals only) the pence of the above
-results are nearly 8_d._ ·22 of a farthing, 5½_d._ ·18, and 4½_d._ ·91.
-
-A man can pay £2376. 4. 4½, his debts being £3293. 11. 0¾. How much per
-cent can he pay, and how much in the pound?
-
- 3293·553)2376·2180(·7214756
- 70·7309
- 4·8598
- 1·5662
- 2488
- 183
- 18
-
- _Answer_, £72. 2.11½ per cent.
- 0.14.5¼ per pound.
-
-
-
-
-APPENDIX VII.
-
-ON THE MAIN PRINCIPLE OF BOOK-KEEPING.
-
-
-A brief notice of the principle on which accounts are kept (when they
-are _properly_ kept) may perhaps be useful to students who are learning
-book-keeping, as the treatises on that subject frequently give too
-little in the way of explanation.
-
-Any person who is engaged in business must desire to know accurately,
-whenever an investigation of the state of his affairs is made.
-
-1, What he had at the commencement of the account, or immediately after
-the last investigation was made; 2, What he has gained and lost in the
-interval in all the several branches of his business; 3, What he is now
-worth. From the first two of these things he obviously knows the third.
-In the interval between two investigations, he may at any one time
-desire to know how any one account stands.
-
-An _account_ is a recital of all that has happened, in reference to any
-class of dealings, since the last investigation. It can only consist
-of receipts and expenditures, and so it is said to have two sides, a
-_debtor_ and a _creditor_ side.
-
-All accounts are kept in _money_. If goods be bought, they are
-estimated by the money paid for them. If a debtor give a bill of
-exchange, being a promise to pay a certain sum at a certain time, it is
-put down as worth that sum of money. All the tools, furniture, horses,
-&c. used in the business are rated at their value in money. All the
-actual coin, bank-notes, &c., which are in or come in, being the only
-money in the books which really is money, is called _cash_.
-
-The accounts are kept as if every different sort of account belonged
-to a separate person, and had an interest of its own, which every
-transaction either promotes or injures. If the student find that it
-helps him, he may imagine a clerk to every account: one to take charge
-of, and regulate, the actual cash; another for the bills which the
-house is to receive when due; another for those which it is to pay when
-due; another for the cloth (if the concern deal in cloth); another
-for the sugar (if it deal in sugar); one for every person who has an
-account with the house; one for the profits and losses; and so on.
-
-All these clerks (or accounts) belonging to one merchant, must account
-to him in the end--must either produce all they have taken in charge,
-or relieve themselves by shewing to whom it went. For all that they
-have received, for every responsibility they have undertaken to _the
-concern itself_, they are bound, or are _debtors_; for everything
-which has passed out of charge, or about which they are relieved from
-answering _to the concern_, they are unbound, or are _creditors_.
-These words must be taken in a very wide sense by any one to whom
-book-keeping is not to be a mystery. Thus, whenever any account assumes
-responsibility to any parties _out of the concern_, it must be creditor
-in the books, and debtor whenever it discharges any other parties of
-their responsibility. But whenever an account removes responsibility
-from any other account in the same books it is debtor, and creditor
-whenever it imposes the same.
-
-To whom are all these parties, or accounts, bound, and from whom are
-they released? Undoubtedly the merchant himself, or, more properly,
-the _balance-clerk_, presently mentioned. But it is customary to say
-that the accounts are debtors _to_ each other, and creditors _by_
-each other. Thus, cash _debtor_ to bills receivable, means that the
-cash account (or the clerk who keeps it) is bound to answer for a sum
-which was paid on a bill of exchange due to the house. At full length
-it would be: “Mr. C (who keeps the cash-box) has received, and is
-answerable for, this sum which has been paid in by Mr. A, when he paid
-his bill of exchange.” On the other hand, the corresponding entry in
-the account of bills receivable runs--bills receivable, _creditor_
-by cash. At full length: “Mr. B (who keeps the bills receivable) is
-freed from all responsibility for Mr. A’s bill, which he once held, by
-handing over to Mr. C, the cash-clerk, the money with which Mr. A took
-it up.” Bills receivable creditor _by_ cash is intelligible, but cash
-debtor _to_ bills receivable is a misnomer. The cash account is debtor
-_to the merchant by_ the sum received for the bill, and it should be
-cash debtor _by_ bill receivable. The fiction of debts, not one of
-which is ever paid to the party _to_ whom it is said to be owing,
-though of no consequence in practice, is a stumbling-block to the
-learner; but he must keep the phrase, and remember its true meaning.
-
-The account which is made _debtor_, or bound, is said to be _debited_;
-that which is made _creditor_, or released, is said to be _credited_.
-All who receive must be _debited_; all who give must be _credited_.
-
-No cancel is ever made. If cash received be afterwards repaid, the
-sum paid is not struck off the receipts (or debtor-side of the cash
-account), but a discharge, or credit, is written on the expenditure (or
-credit) side.
-
-The book in which the accounts are kept is called a _ledger_. It
-has double columns, or else the debtor-side is on one page, and the
-creditor side on the opposite, of each account. The debtor-side is
-always the left. Other books are used, but they are only to help in
-keeping the ledger correct. Thus there may be a _waste-book_, in which
-all transactions are entered as they occur, in common language; a
-_journal_, in which the transactions described in the waste-book are
-entered at stated periods, in the language of the ledger. The items
-entered in the journal have references to the pages of the ledger
-to which they are carried, and the items in the ledger have also
-references to the pages of the journal from which they come; and by
-this mode of reference it is easy to make a great deal of abbreviation
-in the ledger. Thus, when it happens, in making up the journal to a
-certain date, that several different sums were paid or received at or
-near the same time, the totals may be entered in the ledger, and the
-cash account may be made debtor to, or creditor by, sundry accounts,
-or sundries; the sundry accounts being severally credited or debited
-for their shares of the whole. The only book that need be explained is
-the ledger. All the other books, and the manner in which they are kept,
-important as they may be, have nothing to do with the main principle
-of the method. Let us, then, suppose that all the items are entered
-at once in the ledger as they arise. It has appeared that every item
-is entered twice. If A pay on account of B, there is an entry, “A,
-creditor by B;” and another, “B, debtor to A.” This is what is called
-_double-entry_; and the consequence of it is, that the sum of all the
-debtor items in the whole book is equal to the sum of all the creditor
-items. For what is the first set but the second with the items in a
-different order? If it were convenient, one entry of each sum might
-be made a double-entry. The multiplication table is called a table of
-_double-entry_, because 42, for instance, though it occurs only once,
-appears in two different aspects, namely, as 6 times 7 and as 7 times
-6. Suppose, for example, that there are five accounts, A, B, C, D, E,
-and that each account has one transaction of its own with every other
-account; and let the debits be in the _columns_, the credits in the
-_rows_, as follows:
-
- -------------+------+------+------+------+------+
- Debtor | A | B | C | D | E |
- -------------+------+------+------+------+------+
- A, Creditor | | 23 | 19 | 32 | 4 |
- +------+------+------+------+------+
- B, Creditor | 17 | | 6 | 11 | 25 |
- +------+------+------+------+------+
- C, Creditor | 9 | 41 | | 10 | 2 |
- +------+------+------+------+------+
- D, Creditor | 14 | 28 | 16 | | 3 |
- +------+------+------+------+------+
- E, Creditor | 15 | 4 | 60 | 1 | |
- +------+------+------+------+------+
-
-Here the 16 is supposed to appear in D’s account as D creditor by C,
-and in C’s account as C debtor to D. And to say that the sum of debtor
-items is the same as that of creditor items, is merely to say that the
-preceding numbers give the same sum, whether the rows or the columns be
-first added up.
-
-If it be desired to close the ledger when it stands as above, the
-following is the way the accounts will stand: the lines in italics will
-presently be explained.
-
- A, Debtor. | A, Creditor.| B, Debtor. | B, Creditor.
- To B 17 | By B 23 | To A 23 | By A 17
- To C 9 | By C 19 | To C 41 | By C 6
- To D 14 | By D 32 | To D 28 | By D 11
- To E 15 | By E 4 | To E 4 | By E 25
- To Balance 23 | | | By Balance 37
- -- | -- | -- | --
- 78 | 78 | 96 | 96
- --------------+------------------+---------------+---------------+
- C, Debtor. | C, Creditor. | D, Debtor. | D, Creditor.
- To A 19 | By A 9 | To A 32 | By A 14
- To B 6 | By B 41 | To B 11 | By B 28
- To D 16 | By D 10 | To C 10 | By C 16
- To E 60 | By E 2 | To E 1 | By E 3
- | By Balance 39 | To Balance 7 |
- --- | --- | -- | --
- 101 | 101 | 61 | 61
- --------------+------------------+-----------------+---------------
- E, Debtor. | E, Creditor. | Balance, Debtor.| Balance, Cred.
- To A 4 | By A 15 | To B 37 | By A 23
- To B 25 | By B 4 | To C 39 | By D 7
- To C 2 | By C 60 | | By E 46
- | | -- | --
- To D 3 | By D 1 | 76 | 76
- To Balance 46 | | |
- -- | -- | |
- 80 | 80 | |
-
-In all the part of the above which is printed in Roman letters we see
-nothing but the preceding table repeated. But when all the accounts
-have been completed, and no more entries are left to be made, there
-remains the last process, which is termed _balancing the ledger_.
-To get an idea of this, suppose a new clerk, who goes round all the
-accounts, collecting debts and credits, and taking them all upon
-himself, that he alone may be entitled to claim the debts and to be
-responsible for the assets of the concern. To this new clerk, whom I
-will call the _balance-clerk_, every account gives up what it has,
-whether the same be debt or credit. The cash-clerk gives up all the
-cash; the clerks of the two kinds of bills give up all their documents,
-whether bills receivable or entries of bills payable (remember that
-any entry against which there is money set down in the books counts as
-money when given up, that is, as money due or money owing); the clerks
-of the several accounts of goods give up all their unsold remainders
-at cost prices; the clerks of the several personal accounts give up
-vouchers for the sums owing to or from the several parties; and so on.
-But where more has been paid out than received, the balance-clerk
-adjusts these accounts by giving instead of receiving; in fact, he so
-acts as to make the debtor and creditor sides of the accounts he visits
-equal in amount. For instance, the A account is indebted to the concern
-55, while payments or discharges to the amount of 78 have been made by
-it. The balance-clerk accordingly hands over 23 to that account, for
-which it becomes debtor, while the balance enters itself as creditor to
-the same amount. But in the B account there is 96 of receipt, and only
-59 of payment or discharge. The balance-clerk then receives 37 from
-this account, which is therefore credited by balance, while the balance
-acknowledges as much of debt. The balance account must, of course,
-exactly balance itself, if the accounts be all right; for of all the
-equal and opposite entries of which the ledger consists, so far as
-they do not balance one another, one goes into one side of the balance
-account, and the other into the other. Thus the balance account becomes
-a test of the accuracy of one part of the work: if its two sides do not
-give the same sums, either there have been entries which have not had
-their corresponding balancing entries correctly made, or else there has
-been error in the additions.
-
-But since the balance account must thus always give the _same sum_ on
-both sides, and since _balance debtor_ implies what is favourable to
-the concern, and _balance creditor_ what is unfavourable, does it not
-appear as if this system could only be applied to cases in which there
-is neither loss nor gain? This brings us to the two accounts in which
-are entered all that the concern _began with_, and all that it _gains
-or loses_--the _stock account_, and the _profit-and-loss account_.
-In order to make all that there was to begin with a matter of double
-entry, the opening of the ledger supposes the merchant himself to put
-his several clerks in charge of their several departments. In the stock
-account, _stock_, which here stands for the owner of the books, is made
-creditor by all the property, and debtor by all the liabilities; while
-the several accounts are made debtors for all they take from the stock,
-and creditors by all the responsibilities they undertake. Suppose, for
-instance, there are £500 in cash at the commencement of the ledger.
-There will then appear that the merchant has handed over to the
-cash-box £500, and in the stock account will appear, “Stock creditor
-by cash, £500;” while in the cash account will appear, “Cash debtor to
-stock, £500.” Suppose that at the beginning there is a debt outstanding
-of £50 to Smith and Co., then there will appear in the stock account,
-“Stock debtor to Smith and Co. £50,” and in Smith and Co.’s account
-will appear “Smith and Co. creditors by stock, £50.” Thus there is
-double entry for all that the concern begins with by this contrivance
-of the stock account.
-
-The account to which everything is placed for which an actual
-equivalent is not seen in the books is the _profit-and-loss_ account.
-This profit-and-loss account, or the clerk who keeps it, is made
-answerable for every loss, and the supposed cause of every gain. This
-account, then, becomes debtor for every loss, and creditor by every
-gain. If goods be damaged to the amount of £20 by accident, and a loss
-to that amount occur in their sale, say they cost £80 and sell for
-£60 cash, it is clear that there is an entry “Cash debtor to goods
-£60,” and “Goods creditor by cash £60.” Now, there is an entry of
-£80 somewhere to the debit of the goods for cash laid out, or bills
-given, for the whole of the goods. It would affect the accuracy of
-the accounts to take no notice of this; for when the balance-clerk
-comes to adjust this account, he would find he receives £20 less than
-he might have reckoned upon, without any explanation of the reason;
-and there would be a failure of the principle of double-entry. Since
-it is convenient that the balance account of the goods should merely
-represent the stock in hand at the close, the account of goods
-therefore lays the responsibility of £20 upon the profit-and-loss
-account, or there is the entry “Goods creditor by profit-and-loss,
-£20,” and also “Profit-and-loss debtor to goods, £20.” Again, in all
-payments which are not to bring in a specific return, such as house
-and trade expenses, wages, &c. these several accounts are supposed to
-adjust matters with the profit-and-loss account before the balance
-begins. Thus, suppose the outgoings from the mere premises occupied
-exceed anything those premises yield by £200, or the debits of the
-house account exceed its credits by £200, the account should be
-balanced by transferring the responsibility to the profit-and-loss
-account, under the entries “House expenses creditor by profit-and-loss,
-£200”, “Profit-and-loss debtor to house expenses, £200.” In this way
-the profit-and-loss account steps in from time to time before the
-balance account commences its operations, in order that that same
-balance account may consist of _nothing but the necessary matters of
-account for the next year’s ledger_.
-
-This _transference of accounts_, or transfusion of one account into
-another, requires attentive consideration. The receiving account
-becomes creditor for the credits, and debtor for the debits, of the
-transmitting account. The rule, therefore, is: Make the transmitting
-account balance itself, and, on whichever side it is necessary to enter
-a balancing sum, make the account debtor or creditor, as the case may
-be, to the receiving account, and the latter creditor or debtor to the
-former. Thus, suppose account A is to be transferred to account B, and
-the latter is to arrange with the balance account. If the two stand as
-in Roman letters, the processes in Italic letters will occur before the
-final close.
-
- A, Debtor. | A, Creditor. | B, Debtor. | B, Creditor.
- | | |
- To sundries £100|By sundries £500|To sundries £600|By sundries £400
- To B . . . 400| |To Balance 200|By A . . . 400
- ----| ----| ----| ----
- £500| £500| £800| £800
-
-And the entry in the balance account will be, “Creditor by B, £200,”
-shewing that, on these two accounts, the credits exceed the debits by
-£200.
-
-Still, before the balance account is made up, it is desirable that the
-profit-and-loss account should be transferred to the stock account;
-for the profit and loss of this year is of no moment as a part of
-next year’s ledger, except in so far as it affects the stock at the
-commencement of the latter. Let this be done, and the balance account
-may then be made in the form required.
-
-The stock account and the profit-and-loss account, the latter being
-the only direct channel of alteration for the former, differ in a
-peculiar manner[60] from the other preliminary accounts, and the
-balance account is a species of umpire. They represent the merchant:
-their interests are his interests; he is solvent upon the excess of
-their credits over their debits, insolvent upon the excess of their
-debits over their credits. It is exactly the reverse in all the other
-accounts. If a malicious person were to get at the ledger, and put on
-a cipher to the pounds in various items, with a view of making the
-concern appear worse than it really is, he would make his alterations
-on the _debtor_ sides of the stock and profit-and-loss accounts, and
-on the _creditor_ sides of all the others. Accordingly, in the balance
-account, the net stock, after the incorporation of the profit-and-loss
-account, appears on the _creditor_ side (if not, it should be called
-amount of _insolvency_, not _stock_), and the debts of the concern
-appear on the same side. But on the debit side of the balance account
-appear all the assets of the concern (for which the balance-clerk is
-debtor to the clerks from whom he has taken them).
-
-[60] The treatises on book-keeping have described this difference in as
-peculiar a manner. They call these accounts the _fictitious accounts_.
-Now they represent the merchant himself; their credits are gain to the
-business, their debits losses or liabilities. If the terms real and
-fictitious are to be used at all, they are the _real_ accounts, end all
-the others are as _fictitious_ as the clerks whom we have supposed to
-keep them.
-
-The young student must endeavour to get the enlarged view of the words
-debtor and creditor which is requisite, and must then learn by practice
-(for nothing else will give it) facility in allotting the actual
-entries in the waste-book to the proper sides of the proper accounts.
-I do not here pretend to give more than such a view of the subject as
-may assist him in studying a treatise on book-keeping, which he will
-probably find to contain little more than examples.
-
-
-
-
-APPENDIX VIII.
-
-ON THE REDUCTION OF FRACTIONS TO OTHERS OF NEARLY EQUAL VALUE.
-
-
-There is a useful method of finding fractions which shall be nearly
-equal to a given fraction, and with which the computer ought to be
-acquainted. Proceed as in the rule for finding the greatest common
-measure of the numerator and denominator, and bring all the quotients
-into a line. Then write down,
-
- 1 2nd Quot.
- -------- ------------------------
- 1st Quot. 1st Quot. × 2d Quot. + 1
-
-Then take the third quotient, multiply the numerator and denominator of
-the second by it, and add to the products the preceding numerator and
-denominator. Form a third fraction with the results for a numerator and
-denominator. Then take the fourth quotient, and proceed with the third
-and second fractions in the same way; and so on till the quotients are
-exhausted. For example, let the fraction be ⁹¹³¹/₁₃₁₂₈.
-
- 9131)13128(1, 2
- 1137 3997(3, 1
- 551 586(1, 15
- 201 35(1, 2
- 26 9(1, 8
- 8 1
-
-This is the process for finding the greatest common measure of 9131 and
-13128 in its most compact form, and the quotients and fractions are:
-
- 1 2 3 1 1 15 1 2 1 8
-
- 1 2 7 9 16 249 265 779 1044 9131
- --- --- --- --- ---- ----- ----- ----- ------ ------
- 1 3 10 13 23 358 381 1120 1501 13128
-
-It will be seen that we have thus a set of fractions ending with the
-original fraction itself, and formed by the above rule, as follows:
-
- 1 1
- 1st Fraction = -------- = ---
- 1st Quot. 1
-
- 2d Quot. 2
- 2d Fraction = ------------------------ = ---
- 1st Quot. × 2d Quot. + 1 3
-
- 2d Numʳ. × 3d Quot. + 1st Numʳ. 2 × 3 + 1 7
- 3d Fraction = ------------------------------- = --------- = ---
- 2d Denʳ. × 3d Quot. + 1st Denʳ. 3 × 3 + 1 10
-
- 3d Numʳ. × 4th Quot. + 2d Numʳ. 7 × 1 + 2 9
- 4th Fraction = ------------------------------- = --------- = ---;
- 3d Denʳ. × 4th Quot. + 2d Denʳ. 10 × 1 + 3 13
-and so on. But we have done something more than merely reascend to the
-original fraction by means of the quotients. The set of fractions,
-¹/₁, ²/₃, ⁷/₁₀, ⁹/₁₃, &c. are continually approaching in value to the
-original fraction, the first being too great, the second too small, the
-third too great, and so on alternately, but each one being nearer to
-the given fraction than any of those before it. Thus, ¹/₁ is too great,
-and ²/₃ is too small; but ²/₃ is not so much too small as ¹/₁ is too
-great. And again, ⁷/₁₀, though too great, is not so much too great as
-²/₃ is too small.
-
-Moreover, the difference of any of the fractions from the original
-fraction is never greater than a fraction having unity for its
-numerator and the product of the denominator and the next denominator
-for its denominator. Thus, ¹/₁ does not err by so much as ¹/₃, nor ²/₃
-by so much as ¹/₃₀, nor ⁷/₁₀ by so much as ¹/₁₃₀, nor ⁹/₁₃ by so much
-as ¹/₂₉₉, &c.
-
-Lastly, no fraction of a less numerator and denominator can come
-so near to the given fraction as any one of the fractions in the
-list. Thus, no fraction with a less numerator than 249, and a less
-denominator than 358, can come so near to
-
- 9131 249
- ----- as ---.
- 13128 358
-
-The reader may take any example for himself, and the test of the
-accuracy of the process is the ultimate return to the fraction begun
-with. Another test is as follows: The numerator of the difference of
-any two consecutive approximating fractions ought to be unity. Thus,
-in our instance, we have ¹⁶/₂₃ and ²⁴⁹/₃₅₈, which, with a common
-denominator, 23 × 358, have 5728 and 5727 for their numerators.
-
-As another example, let us examine this question: The length of the
-year is 365·24224 days, which is called in common life 365¼ days. Take
-the fraction ²⁴²²⁴/₁₀₀₀₀₀, and proceed as in the rule.
-
- 24224)100000(4, 7, 1, 4, 9, 2
- 2496 3104
- 64 608
- 0 32
-
- 1 7 8 39 359 757
- --- --- --- ---- ---- ----
- 4 29 33 161 1482 3125
-
-and ⁷⁵⁷/₃₁₂₅ is ·24224 in its lowest terms. Hence, it appears that the
-excess of the year over 365 days amounts to about 1 day in 4 years,
-which is not wrong by so much as 1 day in 116 years; more accurately,
-to 7 days in 29 years, which is not wrong by so much as 1 day in 957
-years; more accurately still, to 8 days in 33 years, which is not wrong
-by so much as 1 day in 5313 years; and so on.
-
-This method may be applied to finding fractions nearly equal to the
-square roots of integers, in the following manner:
-
- __
- √43 = 6 + ...
-
- 6 | 1 5 4 5 5 4 5 1 6 6 |1 5 4, &c.
- 1 | 7 6 3 9 2 9 3 6 7 1 |7 6 3, &c.
- --+----------------------+------
- 6 | 1 1 3 1 5 1 3 1 1 1 2|1 1 3, &c.
-
-Set down the number whose square root is wanted, say 43. This square
-root is 6 and a fraction. Set down the integer 6 in the first and third
-row, and 1 in the second row always. Form the successive rows each from
-the one before, in the following manner:
-
- One row The next row has _b′_, _a′_, _c′_, formed in this order,
- being thus,
- _a_ _a′_ = excess of _b′c′_, already formed, over _a_.
- _b_ _b′_ = quotient of 43 - _a_² divided by _b_.
- _c_ _c′_ = integer in the quotient of 6 + _a_ divided by _b′_.
-
-Thus the second row is formed from the first, as under:
-
- 6|1 = excess of 7 × 1 (both just found) over 6.
- 1|7 = 43 - 6 × 6 divided by 1.
- --+--
- 6|1 = integer of 6 + 6 divided by 7 (just found).
-
-The third row is formed from the second, thus:
-
- 1 5 = excess of 1 × 6 over 1.
- 7 6 = 43 - 1 × 1 divided by 7.
- 1 1 = integer of 6 + 1 divided by 6;
-
-and so on. In process of time the second column, 1, 7, 1, occurs again,
-after which the several columns are repeated in the same order. As a
-final process, take the set in the lowest line (excluding the first,
-6), namely, 1, 1, 3, 1, 5, 1, 3, &c. and use them by the rule given at
-the beginning of this article, as follows:
-
- 1 1 3 1 5 1 3 1 1, &c.
-
- 1 1 4 5 29 34 131 165 296
- --- --- --- --- ---- ---- ---- ---- ----
- 1 2 7 9 52 61 235 296 531
-Hence, 6¹⁶⁵/₂₉₆ is very near the square root of 43, not erring by so
-much as
-
- 1
- ---------.
- 296 × 531
-
-If we try it, we shall find (⁶¹⁶⁵/₂₉₆) to be ¹⁹⁴¹/₂₉₆, the square of
-which is ³⁷⁶⁷⁴⁸¹/₈₇₆₁₆, or 43⁷/₈₇₆₁₆.
-
-This rule is of use when it is frequently wanted to use one square
-root, and therefore desirable to ascertain whether any easy
-approximation exists by means of a common fraction. For example, √2 is
-often used.
-
- _
- √2 = 1 + ...
- 1|1 1
- 1|1 1
- 1|2 2 2 2 2 2
- 1 2 5 12 29 70
- --- --- --- --- --- ---, &c.
- 2 5 12 29 70 169
-
-Here it appears that
-
- 29 1 99 100 - 1
- 1---- does not err by --------; consequently, ---- or ------- is,
- 70 70 × 169 70 70
-
-considering the ease of the operation, a fair approximation. In fact,
-⁹⁹/₇₀ is 1·4142857 ... the truth being 1·4142135 ...
-
-The following is an additional example:
-
- __
- √19 = 4 + ...
- 4 | 2 3 3 2 4 4 2
- 1 | 3 5 2 5 3 1 3
- 4 | 2 1 3 1 2 8 2 1 3 1 2, &c.
-
- 1 1 4 5 14
- --- --- --- --- ---, &c.
- 2 3 11 14 39
-
-
-
-
-APPENDIX IX.
-
-ON SOME GENERAL PROPERTIES OF NUMBERS.
-
-
-PROP. 1. If a fraction be reduced to its lowest terms, _so called_,[61]
-that is, if neither, numerator nor denominator be divisible by any
-integer greater than unity, then no fraction of a smaller numerator and
-denominator can have the same value.
-
-[61] This theorem shews that what is _called_ reducing a fraction to
-its lowest terms (namely, dividing numerator and denominator by their
-greatest common measure), is correctly so called.
-
-Let _a_/_b_ be a fraction in which _a_ and _b_ have no common measure
-greater than unity: and, if possible, let _c_/_d_ be a fraction of the
-same value, _c_ being less than _a_, and _d_ less than _b_. Now, since
-
- _a_ _c_ _a_ _b_
- --- = ---, we have --- = ---;
- _b_ _d_ _c_ _d_
-let _m_ be the integer quotient of these last fractions (which must
-exist, since _a_ > _c_, _b_ > _d_), and let _e_ and _f_ be the
-remainders. Then
-
- _a_ _mc_ + _e_ _c_ _mc_
- --- or ---------- = --- = ----
- _b_ _md_ + _f_ _d_ _md_
-
-Hence,
-
- _e_ _mc_
- --- and ---- must be equal, for if not,
- _f_ _md_
-
- _mc_ + _e_ _mc_ _e_
- ---------- would lie between ---- and ---,
- _md_ + _f_ _md_ _f_
-
-instead of being equal to the former. Hence,
-
- _a_ _e_
- --- = ---;
- _b_ _f_
-
-so that if a fraction whose numerator and denominator have no common
-measure greater than unity, be equal to a fraction of lower numerator
-and denominator, it is equal to another in which the numerator and
-denominator are still lower. If we proceed with
-
- _a_ _e_
- --- = --- in a similar manner, we find
- _b_ _f_
-
- _a_ _g_
- --- = --- where _g_ < _e_, _h_ < _f_,
- _b_ _h_
-
-and so on. Now, if there be any process which perpetually diminishes
-the terms of a fraction by one or more units at every step, it must at
-last bring either the numerator or denominator, or both, to 0. Let
-
- _a_ _v_
- --- = ---
- _b_ _w_
-
-be one of the steps, and let _a_ = _kv_ + _x_, _b_ = _kw_ + _y_; so that
-
- _kv_ + _x_ _v_
- ---------- = ---.
- _kw_ + _y_ _w_
-
-Now, if _x_ = 0 but not _y_, this is absurd, for it gives
-
- _kv_ _kv_
- ---------- = ----.
- _kw_ + _y_ _kw_
-
-A similar absurdity follows if _y_ be 0, but not _x_; and if both _x_
-and _y_ be = 0, then _a_ = _kv_, _b_ = _kw_, or _a_ and _b_ have a
-common measure, _k_. Now _k_ must be greater than 1, for _v_ and _w_
-are less than _c_ and _d_, which by hypothesis are less than _a_ and
-_b_. Consequently _a_ and _b_ have a common measure _k_ greater than 1,
-which by hypothesis they have not. If, then, _a_ and _b_ be integers
-not divisible by any integer greater than 1, the fraction _a_/_b_ is
-really _in its lowest terms_. Also _a_ and _b_ are said to be _prime to
-one another_.
-
-PROP. 2. If the product _ab_ be divisible by _c_, and if _c_ be prime
-to _b_, it must divide _a_. Let
-
- _ab_ _b_ _d_
- ---- = _d_, then --- = ---.
- _c_ _c_ _c_
-
-Now _b_/_c_ is in its lowest terms; therefore, by the last proposition,
-_d_ and _a_ must have a common measure. Let the greatest common measure
-be _k_, and let _a_ = _kl_, _d_ = _km_. Then
-
- _b_ _km_ _m_ _m_
- --- = ---- = ---, and ---
- _c_ _kl_ _l_ _l_
-
-is also in its lowest terms; but so is _b_/_c_; therefore we must have
-_m_ = _b_, _l_ = _c_, for otherwise a fraction in its lowest terms
-would be equal to another of lower terms. Therefore _a_ = _kc_, or _a_
-is divisible by _c_. And from this it follows, that if a number be
-prime to two others, it is prime to their product. Let _a_ be prime to
-_b_ and _c_, then no measure of _a_ can measure either _b_ or _c_, and
-no such measure can measure the product _bc_; for any measure of _bc_
-which is prime to one must measure the other.
-
-PROP. 3. If _a_ be prime to _b_, it is prime to all the powers of _b_.
-Every measure[62] of _a_ is prime to _b_, and therefore does not divide
-_b_. Hence, by the last, no measure of _a_ divides _b_²; hence, _a_ is
-prime to _b_², and so is every measure of it; therefore, no measure of
-_a_ divides _bb_², consequently _a_ is prime to _b_³, and so on.
-
-Hence, if _a_ be prime to _b_, _a_ cannot divide without remainder
-any power of _b_. This is the reason why no fraction can be made into
-a decimal unless its denominator be measured by no prime[63] numbers
-except 2 and 5. For if
-
- _a_ _c_
- --- = ---,
- _b_ 10ⁿ
-
-which last is the general form of a decimal fraction, let
-
- _a_ 10ⁿ_a_
- --- be in its lowest terms; then ------
- _b_ _b_
-
-is an integer, whence (Prop. 2) _b_ must divide 10ⁿ, and so must all
-the divisors of _b_. If, then, among the divisors of _b_ there be any
-prime numbers except 2 and 5, we have a prime number (which is of
-course a number prime to 10) not dividing 10, but dividing one of its
-powers, which is absurd.
-
-[62] For that which measures a measure is itself a measure; so that if
-a measure of _a_ could have a measure in common with _b_, _a_ itself
-would have a common measure with _b_.
-
-[63] A prime number is one which is prime to all numbers except its own
-multiples, or has no divisors except 1 and itself.
-
-PROP. 4. If _b_ be prime to _a_, all the multiples of _b_, as _b_,
-2_b_, ... up to (_a_-1)_b_ must leave different remainders when divided
-by _a_. For if, _m_ being greater than _n_, and both less than _a_,
-we have _mb_ and _nb_ giving the same remainder, it follows that
-_mb_-_nb_, or (_m_-_n_)_b_, is divisible by _a_; whence (Prop. 2), a
-divides _m_-_n_, a number less than itself, which is absurd.
-
- * * * * *
-
-If a number be divided into its prime factors, or reduced to a product
-of prime numbers only (as in 360 = 2 × 2 × 2 × 3 × 3 × 5), and if
-_a_, _b_, _c_, &c. be the prime factors, and α, β, γ, &c. the number
-of times they severally enter, so that the number is _a_{^α} × _b_ᵝ ×
-_c_ᵞ × &c., then this can be done in only one way: For any prime number
-_v_, not included in the above list, is prime to _a_, and therefore
-to _a_{^α}, to _b_ and therefore to _b_ᵝ and therefore to _a_{^α} ×
-_b_ᵝ Proceeding in this way, we prove that _v_ is prime to the complete
-product above, or to the given number itself.
-
-The number of divisors which the preceding number _a_{^α}_b_ᵝ_c_ᵞ
-... can have, 0 and itself included, is (α + 1)(β+ 1)(γ + 1).... For
-_a_{^α} as the divisors 1, _a_, _a_² ... _a_{^α} and no others, α + 1
-in all. Similarly, _b_ᵝ has β+ 1 divisors, and so on. Now as all the
-divisors are made by multiplying together one out of each set, their
-number (page 202) is (α + 1)(β + 1)(γ+ 1)....
-
-If a number, _n_, be divisible by certain prime numbers, say 3, 5, 7,
-11, then the third part of all the numbers up to _n_ is divisible by 3,
-the fifth part by 5, and so on. But more than this: when the multiples
-of 3 are omitted, exactly the fifth part of _those which remain_ are
-divisible by 5; for the fifth part of the whole are divisible by 5,
-and the fifth part of those which are removed are divisible by 5,
-therefore the fifth part of those which are left are divisible by 5.
-Again, because the seventh part of the whole are divisible by 7, and
-the seventh part of those which are divisible by 3, or by 5, or by 15,
-it follows that when all those which are multiples of 3 or 5, or both,
-are removed, the seventh part of those which remain are divisible by
-7; and so on. Hence, the number of numbers not exceeding n, which are
-not divisible by 3, 5, 7, or 11, is ¹⁰/₁₁ of ⁶/₇ of ⁴/₅ of ²/₃ of n.
-Proceeding in this way, we find that the number of numbers which are
-prime to _n_, that is, which are not divisible by any one of its prime
-factors, _a_, _b_, _c_, ... is
-
- _a_ - 1 _b_ - 1 _c_ - 1
- _n_ ------- ------- ------- ...
- _a_ _b_ _c_
-
- or _a_{^α-1} - 1}_b_ᵝ⁻¹_c_ᵞ⁻¹ ... (_a_ - 1)(_b_ - 1)(_c_ - 1)....
-
-Thus, 360 being 2³3²5, its number of divisors is 4 × 3 × 2, or 24, and
-there are 2³3.1.2.4 or 96 numbers less than 360 which are prime to it.
-
-PROP. 5. If _a_ be prime to _b_, then the terms of the series, _a_,
-_a_², _a_³, ... severally divided by _b_, must all leave different
-remainders, until 1 occurs as a remainder, after which the cycle of
-remainders will be again repeated.
-
-Let _a_ + _b_ give the remainder _r_ (not unity); then _a_² ÷ _b_ gives
-the same remainder as _r__a_ + _b_, which (Prop. 4) cannot be _r_: let
-it be _s_. Then _a_ˢ ÷ _b_ gives the same remainder as _s__a_ ÷ _b_,
-which (Prop. 4) cannot be either _r_ or _s_, unless _s_ be 1: let it be
-_t_. Then _a_ᵗ ÷ _b_ gives the same remainder as _ta_ ÷ _b_; if _t_ be
-not 1, this cannot be either _r_, _s_, or _t_: let it be _u_. So we go
-on getting different remainders, until 1 occurs as a remainder; after
-which, at the next step, the remainder of _a_ ÷ _b_ is repeated. Now, 1
-must come at last; for division by _b_ cannot give any remainders but
-0, 1, 2, ... _b_- 1; and 0 never arrives (Prop. 3), so that as soon as
-_b_-2 _different_ remainders have occurred, no one of which is unity,
-the next, which must be different from all that precede, must be 1. If
-not before, then at _a_ᵇ⁻¹ we must have a remainder 1; after which the
-cycle will obviously be repeated.
-
-Thus, 7, 7², 7³, 7⁴, &c. will, when divided by 5, be found to give the
-remainders 2, 4, 3, 1, &c.
-
-PROP. 6. The difference of two _m_th powers is always divisible without
-remainder by the difference of the roots; or _a_ᵐ -_b_ᵐ is divisible by
-_a_-_b_; for
-
- _a_ᵐ - _b_ᵐ = _a_ᵐ - _a_ᵐ⁻¹_b_ + _a_ᵐ⁻¹_b_ - _b_ᵐ
-
- = _a_ᵐ⁻¹(_a_ - _b_) + _b_(_a_ᵐ⁻¹ - _b_ᵐ⁻¹)
-
-From which, if _aᵐ⁻¹_-_bᵐ⁻¹_ is divisible by _a_ -_b_, so is _a_ᵐ-_b_ᵐ.
-But _a_-_b_ is divisible by _a_-_b_; so therefore is _a_²- _b_²; so
-therefore is _a_³-_b_³; and so on.
-
-Therefore, if _a_ and _b_, divided by _c_, leave the same remainder,
-_a_² and _b_², _a_³ and _b_³, &c. severally divided by _c_, leave the
-same remainders; for this means that _a_-_b_ is divisible by _c_. But
-_a_ᵐ - _b_ᵐ is divisible by _a_-_b_, and therefore by every measure of
-_a_-_b_, or by _c_; but _a_ᵐ-_b_ᵐ cannot be divisible by _c_, unless
-_a_ᵐ and _b_ᵐ, severally divided by _c_, give the same remainder.
-
-PROP. 7. If _b_ be a prime number, and _a_ be not divisible by _b_,
-then _a_ᵇ and (_a_-1)ᵇ + 1 leave the same remainder when divided by
-_b_. This proposition cannot be proved here, as it requires a little
-more of algebra than the reader of this work possesses.[64]
-
-[64] Expand (_a_-1)ᵇ by the binomial theorem; shew that _when b is a
-prime number_ every coefficient which is not unity is divisible by _b_;
-and the proposition follows.
-
-PROP. 8. In the last case, _a_ᵇ⁻¹ divided by _b_ leaves a remainder
-1. From the last, _a_ᵇ-_a_ leaves the same remainder as (_a_-1)ᵇ +
-1-_a_ or (_a_-1)ᵇ- (_a_-1); that is, the remainder of _a_ᵇ-_a_ is
-not altered if _a_ be reduced by a unit. By the same rule, it may be
-reduced another unit, and so on, still without any alteration of the
-remainder. At last it becomes 1ᵇ-1, or 0, the remainder of which is 0.
-Accordingly, _a_ᵇ-_a_, which is _a_(_a_ᵇ⁻¹- 1), is divisible by _b_;
-and since _b_ is prime to _a_, it must (Prop. 2) divide _a_ᵇ⁻¹-1; that
-is, _a_ᵇ⁻¹, divided by _b_, leaves a remainder 1, if _b_ be a prime
-number and _a_ be not divisible by _b_.
-
-From the above it appears (Prop. 5 and 7), that if _a_ be prime to
-_b_, the set 1, _a_, _a_², _a_³, &c. successively divided by _b_, give
-a set of remainders beginning with 1, and in which 1 occurs again at
-_a_ᵇ⁻¹, if not before, and at _a_ᵇ⁻¹ certainly (whether before or not),
-if _b_ be a prime number. From the point at which 1 occurs, the cycle
-of remainders recommences, and 1 is always the beginning of a cycle.
-If, then, _a_ᵐ be the first power which gives 1 for remainder, _m_ must
-either be _b_-1, or a measure of it, _when b is a prime number_.
-
-But if we divide the terms of the series _m_, _ma_, _ma_², _ma_³, &c.
-by _b_, _m_ being less than _b_, we have cycles of remainders beginning
-with _m_. If 1, _r_, _s_, _t_, &c. be the first set of remainders, then
-the second set is the set of remainders arising from _m_, _mr_, _ms_,
-_mt_, &c. If 1 never occur in the first set before _a_ᵇ⁻¹ (except at
-the beginning), then all the numbers under _b_-1 inclusive are found
-among the set 1, _r_, _s_, _t_, &c.; and if _m_ be prime to _b_ (Prop.
-4), all the same numbers are found, in a different order, among the
-remainders of _m_, _mr_, &c. But should it happen that the set 1, _r_,
-_s_, _t_, &c. is not complete, then _m_, _mr_, _ms_, &c. may give a
-different set of remainders.
-
-All these last theorems are constantly verified in the process for
-reducing a fraction to a decimal fraction. If _m_ be prime to _b_, or
-the fraction _m_/_b_ in its lowest terms, the process involves the
-successive division of _m_, _m_ × 10, _m_ × 10², &c. by _b_. This
-process can never come to an end unless some power of 10, say 10ⁿ, is
-divisible by _b_; which cannot be, if _b_ contain any prime factors
-except 2 and 5. In every other case the quotient repeats itself, the
-repeating part sometimes commencing from the first figure, sometimes
-from a later figure. Thus, ¹/₇ yields ·142857142857, &c., but ¹/₁₄
-gives ·07(142857)(142857), &c., and ¹/₂₈ gives ·03(571428)(571428), &c.
-
-In _m_/_b_, the quotient always repeats from the very beginning
-whenever _b_ is a prime number and _m_ is less than _b_; and the number
-of figures in the repeating part is then always _b_-1, or a measure of
-it. That it must be so, appears from the above propositions.
-
-Before proceeding farther, we write down the repeating part of a
-quotient, with the remainders which are left after the several figures
-are formed. Let the fraction be ¹/₁₇, we have
-
- 0₁₀5₁₅8₁₄8₄2₆3₉5₅2₁₆9₇4₂1₃1₁₃7₁₁6₈4₁₂7₁
-
-This may be read thus: 10 by 17, quotient 0, remainder 10; 10² by 17,
-quotient 05, remainder 15; 10³ by 17, quotient 058, remainder 14; and
-so on. It thus appears that 10¹⁶ by 17 leaves a remainder 1, which is
-according to the theorem.
-
-If we multiply 0588, &c. by _any number under_ 17, the same cycle is
-obtained with a different beginning. Thus, if we multiply by 13, we have
-
- 7647058823529411
-
-beginning with what comes after remainder 13 in the first number. If
-we multiply by 7, we have 4117, &c. The reason is obvious: ¹/₁₇ × 13,
-or ¹³/₁₇, when turned into a decimal fraction, starts with the divisor
-130, and we proceed just as we do in forming ¹/₁₇, when within four
-figures of the close of the cycle.
-
-It will also be seen, that in the last half of the cycle the quotient
-figures are complements to 9 of those in the first half, and that
-the remainders are complements to 17. Thus, in 0₁₀5₁₅8₁₄8₄, &c. and
-9₇4₂1₃1₁₃, &c. we see 0 + 9 = 9, 5 + 4 = 9, 8 + 1 = 9, &c., and 10 + 7
-= 17, 15 + 2 = 17, 14 + 3 = 17, &c. We may shew the necessity of this
-as follows: If the remainder 1 never occur till we come to use _a_ᵇ⁻¹,
-then, _b_ being prime, _b_-1 is even; let it be 2_k_. Accordingly,
-_a_²ᵏ-1 is divisible by _b_; but this is the product of _a_ᵏ-1 and _a_ᵏ
-+ 1, one of which must be divisible by _b_. It cannot be _a_ᵏ-1, for
-then a power of _a_ preceding the (_b_-1)th would leave remainder 1,
-which is not the case in our instance: it must then be _a_ᵏ + 1, so
-that _a_ᵏ divided by _b_ leaves a remainder _b_-1; and the _k_th step
-concludes the first half of the process. Accordingly, in our instance,
-we see, _b_ being 17 and _a_ being 10, that remainder 16 occurs at
-the 8th step of the process. At the next step, the remainder is that
-yielded by 10(_b_-1), or 9_b_ + _b_-10, which gives the remainder
-_b_-10. But the first remainder of all was 10, and 10 + (_b_-10) =
-_b_. If ever this complemental character occur in any step, it must
-continue, which we shew as follows: Let _r_ be a remainder, and _b_-_r_
-a subsequent remainder, the sum being _b_. At the next step after the
-first remainder, we divide 10_r_ by _b_, and, at the next step after
-the second remainder, we divide 10_b_-10_r_ by _b_. Now, since the sum
-of 10_r_ and 10_b_-10_r_ is divisible by _b_, the two remainders from
-these new steps must be such as added together will give _b_, and so
-on; and the _quotients_ added together must give 9, for the sum of the
-remainders 10_r_ and 10_b_-10_r_ yields a quotient 10, of which the two
-remainders give 1.
-
-If ¹/₅₉ and ¹/₆₁ be taken, the repeating parts will be found to contain
-58 and 60 figures. Of these we write down only the first halves, as the
-reader may supply the rest by the complemental property just given.
-
- 01694915254237288135593220338, &c.
-
- 016393442622950819672131147540, &c.
-
-Here, then, are two numbers, the first of which multiplied by any
-number under 59, and the second by any number under 61, can have the
-products formed by carrying certain of the figures from one end to the
-other.
-
-But, _b_ being still prime, it may happen that remainder 1 may occur
-before _b_-1 figures are obtained; in which case, as shewn, the
-number of figures must be a measure of _b_-1. For example, take ¹/₄₁.
-The repeating quotient, written as above, has only 5 figures, and 5
-measures 41-1.
-
- 0₁₀2₁₈4₁₆3₃₇9₁
-
-Now, this period, it will be found, has its figures merely transposed,
-if we multiply by 10, 18, 16, or 37. But if we multiply by any other
-number under 41, we convert this period into the period of another
-fraction whose denominator is 41. The following are 8 periods which may
-be found.
-
- 0₁₀2₁₈4₁₆3₃₇9₁ | 1₉2₈1₃₉9₂₁5₅
- 0₂₀4₃₆8₃₂7₃₃8₂ | 1₁₉4₂₆6₁₄3₁₇4₆
- 0₃₀7₁₃3₇1₂₉7₃ | 2₂₈6₃₄8₁₂2₃₈9₁₁
- 0₄₀9₈₁7₂₃5₂₅6₄ | 3₂₇6₂₄5₃₅8₂₂5₁₅
-
-To find _m_/41, look out for _m_ among the remainders, and take the
-period in which it is, beginning after the remainder. Thus, ³⁴/₄₁ is
-·8292682926, &c., and ¹⁵/₄₁ is ·3658536585, &c. These periods are
-complemental, four and four, as 02439 and 97560, 07317 and 92682, &c.
-And if the first number, 02439, be multiplied by any number under 41,
-look for that number among the remainders, and the product is found in
-the period of that remainder by beginning after the remainder. Thus,
-02439 multiplied by 23 gives 56097, and by 6 gives 14634.
-
-The reader may try to decipher for himself how it is that, with no more
-figures than the following, we can extend the result of our division.
-The fraction of which the period is to be found is ¹/₈₇.
-
- 87)100(01149425
- 130
- 430
- 820 01149425 × 25
- 370 28735625 × 25
- 220 718390625 × 25
- 460 17959765625 × 25
- 25 448994140625
- 0114942528735625
- 718390625
- 1795976 5625
- 448994
- ----------------------------+------
- 0114942528735632183908045977|011494
- |
-
-
-
-
-APPENDIX X.
-
-ON COMBINATIONS.
-
-
-There are some things connected with combinations which I place in an
-appendix, because I intend to demonstrate them more briefly than the
-matters in the text.
-
-Suppose a number of boxes, say 4, in each of which there are counters,
-say 5, 7, 3, and 11 severally. In how many ways can one counter be
-taken out of each box, the order of going to the boxes not being
-regarded. _Answer_, in 5 × 7 × 3 × 11 ways. For out of the first box we
-may draw a counter in 5 different ways, and to each such drawing we may
-annex a drawing from the second in 7 different ways--giving 5 × 7 ways
-of making a drawing from the first two. To each of these we may annex
-a drawing from the third box in 3 ways--giving 5 × 7 × 3 drawings from
-the first three; and so on. The following statements may now be easily
-demonstrated, and similar ones made as to other cases.
-
-If the order of going to the boxes make a difference, and if _a_, _b_,
-_c_, _d_ be the numbers of counters in the several boxes, there are
-4 × 2 × 3 × 1 × _a_ × _b_ × _c_ × _d_ distinct ways. If we want to
-draw, say 2 out of the first box, 3 out of the second, 1 out of the
-third, and 3 out of the fourth, and if the order of the boxes be not
-considered, the number of ways is
-
- _a_ - 1 _b_ - 1 _b_ - 2 _d_ - 1 _d_ - 2
- _a_------- × _b_------- -------- × _c_ × _d_------- -------
- 2 2 3 2 3
-
-If the order of going to the boxes be considered, we must multiply the
-preceding by 4 × 3 × 2 × 1. If the order of the drawings out of the
-boxes makes a difference, but not the order of the boxes, then the
-number of ways is
-
- _a_(_a_-1)_b_(_b_-1)(_b_-2)_cd_(_d_-1)(_d_-2)
-
-The nth power of _a_, or _a_ⁿ, represents the number of ways in which
-_a_ counters _differently marked_ can be distributed in _n_ boxes,
-order of placing them in each box not being considered. Suppose we want
-to distribute 4 differently-marked counters among 7 boxes. The first
-counter may go into either box, which gives 7 ways; the second counter
-may go into either; and any of the first 7 allotments may be combined
-with any one of the second 7, giving 7 × 7 distinct ways; the third
-counter varies each of these in 7 different ways, giving 7 × 7 × 7 in
-all; and so on. But if the counters be undistinguishable, the problem
-is a very different thing.
-
-Required the number of ways in which a number can be compounded of
-other numbers, different orders counting as different ways. Thus, 1 +
-3 + 1 and 1 + 1 + 3 are to be considered as distinct ways of making 5.
-It will be obvious, on a little examination, that each number can be
-composed in exactly twice as many ways as the preceding number. Take
-8 for instance. If every possible way of making 7 be written down, 8
-may be made either by increasing the last component by a unit, or by
-annexing a unit at the end. Thus, 1 + 3 + 2 + 1 may yield 1 + 3 + 2
-+ 2, or 1 + 3 + 2 + 1 + 1: and all the ways of making 8 will thus be
-obtained; for any way of making 8, say _a_ + _b_ + _c_ + _d_, must
-proceed from the following mode of making 7, _a_ + _b_ + _c_ + (_d_-1).
-Now, (_d_-1) is either 0--that is, _d_ is unity and is struck out--or
-(_d_-1) remains, a number 1 less than _d_. Hence it follows that the
-number of ways of making _n_ is 2ⁿ⁻¹. For there is obviously 1 way of
-making 1, 2 of making 2; then there must be, by our rule, 2² ways of
-making 3, 2³ ways of making 4; and so on.
-
- { 1 + 1 + 1 { 1 + 1 + 1 + 1
- { 1 + 1 { { 1 + 1 + 2
- { { 1 + 2 { 1 + 2 + 1
- 1 { { 1 + 3
- { { 2 + 1 { 2 + 1 + 1
- { 2 { { 2 + 2
- { 3 { 3 + 1
- { 4
-
-This table exhibits the ways of making 1, 2, 3, and 4. Hence it follows
-(which I leave the reader to investigate) that there are twice as many
-ways of forming _a_ + _b_ as there are of forming _a_ and then annexing
-to it a formation of _b_; four times as many ways of forming _a_ + _b_
-+ _c_ as there are of annexing to a formation of _a_ formations of _b_
-and of _c_; and so on. Also, in summing numbers which make up _a_ +
-_b_, there are ways in which _a_ is a rest, and ways in which it is
-not, and as many of one as of the other.
-
-Required the number of ways in which a number can be compounded of odd
-numbers, different orders counting as different ways. If _a_ be the
-number of ways in which _n_ can be so made, and _b_ the number of ways
-in which _n_ + 1 can be made, then _a_ + _b_ must be the number of ways
-in which _n_ + 2 can be made; for every way of making 12 out of odd
-numbers is either a way of making 10 with the last number increased by
-2, or a way of making 11 with a 1 annexed. Thus, 1 + 5 + 3 + 3 gives
-12, formed from 1 + 5 + 3 + 1 giving 10. But 1 + 9 + 1 + 1 is formed
-from 1 + 9 + 1 giving 11. Consequently, the number of ways of forming
-12 is the sum of the number of ways of forming 10 and of forming 11.
-Now, 1 can only be formed in 1 way, and 2 can only be formed in 1 way;
-hence 3 can only be formed in 1 + 1 or 2 ways, 4 in only 1 + 2 or 3
-ways. If we take the series 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, &c.
-in which each number is the sum of the two preceding, then the _n_th
-number of this set is the number of ways (orders counting) in which _n_
-can be formed of odd numbers. Thus, 10 can be formed in 55 ways, 11 in
-89 ways, &c.
-
-Shew that the number of ways in which _mk_ can be made of numbers
-divisible by _m_ (orders counting) is 2ᵏ⁻¹.
-
- In the two series, 1 1 1 2 3 4 6 9 13 19 28, &c.
- 0 1 0 1 1 1 2 2 3 4 5, &c.,
-
-the first has each new term after the third equal to the sum of the
-last and last but two; the second has each new term after the third
-equal to the sum of the last but one and last but two. Shew that the
-_n_th number in the first is the number of ways in which _n_ can be
-made up of numbers which, divided by 3, leave a remainder 1; and that
-the _n_th number in the second is the number of ways in which _n_ can
-be made up of numbers which, divided by 3, leave a remainder 2.
-
-It is very easy to shew in how many ways a number can be made up of
-a given number of numbers, if different orders count as different
-ways. Suppose, for instance, we would know in how many ways 12 can
-be thus made of 7 numbers. If we write down 12 units, there are 11
-intervals between unit and unit. There is no way of making 12 out of 7
-numbers which does not answer to distributing 6 partition-marks in the
-intervals, 1 in each of 6, and collecting all the units which are not
-separated by partition-marks. Thus, 1 + 1 + 3 + 2 + 1 + 2 + 2, which is
-one way of making 12 out of 7 numbers, answers to
-
- | | | | | |
- 1 | 1 | 111 | 11 | 1 | 11 | 11
- | | | | | |
-
-in which the partition-marks come in the 1st, 2d, 5th, 7th, 8th, and
-10th of the 11 intervals. Consequently, to ask in how many ways 12 can
-be made of 7 numbers, is to ask in how many ways 6 partition-marks can
-be placed in 11 intervals; or, how many combinations or selections can
-be made of 6 out of 11. The answer is,
-
- 11 × 10 × 9 × 8 × 7 × 6
- -----------------------, or 462.
- 1 × 2 × 3 × 4 × 5 × 6
-
-Let us denote by _m_ₙ the number of ways in which _m_ things can be
-taken out of _n_ things, so that _m_ₙ is the abbreviation for
-
- _n_ - 1 _n_ - 2 _n_ - _m_ + 1
- _n_ × ------ × ------- ... as far as -------------
- 2 3 _m_
-
-Then _m_ₙ also represents the number of ways in which _m_ + 1 numbers
-can be put together to make _n_ + 1. What we proved above is, that 6₁₁
-is the number of ways in which we can put together 7 numbers to make
-12. There will now be no difficulty in proving the following:
-
- 2ⁿ = 1 + 1ₙ + 2ₙ + 3ₙ ... + _n_ₙ
-
-In the preceding question, 0 did not enter into the list of numbers
-used. Thus, 3 + 1 + 0 + 0 was not considered as one of the ways of
-putting together four numbers to make 5. But let us now ask, what is
-the number of ways of putting together 7 numbers to make 12, allowing 0
-to be in the list of numbers. There can be no more (nor fewer) ways of
-doing this than of putting 7 numbers together, among which 0 is _not_
-included, to make 19. Take every way of making 12 (0 included), and put
-on 1 to each number, and we get a way of making 19 (0 not included).
-Take any way of making 19 (0 not included), and strike off 1 from
-each number, and we have one of the ways of making 12 (0 included).
-Accordingly, 6₁₈ is the number of ways of putting together 7 numbers (0
-being allowed) to make 12. And (_m_- 1)ₙ₊ₘ₋₁ is the number of ways of
-putting together _m_ numbers to make _n_, 0 being included.
-
-This last amounts to the solution of the following: In how many ways
-can _n_ counters (undistinguishable from each other) be distributed
-into _m_ boxes? And the following will now be easily proved: The number
-of ways of distributing _c_ undistinguishable counters into _b_ boxes is
-(_b_ - 1)_{_b_ + _c_ - 1}, if any box or boxes may be left empty. But
-if there must be 1 at least in each box, the number of ways is (_b_ -
-1)_{_c_ - 1}; if there must be 2 at least in each box, it is (_b_ -
-1)_{_c- b_-1}; if there must be 3 at least in each box, it is (_b_ -
-1)_{_c_ - 2_b_ - 1}; and so on.
-
-The number of ways in which _m odd_ numbers can be put together to make
-_n_, is the same as the number of ways in which _m_ even numbers (0
-included) can be put together to make _n_-_m_; and this is the number
-of ways in which _m_ numbers (odd or even, 0 included) can be put
-together to make ½(_n_-_m_). Accordingly, the number of ways in which m
-odd numbers can be put together to make _n_ is the same as the number
-of combinations of _m_-1 things out of ½(_n_-_m_) + _m_-1, or ½(_n_ +
-_m_)-1. Unless _n_ and _m_ be both even or both odd, the problem is
-evidently impossible.
-
-There are curious and useful relations existing between numbers of
-combinations, some of which may readily be exhibited, under the simple
-expression of _m_ₙ to stand for the number of ways in which _m_ things
-may be taken out of _n_. Suppose we have to take 5 out of 12: Let the
-12 things be marked A, B, C, &c. and set apart one of them, A. Every
-collection of 5 out of the 12 either does or does not include A. The
-number of the latter sort must be 5₁₁; the number of the former sort
-must be 4₁₁, since it is the number of ways in which the _other four_
-can be chosen out of all but A. Consequently, 5₁₂ must be 5₁₁ + 4₁₁,
-and thus we prove in every case,
-
- _m_ₙ′ = _m_ₙ₋₁ + (_m_ - 1)ₙ₋₁
-
-0ₙ and _n_ₙ both are 1; for there is but one way of taking _none_, and
-but one way of taking _all_. And again _m_ₙ and (_n_-_m_)ₙ are the same
-things. And if _m_ be greater than _n_, _m_ₙ is 0; for there are no
-ways of doing it. We make one of our preceding results more symmetrical
-if we write it thus,
-
- 2ⁿ = 0ₙ + 1ₙ + 2ₙ + ... + _n_ₙ
-
-If we now write down the table of symbols in which the (_m_ + 1)th
-
- 0 1 2 3, &c.
- +--------------------------------------
- 1 | 0₁ 1₁ 2₁ 3₁, &c.
- 2 | 0₂ 1₂ 2₂ 3₂, &c.
- 3 | 0₃ 1₃ 2₃ 3₃, &c.
- &c. | &c. &c. &c. &c.
-
-number of the _n_th row represents _m_ₙ, the number of combinations of
-_m_ out of _n_, we see it proved above that the law of formation of
-this table is as follows: Each number is to be the sum of the number
-above it and the number preceding the number above it. Now, the first
-row must be 1, 1, 0, 0, 0, &c. and the first column must be 1, 1, 1, 1,
-&c. so that we have a table of the following kind, which may be carried
-as far as we please:
-
- 0 1 2 3 4 5 6 7 8 9 10
- +----------------------------------------------------
- 1 | 1 1 0 0 0 0 0 0 0 0 0
- 2 | 1 2 1 0 0 0 0 0 0 0 0
- 3 | 1 3 3 1 0 0 0 0 0 0 0
- 4 | 1 4 6 4 1 0 0 0 0 0 0
- 5 | 1 5 10 10 5 1 0 0 0 0 0
- 6 | 1 6 15 20 15 6 1 0 0 0 0
- 7 | 1 7 21 35 35 21 7 1 0 0 0
- 8 | 1 8 28 56 70 56 28 8 1 0 0
- 9 | 1 9 36 84 126 126 84 36 9 1 0
- 10 | 1 10 45 120 210 252 210 120 45 10 1
-
-Thus, in the row 9, under the column headed 4, we see 126, which is 9
-× 8 × 7 × 6 ÷ (1 × 2 × 3 × 4), the number of ways in which 4 can be
-chosen out of 9, which we represent by 4-{9}.
-
-If we add the several rows, we have 1 + 1 or 2, 1 + 2 + 1 or 2², next
-1 + 3 + 3 + 1 or 2³, &c. which verify a theorem already announced; and
-the law of formation shews us that the several columns are formed thus:
-
- 1 1 1 2 1 1 3 3 1
- 1 1 1 2 1 1 3 3 1
- ----- ------- ---------
- 1 2 1 1 3 3 1 1 4 6 4 1, &c.
-
-so that the sum in each row must be double of the sum in the preceding.
-But we can carry the consequences of this mode of formation further. If
-we make the powers of 1 + _x_ by actual algebraical multiplication, we
-see that the process makes the same oblique addition in the formation
-of the numerical multipliers of the powers of _x_.
-
- 1 + _x_
- 1 + _x_
- -------
- 1 + _x_
- _x_ + _x_²
- ---------------
- 1 + 2_x_ + _x_²
-
- 1 + 2_x_ + _x_²
- 1 + _x_
- ---------------
- 1 + 2_x_ + _x_²
- _x_ + 2_x_² + _x_³
- -----------------------
- 1 + 3_x_ + 3_x_² + _x_³
-
-Here are the second and third powers of 1 + _x_: the fourth, we can
-tell beforehand from the table, must be 1 + 4_x_ + 6_x_² + 4_x_³ +
-_x_⁴; and so on. Hence we have
-
- (1 + _x_)ⁿ = 0ₙ + 1ₙ_x_ + 2ₙ_x_² + 3ₙ_x_³ + ... + _n_ₙ_x_ⁿ
-
-which is usually written with the symbols 0ₙ, 1ₙ, &c. at length, thus,
-
- _n_ - 1 _n_ - 1 _n_ - 2
- (1 + _x_)ⁿ = 1 + _nx_ + _n_-------_x_² + _n_------- -------_x_³ + &c.
- 2 2 3
-
-This is the simplest case of what in algebra is called the _binomial
-theorem_. If instead of 1 + _x_ we use _x_ + _a_, we get
-
- (_x_+_a_)ⁿ = _x_ⁿ+1ₙ_ax_ⁿ⁻¹+2ₙ_a_²_x_ⁿ⁻²+3ₙ_a_³_x_ⁿ⁻³+... +_n_ₙ_a_ⁿ
-
-We can make the same table in another form. If we take a row of ciphers
-beginning with unity, and setting down the first, add the next, and
-then the next, and so on, and then repeat the process with one step
-less, and then again with one step less, we have the following:
-
- 1 0 0 0 0 0 0
- 1 1 1 1 1 1 1
- 1 2 3 4 5 6
- 1 3 6 10 15
- 1 4 10 20
- 1 5 15
- 1 6
- 1
-
-In the oblique columns we see 1 1, 1 2 1, 1 3 3 1, &c. the same as
-in the original table, and formed by the same additions. If, before
-making the additions, we had always multiplied by _a_, we should have
-got the several components of the powers of 1 + _a_, thus,
-
- 1 0 0 0 0
- 1 _a_ _a_² _a_³ _a_⁴
- 1 2_a_ 3_a_² 4_a_³
- 1 3_a_ 6_a_²
- 1 4_a_
- 1
-
-where the oblique columns 1 + _a_, 1 + 2_a_ + _a_², 1 + 3_a_ + 3_a_² +
-_a_³, &c., give the several powers of 1 + _a_. If instead of beginning
-with 1, 0, 0, &c. we had begun with _p_, 0, 0, &c. we should have got
-_p_, _p_ × 4_a_, _p_ × 6_a_², &c. at the bottom of the several columns;
-and if we had written at the top _x_⁴, _x_³, _x_², _x_, 1, we should
-have had all the materials for forming _p_(_x_ + _a_)⁴ by multiplying
-the terms at the top and bottom of each column together, and adding the
-results.
-
-Suppose we follow this mode of forming _p_(_x_ + _a_)³ + _q_(_x_ +
-_a_)² + _r_(_x_ + _a_) + _s_.
-
- _x_³ _x_² _x_ 1 _x_² _x_ 1 _x_ 1 1
- _p_ 0 0 0 _q_ 0 0 _r_ 0 3
- _p_ _pa_ _pa_² _pa_³ _q_ _qa_ _qa_² _r_ _ra_
- _p_ 2_pa_ 3_pa_² _q_ 2_qa_ _r_
- _p_ 3_pa_ _q_
- _p_
-
- _px_³ + 3_pax_² + 3_pa_²_x_ + _pa_³ + _qx_² + 2_qax_ + _qa_²
- + _rx_ + _ra_ + _s_
-
- = _px_³ + (3_pa_ + _q_)_x_² + (3_pa_² + 2_qa_ + _r_)_x_ + _pa_³
- + _qa_² + _ra_ + _s_
-
-Now, observe that all this might be done in one process, by entering
-_q_, _r_, and _s_ under their proper powers of _x_ in the first
-process, as follows
-
- _x_³ _x_² _x_ 1
- _p_ _q_ _r_ _s_
- _p_ _pa_ + _q_ _pa_² + _qa_ + _r_ _pa_³ + _qa_² + _ra_ + _s_
- _p_ 2_pa_ + _q_ 3_pa_² + 2_qa_ + _r_
- _p_ 3_pa_ + _q_
- _p_
-
-This process[65] is the one used in Appendix XI., with the slight
-alteration of varying the sign of the last letter, and making
-subtractions instead of additions in the last column. As it stands, it
-is the most convenient mode of writing _x_ + _a_ instead of _x_ in a
-large class of algebraical expressions. For instance, what does 2_x_⁵ +
-_x_⁴ + 3_x_² + 7_x_ + 9 become when _x_ + 5 is written instead of _x_?
-The expression, made complete, is,
-
- 2_x_⁵ + 1_x_⁴ + 0_x_³ + 3_x_² + 7_x_ + 9
-
- 1 0 3 7 9
- 2 11 55 278 1397 6994
- 2 21 160 1078 6787
- 2 31 315 2653
- 2 41 520
- 2 51
-
- _Answer_, 2_x_⁵ + 51_x_⁴ + 520_x_³ + 2653_x_² + 6787_x_ + 6994.
-
-[65] The principle of this mode of demonstration of Horner’s method was
-stated in Young’s Algebra (1823), being the earliest elementary work in
-which that method was given.
-
-
-
-
-APPENDIX XI.
-
-ON HORNER’S METHOD OF SOLVING EQUATIONS.
-
-
-The rule given in this chapter is inserted on account of its excellence
-as an exercise in computation. The examples chosen will require but
-little use of algebraical signs, that they may be understood by those
-who know no more of algebra than is contained in the present work.
-
-To solve an equation such as
-
- 2_x_⁴ + _x_² - 3_x_ = 416793,
-
-or, as it is usually written,
-
- 2_x_⁴ + _x_² - 3_x_ - 416793 = 0,
-
-we must first ascertain by trial not only the first figure of the root,
-but also the denomination of it: if it be a 2, for instance, we must
-know whether it be 2, or 20, or 200, &c., or ·2, or ·02, or ·002,
-&c. This must be found by trial; and the shortest way of making the
-trial is as follows: Write the expression in its complete form. In the
-preceding case the form is not complete, and the complete form is
-
- 2_x_⁴ + 0_x_³ + 1_x_² - 3_x_ - 416793.
-
-To find what this is when x is any number, for instance, 3000, the best
-way is to take the first multiplier (2), multiply it by 3000, and take
-in the next multiplier (0), multiply the result by 3000, and take in
-the next multiplier (1), and so on to the end, as follows:
-
- 2 × 3000 + 0 = 6000; 6000 × 3000 + 1 = 18000001
-
- 18000001 × 3000 - 3 = 54000002997
-
- 54000002997 × 3000 - 416793 = 162000008574207
-
-Now try the value of the above when _x_ = 30. We have then, for the
-steps, 60 (2 × 30 + 0), 1801, 54027, and lastly,
-
-1620810-416793,
-
-or _x_ = 30 makes the first terms greater than 416793. Now try _x_ = 20
-which gives 40, 801, 16017, and lastly,
-
-320340-416793,
-
-or _x_ = 20 makes the first terms less than 416793. Between 20 and
-30, then, must be a value of _x_ which makes 2_x_⁴ + _x_²-3x equal to
-416793. And this is the preliminary step of the process.
-
-Having got thus far, write down the coefficients +2, 0, +1,-3, and
--416793, each with its proper algebraical sign, except the last, in
-which let the sign be changed. This is the most convenient way when the
-last sign is-. But if the last sign be +, it may be more convenient
-to let it stand, and change all which come before. Thus, in solving
-_x_³-12_x_ + 1 = 0, we might write
-
- -1 0 +12 1
-
-whereas in the instance before us, we write
-
- +2 0 +1 -3 416793
-
-Having done this, take the highest figure of the root, properly named,
-which is 2 tens, or 20. Begin with the first column, multiply by 20,
-and join it to the number in the next column; multiply that by 20,
-and join it to the number in the next column; and so on. But when you
-come to the last column, subtract the product which comes out of the
-preceding column, or join it to the last column after changing its
-sign. When this has been done, repeat the process with the numbers
-which now stand in the columns, omitting the last, that is, the
-subtracting step; then repeat it again, going only as far as the last
-column but two, and so on, until the columns present a set of rows of
-the following appearance:
-
- _a_ _b_ _c_ _d_ _e_
- _f_ _g_ _h_ _i_
- _k_ _l_ _m_
- _n_ _o_
- _p_
-
-to the formation of which the following is the key:
-
- _f_ = 20_a_ + _b_,
- _g_ = 20_f_ + _c_,
- _h_ = 20_g_ + _d_,
- _i_ = _e_ - 20_h_,
- _k_ = 20_a_ + _f_,
- _l_ = 20_k_ + _g_,
- _m_ = 20_l_ + _h_,
- _n_ = 20_a_ + _k_,
- _o_ = 20_n_ + _l_,
- _p_ = 20_a_ + _n_.
-
-We call this _Horner’s Process_, from the name of its inventor. The
-result is as follows:
-
- 2 0 1 -3 416793 (20
- 40 801 16017 96453
- 80 2401 64037
- 120 4801
- 160
-
-We have now before us the row
-
- 2 160 4801 64037 96453
-
-which furnishes our means of guessing at the next, or units’ figure of
-the root.
-
-Call the last column the _dividend_, the last but one the _divisor_,
-and all that come before _antecedents_. See how often the dividend
-contains the divisor; this gives the guess at the next figure. The
-guess is a true one,[66] if, on applying Horner’s process, the divisor
-result, augmented as it is by the antecedent processes, still go as
-many times in the dividend. For example, in the case before us, 96453
-contains 64037 once; let 1 be put on its trial. Horner’s process is
-found to succeed, and we have for the second process,
-
- 2 160 4801 64037 96453
- 162 4963 69000 27453
- 164 5127 74127
- 166 5293
- 168
-
-As soon as we come to the fractional portion of the root, the process
-assumes a more[67] methodical form.
-
-The equation being of the _fourth_ degree, annex _four_ ciphers to
-the dividend, _three_ to the divisor, _two_ to the antecedent, and
-_one_ to the previous antecedent, leaving the first column as it is;
-then find the new figure by the dividend and divisor, as before,[68]
-and apply Horner’s process. Annex ciphers to the results, as before,
-and proceed in the same way. The annexing of the ciphers prevents our
-having any thing to do with decimal points, and enables us to use the
-quotient-figures without paying any attention to their _local_ values.
-The following exhibits the whole process from the beginning, carried
-as far as it is here intended to go before beginning the contraction,
-which will give more figures, as in the rule for the square root. The
-following, then, is the process as far as one decimal place:
-
-[66] Various exceptions may arise when an equation has two nearly equal
-roots. But I do not here introduce algebraical difficulties; and a
-student might give himself a hundred examples, taken at hazard, without
-much chance of lighting upon one which gives any difficulty.
-
-[67] This form might be also applied to the integer portions; but
-it is hardly needed in such instances as usually occur. See the
-article _Involution and Evolution_ in the _Supplement_ to the _Penny
-Cyclopædia_.
-
-[68] After the second step, the trial will rarely fail to give the true
-figure.
-
- 2 0 1 -3 416793(213
- 40 801 16017 96453
- 80 2401 64037 -----
- 120 4801 ----- 274530000
- 160 ---- 69000 47339778
- --- 4963 74127000 ---------
- 162 5127 --------
- 164 529300 75730074
- 166 ------ 77348376
- 1680 534358
- ---- 539434
- 1686 544528
- 1692
- 1698
- 1704
- ----
-
-If we now begin the contraction, it is good to know beforehand on
-what number of additional root-figures we may reckon. We may be
-pretty certain of having nearly as many as there are figures in the
-divisor when we begin to contract--one less, or at least two less.
-Thus, there being now eight figures in the divisor, we may conclude
-that the contraction will give us at least six more figures. To begin
-the contraction, let the dividend stand, cut off one figure from the
-divisor, two from the column before that, three from the one before
-that, and so on. Thus, our contraction begins with
-
- | | | |
- |0002 1|704 5445|28 7734837|6 47339778
- | | | |
-
-The first column is rendered quite useless here. Conduct the process
-as before, using only the figures which are not cut off. But it will
-be better to go as far as the first figure cut off, carrying from the
-second figure cut off. We shall then have as follows:
-
- | | |
- 1|704 5445|28 7734837|6 47339778(6
- | 5455|5 7767570|6 734354
- 5465|7 7800364|8
- 5475|9 |
- |
-
-At the next contraction the column 1|704 becomes |001704, and is quite
-useless. The next step, separately written (which is not, however,
-necessary in working), is
-
- | |
- 54|759 780036|48 734354(0
- | |
-
-Here the dividend 734354 does not contain the divisor 780036, and we,
-therefore, write 0 as a root figure and make another contraction, or
-begin with
-
- | |
- |54759 78003|648 734354(9
- | 78008|5 32277
- 78013|4
- |
-
-At the next contraction the first column becomes |0054759, and is
-quite useless, so that the remainder of the process is the contracted
-division.
-
- |
- 7801|34)32277(4137
- | 1072
- 292
- 58
- 3
-
-and the root required is 21·36094137.
-
-I now write down the complete process for another equation, one root of
-which lies between 3 and 4: it is
-
- _x_³ - 10_x_ + 1 = 0
-
- 1 0 -10 -1(3·1110390520730990796
- 3 -1 2000
- 6 1700 209000
- 9 0 1791 19769000
- 9 1 188300 743369000000
- 9 2 189231 172311710273000
- 9 30 19016300 991247447681
- 9 31 19025631 39462875420
- 9 32 1903496300 0 0 1391491559
- 9 33 0 1903524299 0 9 58993123
- 9 33 1 1903552298 2 7 0 0 1886047
- 9 33 2 1903560698 0 5|9|1 172835
- 9 33 30 0 1903569097 8 5|6|3 1515
- 9 33 30 3 1903569144 5 2|2| 183
- 9 33 30 6 1903569191 1|8|8 12
- 9 33 30 90 1903569193 0|6| 1
- 9 33|30|99 1903569194|9|3|
- 9 33|31|08 | | |
- |09|33|31|17
- | | | |
-
-The student need not repeat the rows of figures so far as they come
-under one another: thus, it is not necessary to repeat 190356. But he
-must use his own discretion as to how much it would be safe for him to
-omit. I have set down the whole process here as a guide.
-
-The following examples will serve for exercise:
-
- 1. 2_x_³ - 100_x_ - 7 = 0
- _x_ = 7·10581133.
-
- 2. _x_⁴ + _x_³ + _x_² + _x_ = 6000
- _x_ = 8·531437726.
-
- 3. _x_³ + 3_x_² - 4_x_ - 10 = 0
- _x_ = 1·895694916504.
-
- 4. _x_³ + 100_x_² - 5_x_ - 2173 = 0
- _x_ = 4·582246071058464.
- _
- 5. ∛2 = 1·259921049894873164767210607278.[69]
-
- 6. _x_³ - 6_x_ = 100
- _x_ = 5·071351748731.
-
- 7. _x_³ + 2_x_² + 3_x_ = 300
- _x_ = 5·95525967122398.
-
- 8. _x_³ + _x_ = 1000
- _x_ = 9·96666679.
-
- 9. 27000_x_³ + 27000_x_ = 26999999
- _x_ = 9·9666666.....
-
- 10. _x_³ - 6_x_ = 100
- _x_ = 5·0713517487.
-
- 11. _x_⁵ - 4_x_⁴ + 7_x_³ - 863 = 0
- _x_ = 4·5195507.
-
- 12. _x_³ - 20_x_ + 8 = 0
- _x_ = 4·66003769300087278.
-
- 13. _x_³ + _x_² + _x_ - 10 = 0
- _x_ = 1·737370233.
-
- 14. _x_³ - 46_x_² - 36_x_ + 18 = 0
- _x_ = 46·7616301847, or _x_ = ·3471623192.
-
- 15. _x_³ + 46_x_² - 36_x_ - 18 = 0
- _x_ = 1·1087925037.
-
- 16. 8991_x_³ - 162838_x_² + 746271_x_ - 81000 = 0
- _x_ = ·111222333444555....
-
- 17. 729_x_³ - 486_x_² + 99_x_ - 6 = 0
- _x_ = ·1111..., or ·2222..., or ·3333....
-
- 18. 2_x_³ + 3_x_² - 4_x_ = 500
- _x_ = 5·93481796231515279.
-
- 19. _x_³ + 2_x_² + _x_ - 150 = 0
- _x_ = 4·6684090145541983253742991201705899.
-
- 20. _x_³ + _x_ = _x_² + 500
- _x_ = 8·240963558144858526963.
-
- 21. _x_³ + 2_x_² + 3_x_ - 10000 = 0
- _x_ = 20·852905526009.
-
- 22. _x_⁵ - 4_x_ - 2000 = 0
- _x_ = 4·581400362.
-
- 23. 10_x_³ - 33_x_² - 11_x_ - 100 = 0
- _x_ = 4·146797808584278785.
-
- 24. _x_⁴ + _x_³ + _x_² + _x_ = 127694
- _x_ = 18·64482373095.
-
- 25. 10_x_³ + 11_x_² + 12_x_ = 100000
- _x_ = 21·1655995554508805.
-
- 26. _x_³ + _x_ = 13
- _x_ = 2·209753301208849.
-
- 27. _x_³ + _x_² - 4_x_ - 1600 = 0
- _x_ = 11·482837157.
-
- 28. _x_³ - 2_x_ = 5
- _x_ = 2·094551481542326591482386540579302963857306105628239.
-
- 29. _x_⁴ - 80_x_³ + 24_x_² - 6_x_ - 80379639 = 0
- _x_ = 123.[70]
-
- 30. _x_³ - 242_x_² - 6315_x_ + 2577096 = 0
- _x_ = 123.[71]
-
- 31. 2_x_⁴ - 3_x_³ + 6_x_ - 8 = 0
- _x_ = 1·414213562373095048803.[72]
-
- 32. _x_⁴ - 19_x_³ + 132_x_² - 302_x_ + 200 = 0
- _x_ = 1·02804, or 4, or 6·57653, or 7·39543[73].
-
- 33. 7_x_⁴ - 11_x_³ + 6_x_² + 5_x_ = 215
- _x_ = 2·70648049385791.[74]
-
- 34. 7_x_⁵ + 6_x_⁴ + 5_x_³ + 4_x_² + 3_x_ = 11
- _x_ = ·770768819622658522379296505.[75]
-
- 35. 4_x_⁶ + 7_x_⁵ + 9_x_⁴ + 6_x_³ + 5_x_² + 3_x_ = 792
- _x_ = 2·0520421768796053652140434012812019734602755995
- 45541724214.[76]
-
- 36. 2187_x_⁴ - 2430_x_³ + 945_x_² - 150_x_ + 8 = 0
- _x_ = ·1111...., or ·2222...., or ·3333...., or ·4444....
-
-[69] The solution of _x_³ + 0_x_² + 0_x_-2 = 0.
-
-[70] Taken from a paper on the subject, by Mr. Peter Gray, in the
-_Mechanics’ Magazine_.
-
-[71] Taken from a paper on the subject, by Mr. Peter Gray, in the
-_Mechanics’ Magazine_.
-
-[72] Taken from a paper on the subject, by Mr. Peter Gray, in the
-_Mechanics’ Magazine_.
-
-[73] Taken from the late Mr. Peter Nicholson’s Essay on Involution and
-Evolution.
-
-[74] Taken from the late Mr. Peter Nicholson’s Essay on Involution and
-Evolution.
-
-[75] Taken from the late Mr. Peter Nicholson’s Essay on Involution and
-Evolution.
-
-[76] Taken from the late Mr. Peter Nicholson’s Essay on Involution and
-Evolution.
-
-
-
-
-APPENDIX XII.
-
-RULES FOR THE APPLICATION OF ARITHMETIC TO GEOMETRY.
-
-
-The student should make himself familiar with the most common terms of
-geometry, after which the following rules will present no difficulty.
-In them all, it must be understood, that when we talk of multiplying
-one line by another, we mean the repetition of one line as often as
-there are units of a given kind, as feet or inches, in another. In any
-other sense, it is absurd to talk of multiplying a quantity by another
-quantity. All quantities of the same kind should be represented in
-numbers of the same unit; thus, all the lines should be either feet
-and decimals of a foot, or inches and decimals of an inch, &c. And in
-whatever unit a length is represented, a surface is expressed in the
-corresponding square units, and a solid in the corresponding cubic
-units. This being understood, the rules apply to all sorts of units.
-
-_To find the area of a rectangle._ Multiply together the units in
-two sides which meet, or multiply together two sides which meet; the
-product is the number of square units in the area. Thus, if 6 feet and
-5 feet be the sides, the area is 6 × 5, or 30 square feet. Similarly,
-the area of a square of 6 feet long is 6 × 6, or 36 square feet (234).
-
-_To find the area of a parallelogram._ Multiply one side by the
-perpendicular distance between it and the opposite side; the product is
-the area required in square units.
-
-_To find the area of a trapezium._[77] Multiply either of the two sides
-which are not parallel by the perpendicular let fall upon it from the
-middle point of the other.
-
-[77] A four-sided figure, which has two sides parallel, and two sides
-not parallel.
-
-_To find the area of a triangle._ Multiply any side by the
-perpendicular let fall upon it from the opposite vertex, and take half
-the product. Or, halve the sum of the three sides, subtract the three
-sides severally from this half sum, multiply the four results together,
-and find the square root of the product. The result is the number of
-square units in the area; and twice this, divided by either side, is
-the perpendicular distance of that side from its opposite vertex.
-
-_To find the radius of the internal circle which touches the three
-sides of a triangle._ Divide the area, found in the last paragraph, by
-half the sum of the sides.
-
-_Given the two sides of a right-angled triangle, to find the
-hypothenuse._ Add the squares of the sides, and extract the square root
-of the sum.
-
-_Given the hypothenuse and one of the sides, to find the other side._
-Multiply the sum of the given lines by their difference, and extract
-the square root of the product.
-
-_To find the circumference of a circle from its radius, very
-nearly._ Multiply twice the radius, or the diameter, by 3·1415927,
-taking as many decimal places as may be thought necessary. For a
-rough computation, multiply by 22 and divide by 7. For a very exact
-computation, in which decimals shall be avoided, multiply by 355 and
-divide by 113. See (131), last example.
-
-_To find the arc of a circular sector, very nearly, knowing the radius
-and the angle._ Turn the angle into seconds,[78] multiply by the
-radius, and divide the product by 206265. The result will be the number
-of units in the arc.
-
-[78] The right angle is divided into 90 equal parts called _degrees_,
-each degree into 60 equal parts called _minutes_, and each minute into
-60 equal parts called _seconds_. Thus, 2° 15′ 40″ means 2 degrees, 15
-minutes, and 40 seconds.
-
-_To find the area of a circle from its radius, very nearly._ Multiply
-the square of the radius by 3·1415927.
-
-_To find the area of a sector, very nearly, knowing the radius and the
-angle._ Turn the angle into seconds, multiply by the square of the
-radius, and divide by 206265 × 2, or 412530.
-
-_To find the solid content of a rectangular parallelopiped._ Multiply
-together three sides which meet: the result is the number of cubic
-units required. If the figure be not rectangular, multiply the area
-of one of its planes by the perpendicular distance between it and its
-opposite plane.
-
-_To find the solid content of a pyramid._ Multiply the area of the base
-by the perpendicular let fall from the vertex upon the base, and divide
-by 3.
-
-_To find the solid content of a prism._ Multiply the area of the base
-by the perpendicular distance between the opposite bases.
-
-_To find the surface of a sphere._ Multiply 4 times the square of the
-radius by 3·1415927.
-
-_To find the solid content of a sphere._ Multiply the cube of the
-radius by 3·1415927 × ⁴/₃, or 4·18879.
-
-_To find the surface of a right cone._ Take half the product of the
-circumference of the base and slanting side. _To find the solid
-content_, take one-third of the product of the base and the altitude.
-
-_To find the surface of a right cylinder._ Multiply the circumference
-of the base by the altitude. _To find the solid content_, multiply the
-area of the base by the altitude.
-
-The weight of a body may be found, when its solid content is known, if
-the weight of one cubic inch or foot of the body be known. But it is
-usual to form tables, not of the weights of a cubic unit of different
-bodies, but of the proportion which these weights bear to some one
-amongst them. The one chosen is usually distilled water, and the
-proportion just mentioned is called the _specific gravity_. Thus, the
-specific gravity of gold is 19·362, or a cubic foot of gold is 19·362
-times as heavy as a cubic foot of distilled water. Suppose now the
-weight of a sphere of gold is required, whose radius is 4 inches. The
-content of this sphere is 4 × 4 × 4 × 4·1888, or 268·0832 cubic inches;
-and since, by (217), each cubic inch of water weighs 252·458 grains,
-each cubic inch of gold weighs 252·458 × 19·362, or 4888·091 grains; so
-that 268·0832 cubic inches of gold weigh 268·0832 × 4888·091 grains, or
-227½ pounds troy nearly. Tables of specific gravities may be found in
-most works of chemistry and practical mechanics.
-
-The cubic foot of water is 908·8488 troy ounces, 75·7374 troy pounds,
-997·1369691 averdupois ounces, and 62·3210606 averdupois pounds. For
-all rough purposes it will do to consider the cubic foot of water as
-being 1000 common ounces, which reduces tables of specific gravities
-to common terms in an obvious way. Thus, when we read of a substance
-which has the specific gravity 4·1172, we may take it that a cubic foot
-of the substance weighs 4117 ounces. For greater correctness, diminish
-this result by 3 parts out of a thousand.
-
-THE END.
-
-
-
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-<p style='text-align:center; font-size:1.2em; font-weight:bold'>The Project Gutenberg eBook of Elements of arithmetic, by Augustus De Morgan</p>
-<div style='display:block; margin:1em 0'>
-This eBook is for the use of anyone anywhere in the United States and
-most other parts of the world 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 <a href="https://www.gutenberg.org">www.gutenberg.org</a>. If you
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-country where you are located before using this eBook.
-</div>
-
-<p style='display:block; margin-top:1em; margin-bottom:1em; margin-left:2em; text-indent:-2em'>Title: Elements of arithmetic</p>
-<p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em'>Author: Augustus De Morgan</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Release Date: August 1, 2022 [eBook #68662]</p>
-<p style='display:block; text-indent:0; margin:1em 0'>Language: English</p>
- <p style='display:block; margin-top:1em; margin-bottom:0; margin-left:2em; text-indent:-2em; text-align:left'>Produced by: Richard Tonsing and the Online Distributed Proofreading Team at https://www.pgdp.net (This file was produced from images generously made available by The Internet Archive)</p>
-<div style='margin-top:2em; margin-bottom:4em'>*** START OF THE PROJECT GUTENBERG EBOOK ELEMENTS OF ARITHMETIC ***</div>
-
-<hr class="chap x-ebookmaker-drop" />
-<h1>ELEMENTS OF ARITHMETIC.</h1>
-
-<p class="f150">BY AUGUSTUS DE MORGAN,</p>
-
-<p class="center space-above2">OF TRINITY COLLEGE, CAMBRIDGE;</p>
-
-<p class="f90">FELLOW OF THE ROYAL ASTRONOMICAL SOCIETY,<br />
-AND OF THE CAMBRIDGE PHILOSOPHICAL SOCIETY;<br />
-PROFESSOR OF MATHEMATICS IN UNIVERSITY COLLEGE, LONDON.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="blockquot">
-<p>“Hominis studiosi est intelligere, quas utilitates
-proprie afferat arithmetica his, qui solidam et
-perfectam doctrinam in cæteris philosophiæ partibus
-explicant. Quod enim vulgo dicunt, principium esse
-dimidium totius, id vel maxime in philosophiæ partibus
-conspicitur.”&mdash;<span class="smcap">Melancthon.</span></p>
-
-<p>“Ce n’est point par la routine qu’on e’instruit, c’est par
-sa propre réflexion; et il est essentiel de contracter
-l’habitude de se rendre raison de ce qu’on fait: cette
-habitude s’acquiert plus facilement qu’on ne pense; et une
-fois acquise, elle ne se perd plus.”&mdash;<span class="smcap">Condillac.</span></p>
-</div>
-
-<p class="f120 space-above2 space-below2"><i>SEVENTEENTH THOUSAND.</i></p>
-
-<p class="center">LONDON:<br />WALTON AND MABERLY,<br />
-UPPER GOWER STREET, AND IVY LANE, PATERNOSTER ROW.</p>
-
-<p class="center space-above1 space-below1">M.DCCC.LVIII.</p>
-
-<p class="center">LONDON:<br />PRINTED BY J. WERTHEIMER AND CO.,<br />
-CIRCUS-PLACE, FINSBURY-CIRCUS.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_v">[Pg v]</span></p>
-
-<h2 class="nobreak">PREFACE.</h2>
-</div>
-
-<p>The preceding editions of this work were published in 1830, 1832,
-1835, and 1840. This fifth edition differs from the three preceding,
-as to the body of the work, in nothing which need prevent the four,
-or any two of them, from being used together in a class. But it is
-considerably augmented by the addition of eleven new
-Appendixes,<a id="FNanchor_1" href="#Footnote_1" class="fnanchor">[1]</a>
-relating to matters on which it is most desirable that the advanced
-student should possess information. The <a href="#APPENDIX_I">first Appendix,
-on <i>Computation</i></a>, and the <a href="#APPENDIX_VI">sixth, on <i>Decimal Money</i></a>,
-should be read and practised by every student with as much attention
-as any part of the work. The mastery of the rules for instantaneous
-conversion of the usual fractions of a pound sterling into decimal
-fractions, gives the possessor the greater part of the advantage which
-he would derive from the introduction of a decimal coinage.</p>
-
-<p>At the time when this work was first published, the importance
-of establishing arithmetic in the young mind upon reason and
-demonstration, was not admitted by many. The case is now altered:
-<span class="pagenum" id="Page_vi">[Pg vi]</span>
-schools exist in which rational arithmetic is taught, and mere rules
-are made to do no more than their proper duty. There is no necessity
-to advocate a change which is actually in progress, as the works which
-are published every day sufficiently shew. And my principal reason for
-alluding to the subject here, is merely to warn those who want nothing
-but routine, that this is not the book for their purpose.</p>
-
-<p class="author"><span class="smcap">A. De Morgan.</span></p>
-<p><i>London, May 1, 1846.</i></p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_vii">[Pg vii]</span></p>
-<h2 class="nobreak">TABLE OF CONTENTS.</h2>
-</div>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="TOC" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" colspan="3"><span class="fontsize_120"><b>BOOK I.</b></span></td>
- </tr><tr>
- <td class="tdr"><span class="fontsize_80">SECTION</span></td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdr"><span class="fontsize_80">PAGE</span></td>
- </tr><tr>
- <td class="tdr">I.</td>
- <td class="tdl_ws1">Numeration</td>
- <td class="tdr"><a href="#SECTION_I">&nbsp;1</a></td>
- </tr><tr>
- <td class="tdr">II.</td>
- <td class="tdl_ws1">Addition and Subtraction</td>
- <td class="tdr"><a href="#SECTION_II">14</a></td>
- </tr><tr>
- <td class="tdr">III.</td>
- <td class="tdl_ws1">Multiplication</td>
- <td class="tdr"><a href="#SECTION_III">24</a></td>
- </tr><tr>
- <td class="tdr">IV.</td>
- <td class="tdl_ws1">Division</td>
- <td class="tdr"><a href="#SECTION_IV">34</a></td>
- </tr><tr>
- <td class="tdr">V.</td>
- <td class="tdl_ws1">Fractions</td>
- <td class="tdr"><a href="#SECTION_V">51</a></td>
- </tr><tr>
- <td class="tdr">VI.</td>
- <td class="tdl_ws1">Decimal Fractions</td>
- <td class="tdr"><a href="#SECTION_VI">65</a></td>
- </tr><tr>
- <td class="tdr">VII.</td>
- <td class="tdl_ws1">Square Root</td>
- <td class="tdr"><a href="#SECTION_VII">89</a></td>
- </tr><tr>
- <td class="tdr">VIII.</td>
- <td class="tdl_ws1">Proportion</td>
- <td class="tdr"><a href="#SECTION_VIII">100</a></td>
- </tr><tr>
- <td class="tdr">IX.</td>
- <td class="tdl_ws1">Permutations and Combinations</td>
- <td class="tdr"><a href="#SECTION_IX">118</a></td>
- </tr><tr>
- <td class="tdc_space-above1" colspan="3"><span class="fontsize_120"><b>BOOK II.</b></span></td>
- </tr><tr>
- <td class="tdr">I.</td>
- <td class="tdl_ws1">Weights and Measures, &amp;c.</td>
- <td class="tdr"><a href="#SECTION_2_I">124</a></td>
- </tr><tr>
- <td class="tdr">II.</td>
- <td class="tdl_ws1">Rule of Three</td>
- <td class="tdr"><a href="#SECTION_2_II">144</a></td>
- </tr><tr>
- <td class="tdr">III.</td>
- <td class="tdl_ws1">Interest, &amp;c.</td>
- <td class="tdr"><a href="#SECTION_2_III">150</a></td>
- </tr><tr>
- <td class="tdc_space-above1" colspan="3"><span class="fontsize_120"><b>APPENDIX.</b></span></td>
- </tr><tr>
- <td class="tdr">I.</td>
- <td class="tdl_ws1">On the mode of computing</td>
- <td class="tdr"><a href="#APPENDIX_I">161</a></td>
- </tr><tr>
- <td class="tdr">II.</td>
- <td class="tdl_ws1">On verification by casting out nines and elevens</td>
- <td class="tdr"><a href="#APPENDIX_II">166</a></td>
- </tr><tr>
- <td class="tdr">III.</td>
- <td class="tdl_ws1">On scales of notation</td>
- <td class="tdr"><a href="#APPENDIX_III">168</a></td>
- </tr><tr>
- <td class="tdr">IV.</td>
- <td class="tdl_ws1">On the definition of fractions</td>
- <td class="tdr"><a href="#APPENDIX_IV">171</a></td>
- </tr><tr>
- <td class="tdr">V.</td>
- <td class="tdl_ws1">On characteristics</td>
- <td class="tdr"><a href="#APPENDIX_V">174</a></td>
- </tr><tr>
- <td class="tdr">VI.</td>
- <td class="tdl_ws1">On decimal money</td>
- <td class="tdr"><a href="#APPENDIX_VI">176</a></td>
- </tr><tr>
- <td class="tdr">VII.</td>
- <td class="tdl_ws1">On the main principle of book-keeping</td>
- <td class="tdr"><a href="#APPENDIX_VII">180</a></td>
- </tr><tr>
- <td class="tdr">VIII.</td>
- <td class="tdl_ws1">On the reduction of fractions to others of nearly equal value</td>
- <td class="tdr"><a href="#APPENDIX_VIII">190</a></td>
- </tr><tr>
- <td class="tdr">IX.</td>
- <td class="tdl_ws1">On some general properties of numbers</td>
- <td class="tdr"><a href="#APPENDIX_IX">193</a></td>
- </tr><tr>
- <td class="tdr">X.</td>
- <td class="tdl_ws1">On combinations</td>
- <td class="tdr"><a href="#APPENDIX_X">201</a></td>
- </tr><tr>
- <td class="tdr">XI.</td>
- <td class="tdl_ws1">On Horner’s method of solving equations</td>
- <td class="tdr"><a href="#APPENDIX_XI">210</a></td>
- </tr><tr>
- <td class="tdr">XII.</td>
- <td class="tdl_ws1">Rules for the application of arithmetic to geometry</td>
- <td class="tdr"><a href="#APPENDIX_XII">217</a></td>
- </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-<div class="chapter">
-<p class="f200"><b>ELEMENTS OF ARITHMETIC</b>.</p>
-</div>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h2 class="nobreak">BOOK I.</h2>
-</div>
-
-<p class="f120"><b>PRINCIPLES OF ARITHMETIC</b>.</p>
-
-<h3 id="SECTION_I">SECTION I.<br /><span class="h_subtitle">NUMERATION.</span></h3>
-
-<p>1. Imagine a multitude of objects of the same kind assembled together;
-for example, a company of horsemen. One of the first things that must
-strike a spectator, although unused to counting, is, that to each man
-there is a horse. Now, though men and horses are things perfectly
-unlike, yet, because there is one of the first kind to every one of
-the second, one man to every horse, a new notion will be formed in the
-mind of the observer, which we express in words by saying that there
-is the same <i>number</i> of men as of horses. A savage, who had no
-other way of counting, might remember this number by taking a pebble
-for each man. Out of a method as rude as this has sprung our system
-of calculation, by the steps which are pointed out in the following
-articles. Suppose that there are two companies of horsemen, and a
-person wishes to know in which of them is the greater number, and also
-to be able to recollect how many there are in each.</p>
-
-<p>2. Suppose that while the first company passes by, he drops a pebble
-into a basket for each man whom he sees. There is no connexion between
-<span class="pagenum" id="Page_2">[Pg 2]</span>
-the pebbles and the horsemen but this, that for every horseman there is
-a pebble; that is, in common language, the <i>number</i> of pebbles and
-of horsemen is the same. Suppose that while the second company passes,
-he drops a pebble for each man into a second basket: he will then have
-two baskets of pebbles, by which he will be able to convey to any
-other person a notion of how many horsemen there were in each company.
-When he wishes to know which company was the larger, or contained most
-horsemen, he will take a pebble out of each basket, and put them aside.
-He will go on doing this as often as he can, that is, until one of the
-baskets is emptied. Then, if he also find the other basket empty, he
-says that both companies contained the same number of horsemen; if the
-second basket still contain some pebbles, he can tell by them how many
-more were in the second than in the first.</p>
-
-<p>3. In this way a savage could keep an account of any numbers in which
-he was interested. He could thus register his children, his cattle,
-or the number of summers and winters which he had seen, by means
-of pebbles, or any other small objects which could be got in large
-numbers. Something of this sort is the practice of savage nations at
-this day, and it has in some places lasted even after the invention
-of better methods of reckoning. At Rome, in the time of the republic,
-the prætor, one of the magistrates, used to go every year in great
-pomp, and drive a nail into the door of the temple of Jupiter; a way of
-remembering the number of years which the city had been built, which
-probably took its rise before the introduction of writing.</p>
-
-<p>4. In process of time, names would be given to those collections of
-pebbles which are met with most frequently. But as long as small
-numbers only were required, the most convenient way of reckoning them
-would be by means of the fingers. Any person could make with his
-two hands the little calculations which would be necessary for his
-purposes, and would name all the different collections of the fingers.
-He would thus get words in his own language answering to one, two,
-three, four, five, six, seven, eight, nine, and ten. As his wants
-increased, he would find it necessary to give names to larger numbers;
-<span class="pagenum" id="Page_3">[Pg 3]</span>
-but here he would be stopped by the immense quantity of words which
-he must have, in order to express all the numbers which he would be
-obliged to make use of. He must, then, after giving a separate name
-to a few of the first numbers, manage to express all other numbers by
-means of those names.</p>
-
-<p>5. I now shew how this has been done in our own language. The English
-names of numbers have been formed from the Saxon: and in the following
-table each number after ten is written down in one column, while another
-shews its connexion with those which have preceded it.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary="Number Names" cellpadding="0" >
- <tbody><tr>
- <td class="tdl_ws2">One</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">eleven</td>
- <td class="tdl_ws1">ten and one<a id="FNanchor_2" href="#Footnote_2" class="fnanchor">[2]</a></td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">two</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">twelve</td>
- <td class="tdl_ws1">ten and two</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">three</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">thirteen</td>
- <td class="tdl_ws1">ten and three</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">four</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">fourteen</td>
- <td class="tdl_ws1">ten and four</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">five</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">fifteen</td>
- <td class="tdl_ws1">ten and five</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">six</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">sixteen</td>
- <td class="tdl_ws1">ten and six</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">seven</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">seventeen</td>
- <td class="tdl_ws1">ten and seven</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">eight</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">eighteen</td>
- <td class="tdl_ws1">ten and eight</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">nine</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">nineteen</td>
- <td class="tdl_ws1">ten and nine</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">ten</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">twenty</td>
- <td class="tdl_ws1">two tens</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdl">twenty-one</td>
- <td class="tdl_ws1">two tens and one</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">fifty</td>
- <td class="tdl_ws1">five tens</td>
- </tr><tr>
- <td class="tdl">twenty-two</td>
- <td class="tdl_ws1">two tens and two</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">sixty</td>
- <td class="tdl_ws1">six tens</td>
- </tr><tr>
- <td class="tdc">&amp;c.&nbsp;&amp;c.</td>
- <td class="tdc">&amp;c.&nbsp;&amp;c.</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">seventy</td>
- <td class="tdl_ws1">seven tens</td>
- </tr><tr>
- <td class="tdl_ws2">thirty</td>
- <td class="tdl_ws1">three tens</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">eighty</td>
- <td class="tdl_ws1">eight tens</td>
- </tr><tr>
- <td class="tdl_ws2">&nbsp;&nbsp;&amp;c.</td>
- <td class="tdl_ws2">&nbsp;&amp;c.</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">ninety</td>
- <td class="tdl_ws1">nine tens</td>
- </tr><tr>
- <td class="tdl_ws2">forty</td>
- <td class="tdl_ws1">four tens</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">a hundred</td>
- <td class="tdl_ws1">ten tens</td>
- </tr><tr>
- <td class="tdl_ws2">&nbsp;&nbsp;&amp;c.</td>
- <td class="tdl_ws2">&nbsp;&amp;c.</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1">a hundred and one</td>
- <td class="tdl_ws1" colspan="2">ten tens and one</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdc">&amp;c.&emsp;&amp;c.</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws2">a thousand</td>
- <td class="tdl_ws1" colspan="2">ten hundreds</td>
- <td class="tdl_ws1"><span class="pagenum" id="Page_4">[Pg 4]</span></td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;ten thousand</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1" colspan="2">a hundred thousand</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1"><span class="ws4">a million</span></td>
- <td class="tdl_ws1" colspan="2">ten hundred thousand</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl" colspan="2">&nbsp;</td>
- <td class="tdl_ws1" colspan="3">or one thousand thousand</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1" colspan="4"><span class="ws3">ten millions</span></td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1" colspan="4">&nbsp;a hundred millions</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdc">&amp;c.</td>
- <td class="tdl_ws1" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="space-above1">6. Words, written down in ordinary language,
-would very soon be too long for such continual repetition as takes
-place in calculation. Short signs would then be substituted for words;
-but it would be impossible to have a distinct sign for every number:
-so that when some few signs had been chosen, it would be convenient to
-invent others for the rest out of those already made. The signs which
-we use areas follow:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="Ordinal Names" cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><span class="ws1">0</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">1</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">2</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">3</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">4</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">5</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">6</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">7</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">8</span><span class="ws1">&nbsp;</span></td>
- <td class="tdc"><span class="ws1">9</span><span class="ws1">&nbsp;</span></td>
- </tr><tr>
- <td class="tdc">nought</td>
- <td class="tdc">one</td>
- <td class="tdc">two</td>
- <td class="tdc">three</td>
- <td class="tdc">four</td>
- <td class="tdc">five</td>
- <td class="tdc">six</td>
- <td class="tdc">seven</td>
- <td class="tdc">eight</td>
- <td class="tdc">nine</td>
- </tr>
- </tbody>
-</table>
-
-<p class="space-above1">I now proceed to explain the way in which these
-signs are made to represent other numbers.</p>
-
-<p>7. Suppose a man first to hold up one finger, then two, and so on,
-until he has held up every finger, and suppose a number of men to do
-the same thing. It is plain that we may thus distinguish one number
-from another, by causing two different sets of persons to hold up each
-a certain number of fingers, and that we may do this in many different
-ways. For example, the number fifteen might be indicated either by
-fifteen men each holding up one finger, or by four men each holding up
-two fingers and a fifth holding up seven, and so on. The question is,
-of all these contrivances for expressing the number, which is the most
-convenient? In the choice which is made for this purpose consists what
-is called the method of <i>numeration</i>.</p>
-
-<p>8. I have used the foregoing explanation because it is very probable
-that our system of numeration, and almost every other which is used in
-the world, sprung from the practice of reckoning on the fingers, which
-children usually follow when first they begin to count. The method
-<span class="pagenum" id="Page_5">[Pg 5]</span>
-which I have described is the rudest possible; but, by a little
-alteration, a system may be formed which will enable us to express
-enormous numbers with great ease.</p>
-
-<p>9. Suppose that you are going to count some large number, for example,
-to measure a number of yards of cloth. Opposite to yourself suppose a
-man to be placed, who keeps his eye upon you, and holds up a finger for
-every yard which he sees you measure. When ten yards have been measured
-he will have held up ten fingers, and will not be able to count any
-further unless he begin again, holding up one finger at the eleventh
-yard, two at the twelfth, and so on. But to know how many have been
-counted, you must know, not only how many fingers he holds up, but also
-how many times he has begun again. You may keep this in view by placing
-another man on the right of the former, who directs his eye towards his
-companion, and holds up one finger the moment he perceives him ready
-to begin again, that is, as soon as ten yards have been measured. Each
-finger of the first man stands only for one yard, but each finger of
-the second stands for as many as all the fingers of the first together,
-that is, for ten. In this way a hundred may be counted, because the
-first may now reckon his ten fingers once for each finger of the second
-man, that is, ten times in all, and ten tens is one
-hundred (5).<a id="FNanchor_3" href="#Footnote_3" class="fnanchor">[3]</a>
-Now place a third man at the right of the second, who shall hold up
-a finger whenever he perceives the second ready to begin again. One
-finger of the third man counts as many as all the ten fingers of the
-second, that is, counts one hundred. In this way we may proceed until
-the third has all his fingers extended, which will signify that ten
-hundred or one thousand have been counted (5). A fourth man would
-enable us to count as far as ten thousand, a fifth as far as one
-hundred thousand, a sixth as far as a million, and so on.</p>
-
-<p>10. Each new person placed himself towards your left in the rank
-opposite to you. Now rule columns as in the next page, and to the right
-of them all place in words the number which you wish to represent; in
-<span class="pagenum" id="Page_6">[Pg 6]</span>
-the first column on the right, place the number of fingers
-which the first man will be holding up when that number of yards has
-been measured. In the next column, place the fingers which the second
-man will then be holding up; and so on.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols">
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;7th.&nbsp;</td>
- <td class="tdc">&nbsp;6th.&nbsp;</td>
- <td class="tdc">&nbsp;5th.&nbsp;</td>
- <td class="tdc">&nbsp;4th.&nbsp;</td>
- <td class="tdc">&nbsp;3rd.&nbsp;</td>
- <td class="tdc">&nbsp;2nd.&nbsp;</td>
- <td class="tdc">&nbsp;1st.&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">I.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">5</td>
- <td class="tdc">7</td>
- <td class="tdl_ws1">fifty-seven</td>
- </tr><tr>
- <td class="tdr_ws1">II.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc">0</td>
- <td class="tdc">4</td>
- <td class="tdl_ws1">one hundred and four.</td>
- </tr><tr>
- <td class="tdr_ws1">III.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">0</td>
- <td class="tdl_ws1">one hundred and ten.</td>
- </tr><tr>
- <td class="tdr_ws1">IV.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- <td class="tdc">4</td>
- <td class="tdc">8</td>
- <td class="tdl_ws1">two thousand three hundred</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&emsp;and forty-eight.</td>
- </tr><tr>
- <td class="tdr_ws1">V.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc">5</td>
- <td class="tdc">9</td>
- <td class="tdc">0</td>
- <td class="tdc">6</td>
- <td class="tdl_ws1">fifteen thousand nine</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&emsp;hundred and six.</td>
- </tr><tr>
- <td class="tdr_ws1">VI.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc">8</td>
- <td class="tdc">7</td>
- <td class="tdc">0</td>
- <td class="tdc">0</td>
- <td class="tdc">4</td>
- <td class="tdl_ws1">one hundred and eighty-seven</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&emsp;thousand and four.</td>
- </tr><tr>
- <td class="tdr_ws1">VII.</td>
- <td class="tdc">3</td>
- <td class="tdc">6</td>
- <td class="tdc">9</td>
- <td class="tdc">7</td>
- <td class="tdc">2</td>
- <td class="tdc">8</td>
- <td class="tdc">5</td>
- <td class="tdl_ws1">three million, six hundred and</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&emsp;ninety-seven thousand,</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&emsp;two hundred and eighty-five.</td>
- </tr>
- </tbody>
-</table>
-
-<p>11. In I. the number fifty-seven is expressed. This means (5) five tens
-and seven. The first has therefore counted all his fingers five times,
-and has counted seven fingers more. This is shewn by five fingers of
-the second man being held up, and seven of the first. In II. the number
-one hundred and four is represented. This number is (5) ten tens and
-four. The second person has therefore just reckoned all his fingers
-once, which is denoted by the third person holding up one finger;
-but he has not yet begun again, because he does not hold up a finger
-until the first has counted ten, of which ten only four are completed.
-When all the last-mentioned ten have been counted, he then holds up
-one finger, and the first being ready to begin again, has no fingers
-extended, and the number obtained is eleven tens, or ten tens and one
-ten, or one hundred and ten. This is the case in III. You will now find
-no difficulty with the other numbers in the table.</p>
-
-<p>12. In all these numbers a figure in the first column stands for only
-as many yards as are written under that figure in (6). A figure in
-the second column stands, not for as many yards, but for as many tens
-of yards; a figure in the third column stands for as many hundreds of
-yards; in the fourth column for as many thousands of yards; and so on:
-<span class="pagenum" id="Page_7">[Pg 7]</span>
-that is, if we suppose a figure to move from any column to the one on
-its left, it stands for ten times as many yards as before. Recollect
-this, and you may cease to draw the lines between the columns, because
-each figure will be sufficiently well known by the <i>place</i> in
-which it is; that is, by the number of figures which come upon the
-right hand of it.</p>
-
-<p>13. It is important to recollect that this way of writing numbers,
-which has become so familiar as to seem the <i>natural</i> method, is
-not more natural than any other. For example, we might agree to signify
-one ten by the figure of one with an accent, thus, 1′; twenty or two
-tens by 2′; and so on: one hundred or ten tens by 1″; two hundred by
-2″; one thousand by 1‴; and so on: putting Roman figures for accents
-when they become too many to write with convenience. The fourth number
-in the table would then be written 2‴ 3′ 4′ 8, which might also be
-expressed by 8 4′ 3″ 2‴, 4′ 8 3″ 2‴; or the order of the figures
-might be changed in any way, because their meaning depends upon the
-accents which are attached to them, and not upon the place in which
-they stand. Hence, a cipher would never be necessary; for 104 would be
-distinguished from 14 by writing for the first 1″ 4, and for the second
-1′ 4. The common method is preferred, not because it is more exact than
-this, but because it is more simple.</p>
-
-<p>14. The distinction between our method of numeration and that of the
-ancients, is in the meaning of each figure depending partly upon the
-place in which it stands. Thus, in 44444 each four stands for four of
-<i>something</i>; but in the first column on the right it signifies
-only four of the pebbles which are counted; in the second, it means
-four collections of ten pebbles each; in the third, four of one hundred
-each; and so on.</p>
-
-<p>15. The things measured in (11) were yards of cloth. In this case one
-yard of cloth is called the <i>unit</i>. The first figure on the right
-is said to be in the <i>units’ place</i>, because it only stands for
-so many units as are in the number that is written under it in (6).
-The second figure is said to be in the <i>tens’</i> place, because it
-stands for a number of tens of units. The third, fourth, and fifth
-figures are in the places of the <i>hundreds</i>, <i>thousands</i>, and
-<i>tens of thousands</i>, for a similar reason.
-<span class="pagenum" id="Page_8">[Pg 8]</span></p>
-
-<p>16. If the quantity measured had been acres of land, an acre of land
-would have been called the <i>unit</i>, for the unit is <i>one</i> of
-the things which are measured. Quantities are of two sorts; those which
-contain an exact number of units, as 47 yards, and those which do not,
-as 47 yards and a half. Of these, for the present, we only consider the
-first.</p>
-
-<p>17. In most parts of arithmetic, all quantities must have the same
-unit. You cannot say that 2 yards and 3 feet make 5 <i>yards</i>
-or 5 <i>feet</i>, because 2 and 3 make 5; yet you may say that 2
-<i>yards</i> and 3 <i>yards</i> make 5 <i>yards</i>, and that 2
-<i>feet</i> and 3 <i>feet</i> make 5 <i>feet</i>. It would be absurd to
-try to measure a quantity of one kind with a unit which is a quantity
-of another kind; for example, to attempt to tell how many yards there
-are in a gallon, or how many bushels of corn there are in a barrel of wine.</p>
-
-<p>18. All things which are true of some numbers of one unit are true of
-the same numbers of any other unit. Thus, 15 pebbles and 7 pebbles
-together make 22 pebbles; 15 acres and 7 acres together make 22 acres,
-and so on. From this we come to say that 15 and 7 make 22, meaning that
-15 things of the same kind, and 7 more of the same kind as the first,
-together make 22 of that kind, whether the kind mentioned be pebbles,
-horsemen, acres of land, or any other. For these it is but necessary to
-say, once for all, that 15 and 7 make 22. Therefore, in future, on this
-part of the subject I shall cease to talk of any particular units, such
-as pebbles or acres, and speak of numbers only. A number, considered
-without intending to allude to any particular things, is called an
-<i>abstract</i> number: and it then merely signifies repetitions of a
-unit, or the <i>number of times</i> a unit is repeated.</p>
-
-<p>19. I will now repeat the principal things which have been mentioned in
-this chapter.</p>
-
-<p>I. Ten signs are used, one to stand for nothing, the rest for the first
-nine numbers. They are 0, 1, 2, 3, 4, 5, 6, 7, 8, 9. The first of these
-is called a <i>cipher</i>.</p>
-
-<p>II. Higher numbers have not signs for themselves, but are signified
-by placing the signs already mentioned by the side of each other, and
-agreeing that the first figure on the right hand shall keep the value
-<span class="pagenum" id="Page_9">[Pg 9]</span>
-which it has when it stands alone; that the second on the right hand
-shall mean ten times as many as it does when it stands alone; that the
-third figure shall mean one hundred times as many as it does when it
-stands alone; the fourth, one thousand times as many; and so on.</p>
-
-<p>III. The right hand figure is said to be in the <i>units’ place</i>,
-the next to that in the <i>tens’ place</i>, the third in the
-<i>hundreds’ place</i>, and so on.</p>
-
-<p>IV. When a number is itself an exact number of tens, hundreds, or
-thousands, &amp;c., as many ciphers must be placed on the right of it as
-will bring the number into the place which is intended for it. The
-following are examples:</p>
-
-<p class="center">Fifty, or five tens, 50: seven hundred, 700.<span class="ws4">&nbsp;</span><br />
-Five hundred and twenty-eight thousand, 528000.</p>
-
-<p>If it were not for the ciphers, these numbers would be mistaken for 5,
-7, and 528.</p>
-
-<p>V. A cipher in the middle of a number becomes necessary when any one of
-the denominations, units, tens, &amp;c. is wanting. Thus, twenty thousand
-and six is 20006, two hundred and six is 206. Ciphers might be placed
-at the beginning of a number, but they would have no meaning. Thus 026
-is the same as 26, since the cipher merely shews that there are no
-hundreds, which is evident from the number itself.</p>
-
-<p>20. If we take out of a number, as 16785, any of those figures which
-come together, as 67, and ask, what does this sixty-seven mean? of what
-is it sixty-seven? the answer is, sixty-seven of the same collections
-as the 7, when it was in the number; that is, 67 hundreds. For the 6
-is 6 thousands, or 6 ten hundreds, or sixty hundreds; which, with the
-7, or 7 hundreds, is 67 hundreds: similarly, the 678 is 678 tens. This
-number may then be expressed either as</p>
-
-<ul class="index">
-<li class="isub4">1 ten thousand 6 thousands 7 hundreds 8 tens and 5;</li>
-<li class="isub1">or&nbsp; 16 thousands 78 tens and 5; or 1 ten thousand 678 tens and 5;</li>
-<li class="isub1">or&nbsp; 167 hundreds 8 tens and 5; or 1678 tens and 5, and so on.</li>
-</ul>
-
-<p class="f120 space-above1">21. EXERCISES.</p>
-<p><span class="pagenum" id="Page_10">[Pg 10]</span></p>
-
-<p>I. Write down the signs for&mdash;four hundred and seventy-six; two thousand
-and ninety-seven; sixty-four thousand three hundred and fifty; two
-millions seven hundred and four; five hundred and seventy-eight
-millions of millions.</p>
-
-<p>II. Write at full length 53, 1805, 1830, 66707, 180917324, 66713721,
-90976390, 25000000.</p>
-
-<p>III. What alteration takes place in a number made up entirely of nines,
-such as 99999, by adding one to it?</p>
-
-<p>IV. Shew that a number which has five figures in it must be greater
-than one which has four, though the first have none but small figures
-in it, and the second none but large ones. For example, that 10111 is
-greater than 9879.</p>
-
-<p>22. You now see that the convenience of our method of numeration arises
-from a few simple signs being made to change their value as they
-change the column in which they are placed. The same advantage arises
-from counting in a similar way all the articles which are used in
-every-day life. For example, we count money by dividing it into pounds,
-shillings, and pence, of which a shilling is 12 pence, and a pound 20
-shillings, or 240 pence. We write a number of pounds, shillings, and
-pence in three columns, generally placing points between the columns.
-Thus, 263 pence would not be written as 263, but as £1. 1. 11, where
-£ shews that the 1 in the first column is a pound. Here is a <i>system
-of numeration</i> in which a number in the second column on the right
-means 12 times as much as the same number in the first; and one in the
-third column is twenty times as great as the same in the second, or
-240 times as great as the same in the first. In each of the tables of
-measures which you will hereafter meet with, you will see a separate
-system of numeration, but the methods of calculation for all will be
-the same.</p>
-
-<p>23. In order to make the language of arithmetic shorter, some other
-signs are used. They are as follow:</p>
-
-<p>I. 15 + 38 means that 38 is to be added to 15, and is the same thing
-as 53. This is the <i>sum</i> of 15 and 38, and is read fifteen
-<i>plus</i> thirty-eight (<i>plus</i> is the Latin for <i>more</i>).
-<span class="pagenum" id="Page_11">[Pg 11]</span></p>
-
-<p>II. 64-12 means that 12 is to be taken away from 64, and is the
-same thing as 52. This is the <i>difference</i> of 64 and 12, and is
-read sixty-four <i>minus</i> twelve (<i>minus</i> is the Latin for
-<i>less</i>).</p>
-
-<p>III. 9 × 8 means that 8 is to be taken 9 times, and is the same
-thing as 72. This is the <i>product</i> of 9 and 8, and is read nine
-<i>into</i> eight.</p>
-
-<p>IV. 108/6 means that 108 is to be divided by 6, or that you must find
-out how many sixes there are in 108; and is the same thing as 18. This
-is the <i>quotient</i> of 108 and 6; and is read a hundred and eight <i>by</i> six.</p>
-
-<p>V. When two numbers, or collections of numbers, with the foregoing
-signs, are the same, the sign = is put between them. Thus, that 7
-and 5 make 12, is written in this way, 7 + 5 = 12. This is called an
-<i>equation</i>, and is read, seven <i>plus</i> five <i>equals</i>
-twelve. It is plain that we may construct as many equations as we
-please. Thus:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">12</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">7 + 9 - 3 = 12 + 1;<span class="ws2">&nbsp;</span></td>
- <td class="tdc">&mdash;</td>
- <td class="tdc">&nbsp;-&nbsp;1 + 3 × 2 = 11,</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on.</p>
-
-<p>24. It often becomes necessary to speak of something which is true not
-of any one number only, but of all numbers. For example, take 10 and 7;
-their sum<a id="FNanchor_4" href="#Footnote_4" class="fnanchor">[4]</a>
-is 17, their difference is 3. If this sum and difference
-be added together, we get 20, which is twice the greater of the two
-numbers first chosen. If from 17 we take 3, we get 14, which is twice
-the less of the two numbers. The same thing will be found to hold good
-of any two numbers, which gives this general proposition,&mdash;If the sum
-and difference of two numbers be added together, the result is twice
-the greater of the two; if the difference be taken from the sum, the
-result is twice the lesser of the two. If, then, we take <i>any</i>
-numbers, and call them the first number and the second number, and let
-the first number be the greater; we have</p>
-
-<p class="f120 no-wrap">(1st No. + 2d No.) + (1st No. - 2d No.) = twice 1st No.&nbsp;<br />
-(1st No. + 2d No.) - (1st No. - 2d No.) = twice 2d No.</p>
-
-<p>The brackets here enclose the things which must be first done, before
-<span class="pagenum" id="Page_12">[Pg 12]</span>
-the signs which join the brackets are made use of. Thus, 8-(2 + 1)
-× (1 + 1) signifies that 2 + 1 must be taken 1 + 1 times, and the
-product must be subtracted from 8. In the same manner, any result made
-from two or more numbers, which is true whatever numbers are taken,
-may be represented by using first No., second No., &amp;c., to stand for
-them, and by the signs in (23). But this may be much shortened; for as
-first No., second No., &amp;c., may mean any numbers, the letters <i>a</i>
-and <i>b</i> may be used instead of these words; and it must now be
-recollected that <i>a</i> and <i>b</i> stand for two numbers, provided
-only that <i>a</i> is greater than <i>b</i>. Let twice <i>a</i>
-be represented by 2<i>a</i>, and twice <i>b</i> by 2<i>b</i>. The
-equations then become</p>
-
-<p class="f120 no-wrap">&nbsp;&emsp;(<i>a</i> + <i>b</i>) + (<i>a</i> - <i>b</i>) = 2<i>a</i>,<br />
-and (<i>a</i> + <i>b</i>) - (<i>a</i> - <i>b</i>) = 2<i>b</i>.</p>
-
-<p class="no-indent">This may be explained still further, as follows:</p>
-
-<p>25. Suppose a number of sealed packets, marked <i>a</i>, <i>b</i>,
-<i>c</i>, <i>d</i>, &amp;c., on the outside, each of which contains a
-distinct but unknown number of counters. As long as we do not know
-how many counters each contains, we can make the letter which belongs
-to each stand for its number, so as to talk of <i>the number a</i>,
-instead of the number in the packet marked <i>a</i>. And because we do
-not know the numbers, it does not therefore follow that we know nothing
-whatever about them; for there are some connexions which exist between
-all numbers, which we call <i>general properties</i> of numbers. For
-example, take any number, multiply it by itself, and subtract one from
-the result; and then subtract one from the number itself. The first
-of these will always contain the second exactly as many times as the
-original number increased by one. Take the number 6; this multiplied
-by itself is 36, which diminished by one is 35; again, 6 diminished
-by 1 is 5; and 35 contains 5, 7 times, that is, 6 + 1 times. This
-will be found to be true of any number, and, when proved, may be said
-to be true of the number contained in the packet marked <i>a</i>, or
-of the number <i>a</i>. If we represent a multiplied by itself by
-<i>aa</i>,<a id="FNanchor_5" href="#Footnote_5" class="fnanchor">[5]</a>
-we have, by (23)</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>aa</i> - 1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&mdash;&mdash;&mdash;</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>a</i> + 1.</td>
- </tr><tr>
- <td class="tdc"><i>a</i> - 1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_13">[Pg 13]</span>
-26. When, therefore, we wish to talk of a number without specifying
-any one in particular, we use a letter to represent it. Thus: Suppose
-we wish to reason upon what will follow from dividing a number into
-three parts, without considering what the number is, or what are the
-parts into which it is divided. Let <i>a</i> stand for the number,
-and <i>b</i>, <i>c</i>, and <i>d</i>, for the parts into which it is
-divided. Then, by our supposition,</p>
-
-<p class="f120"><i>a</i> = <i>b</i> + <i>c</i> + <i>d</i>.</p>
-
-<p class="no-indent">On this we can reason, and produce results which
-do not belong to any particular number, but are true of all. Thus, if
-one part be taken away from the number, the other two will remain,
-or</p>
-
-<p class="f120"><i>a</i> - <i>b</i> = <i>c</i> + <i>d</i>.</p>
-
-<p class="no-indent">If each part be doubled, the whole number will be doubled, or</p>
-
-<p class="f120">2<i>a</i> = 2<i>b</i> + 2<i>c</i> + 2<i>d</i>.</p>
-
-<p class="no-indent">If we diminish one of the parts, as <i>d</i>, by a number <i>x</i>, we
-diminish the whole number just as much, or</p>
-
-<p class="f120"><i>a</i> - <i>x</i> = <i>b</i> + <i>c</i> + (<i>d</i> - <i>x</i>).</p>
-
-<p class="f120 space-above1">27. EXERCISES.</p>
-
-<p class="space-below1">What is <i>a</i> + 2<i>b</i> - <i>c</i>, where <i>a</i> = 12, <i>b</i> = 18,
-<i>c</i> = 7?&mdash;<i>Answer</i>, 41.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">What is&emsp;&nbsp;</td>
- <td class="tdc"><i>aa</i> - <i>bb</i></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>a</i> - <i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-below1">where <i>a</i> = 6 and <i>b</i> = 2?&mdash;<i>Ans.</i> 8.</p>
-
-<p>What is the difference between (<i>a</i> + <i>b</i>)(<i>c</i> + <i>d</i>)
-and <i>a</i> + <i>bc</i> + <i>d</i>, for the following values of
-<i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>?</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols">
- <tbody><tr>
- <td class="tdc">&nbsp;&emsp;<i>a</i>&emsp;&nbsp;</td>
- <td class="tdc">&nbsp;&emsp;<i>b</i>&emsp;&nbsp;</td>
- <td class="tdc">&nbsp;&emsp;<i>c</i>&emsp;&nbsp;</td>
- <td class="tdc">&nbsp;&emsp;<i>d</i>&emsp;&nbsp;</td>
- <td class="tdc">&nbsp;<i>Ans.</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- <td class="tdc">4</td>
- <td class="tdc">10</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdc">12</td>
- <td class="tdc">7</td>
- <td class="tdc">1</td>
- <td class="tdc">25</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_14">[Pg 14]</span></p>
-<h3 class="nobreak" id="SECTION_II">SECTION II.<br />
-<span class="h_subtitle">ADDITION AND SUBTRACTION.</span></h3>
-</div>
-
-<p>28. There is no process in arithmetic which does not consist entirely
-in the increase or diminution of numbers. There is then nothing which
-might not be done with collections of pebbles. Probably, at first,
-either these or the fingers were used. Our word <i>calculation</i>
-is derived from the Latin word <i>calculus</i>, which means a
-pebble. Shorter ways of counting have been invented, by which many
-calculations, which would require long and tedious reckoning if pebbles
-were used, are made at once with very little trouble. The four great
-methods are, Addition, Subtraction, Multiplication, and Division; of
-which, the last two are only ways of doing several of the first and
-second at once.</p>
-
-<p>29. When one number is increased by others, the number which is
-as large as all the numbers together is called their <i>sum</i>.
-The process of finding the sum of two or more numbers is called
-<span class="smcap">Addition</span>, and, as was said before, is denoted by
-placing a cross <big>(+)</big> between the numbers which are to be added together.</p>
-
-<p>Suppose it required to find the sum of 1834 and 2799. In order to add
-these numbers, take them to pieces, dividing each into its units, tens,
-hundreds, and thousands:</p>
-
-<p class="f110 no-wrap">1834 is 1 thous. 8 hund. 3 tens and 4;<br />
-2799 is 2 thous. 7 hund. 9 tens and 9.</p>
-
-<p>Each number is thus broken up into four parts. If to each part of the
-first you add the part of the second which is under it, and then put
-together what you get from these additions, you will have added 1834
-and 2799. In the first number are 4 units, and in the second 9: these
-will, when the numbers are added together, contribute 13 units to
-the sum. Again, the 3 tens in the first and the 9 tens in the second
-will contribute 12 tens to the sum. The 8 hundreds in the first and
-the 7 hundreds in the second will add 15 hundreds to the sum; and the
-<span class="pagenum" id="Page_15">[Pg 15]</span>
-thousand in the first with the 2 thousands in the second will
-contribute 3 thousands to the sum; therefore the sum required is</p>
-
-<p class="f110 no-wrap">3 thousands, 15 hundreds, 12 tens, and 13 units.</p>
-
-<p>To simplify this result, you must recollect that&mdash;</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">13 units are</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">1 ten and 3 units.</td>
- </tr><tr>
- <td class="tdr">12 tens are</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">1 hund. and</td>
- <td class="tdl_ws1">2 tens.</td>
- </tr><tr>
- <td class="tdr">15 hund. are</td>
- <td class="tdl_ws1">1 thous. and</td>
- <td class="tdl_ws1">5 hund.</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdr">3 thous. are</td>
- <td class="tdl_ws1">3 thous.</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>Now collect the numbers on the right hand side together, as was done
-before, and this will give, as the sum of 1834 and 2799,</p>
-
-<p class="f110">4 thousands, 6 hundreds, 3 tens, and 3 units,</p>
-
-<p class="no-indent">which (19) is written 4633.</p>
-
-<p>30. The former process, written with the signs of (23) is as follows:</p>
-
-<p class="f110">1834 = 1 × 1000 + 8 × 100 + 3 × 10 + 4<br />
-2799 = 2 × 1000 + 7 × 100 + 9 × 10 + 9</p>
-
-<p class="no-indent">Therefore,</p>
-
-<p class="f110">1834 + 2799 = 3 × 1000 + 15 × 100 + 12 × 10 + 13</p>
-
-<p class="no-indent">But</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">13 =</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">1 × 10 + 3</td>
- </tr><tr>
- <td class="tdr">12 × 10 =</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">1 × 100 +</td>
- <td class="tdl_ws1">2 × 10</td>
- </tr><tr>
- <td class="tdr">15 × 100 =</td>
- <td class="tdl_ws1">1 × 1000 +</td>
- <td class="tdl_ws1">5 × 100</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdr">3 × 1000 =</td>
- <td class="tdl_ws1">3 × 1000</td>
- <td class="tdl_ws1" colspan="2">&nbsp;&emsp;Therefore,</td>
- </tr><tr>
- <td class="tdr">1834 + 2799 =</td>
- <td class="tdl_ws1">4 × 1000 +</td>
- <td class="tdl_ws1">6 × 100 +</td>
- <td class="tdl_ws1">3 × 10 +  3</td>
- </tr><tr>
- <td class="tdr">=</td>
- <td class="tdl_ws1" colspan="3">4633.</td>
- </tr>
- </tbody>
-</table>
-
-<p>31. The same process is to be followed in all cases, but not at the
-same length. In order to be able to go through it, you must know how to
-add together the simple numbers. This can only be done by memory; and
-to help the memory you should make the following table three or four
-times for yourself:
-<span class="pagenum" id="Page_16">[Pg 16]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols">
- <tbody><tr>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;1&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;2&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;3&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;4&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;5&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;6&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;7&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;8&nbsp;&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;&nbsp;9&nbsp;&nbsp;</td>
- </tr><tr>
- <td class="tdc bb">1</td> <td class="tdc bb">2</td>
- <td class="tdc bb">3</td> <td class="tdc bb">4</td>
- <td class="tdc bb">5</td> <td class="tdc bb">6</td>
- <td class="tdc bb">7</td> <td class="tdc bb">8</td>
- <td class="tdc bb">9</td> <td class="tdc bb">10</td>
- </tr><tr>
- <td class="tdc bb">2</td> <td class="tdc bb">3</td>
- <td class="tdc bb">4</td> <td class="tdc bb">5</td>
- <td class="tdc bb">6</td> <td class="tdc bb">7</td>
- <td class="tdc bb">8</td> <td class="tdc bb">9</td>
- <td class="tdc bb">10</td> <td class="tdc bb">11</td>
- </tr><tr>
- <td class="tdc bb">3</td> <td class="tdc bb">4</td>
- <td class="tdc bb">5</td> <td class="tdc bb">6</td>
- <td class="tdc bb">7</td> <td class="tdc bb">8</td>
- <td class="tdc bb">9</td> <td class="tdc bb">10</td>
- <td class="tdc bb">11</td> <td class="tdc bb">12</td>
- </tr><tr>
- <td class="tdc bb">4</td> <td class="tdc bb">5</td>
- <td class="tdc bb">6</td> <td class="tdc bb">7</td>
- <td class="tdc bb">8</td> <td class="tdc bb">9</td>
- <td class="tdc bb">10</td> <td class="tdc bb">11</td>
- <td class="tdc bb">12</td> <td class="tdc bb">13</td>
- </tr><tr>
- <td class="tdc bb">5</td> <td class="tdc bb">6</td>
- <td class="tdc bb">7</td> <td class="tdc bb">8</td>
- <td class="tdc bb">9</td> <td class="tdc bb">10</td>
- <td class="tdc bb">11</td> <td class="tdc bb">12</td>
- <td class="tdc bb">13</td> <td class="tdc bb">14</td>
- </tr><tr>
- <td class="tdc bb">6</td> <td class="tdc bb">7</td>
- <td class="tdc bb">8</td> <td class="tdc bb">9</td>
- <td class="tdc bb">10</td> <td class="tdc bb">11</td>
- <td class="tdc bb">12</td> <td class="tdc bb">13</td>
- <td class="tdc bb">14</td> <td class="tdc bb">15</td>
- </tr><tr>
- <td class="tdc bb">7</td> <td class="tdc bb">8</td>
- <td class="tdc bb">9</td> <td class="tdc bb">10</td>
- <td class="tdc bb">11</td> <td class="tdc bb">12</td>
- <td class="tdc bb">13</td> <td class="tdc bb">14</td>
- <td class="tdc bb">15</td> <td class="tdc bb">16</td>
- </tr><tr>
- <td class="tdc bb">8</td> <td class="tdc bb">9</td>
- <td class="tdc bb">10</td> <td class="tdc bb">11</td>
- <td class="tdc bb">12</td> <td class="tdc bb">13</td>
- <td class="tdc bb">14</td> <td class="tdc bb">15</td>
- <td class="tdc bb">16</td> <td class="tdc bb">17</td>
- </tr><tr>
- <td class="tdc">9</td> <td class="tdc">10</td>
- <td class="tdc">11</td> <td class="tdc">12</td>
- <td class="tdc">13</td> <td class="tdc">14</td>
- <td class="tdc">15</td> <td class="tdc">16</td>
- <td class="tdc">17</td> <td class="tdc">18</td>
- </tr>
- </tbody>
-</table>
-
-<p>The use of this table is as follows: Suppose you want to find the sum
-of 8 and 7. Look in the left-hand column for either of them, 8, for
-example; and look in the top column for 7. On the same line as 8, and
-underneath 7, you find 15, their sum.</p>
-
-<p>32. When this table has been thoroughly committed to memory, so that
-you can tell at once the sum of any two numbers, neither of which
-exceeds 9, you should exercise yourself in adding and subtracting two
-numbers, one of which is greater than 9 and the other less. You should
-write down a great number of such sentences as the following, which
-will exercise you at the same time in addition, and in the use of the
-signs mentioned in (23).</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl">12 + 6 = 18</td>
- <td class="tdl_ws1">22 + 6 = 28</td>
- <td class="tdl_ws1">19 + 8 = 27</td>
- <td class="tdl_ws1"></td>
- </tr><tr>
- <td class="tdl">54 + 9 = 63</td>
- <td class="tdl_ws1">56 + 7 = 63</td>
- <td class="tdl_ws1">22 + 8 = 30</td>
- <td class="tdl_ws1"></td>
- </tr><tr>
- <td class="tdl">100 - 9 = 91</td>
- <td class="tdl_ws1">27 - 8 = 19</td>
- <td class="tdl_ws1">44 - 6 = 38,</td>
- <td class="tdl_ws1">&amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p>33. When the last two articles have been thoroughly studied, you will
-be able to find the sum of any numbers by the following process,<a id="FNanchor_6" href="#Footnote_6" class="fnanchor">[6]</a>
-which is the same as that in (29).
-<span class="pagenum" id="Page_17">[Pg 17]</span></p>
-
-<p><span class="smcap">Rule</span> I. Place the numbers under one another, units under
-units, tens under tens, and so on.</p>
-
-<p>II. Add together the units of all, and part the <i>whole</i> number
-thus obtained into units and tens. Thus, if 85 be the number, part it
-into 8 tens and 5 units; if 136 be the number, part it into 13 tens and
-6 units (20).</p>
-
-<p>III. Write down the units of this number under the units of the rest,
-and keep in memory the number of tens.</p>
-
-<p>IV. Add together all the numbers in the column of tens, remembering
-to take in (or carry, as it is called) the tens which you were told
-to recollect in III., and divide this number of tens into tens and
-hundreds. Thus, if 335 tens be the number obtained, part this into 33
-hundreds and 5 tens.</p>
-
-<p>V. Place the number of tens under the tens, and remember the number of
-hundreds.</p>
-
-<p>VI. Proceed in this way through every column, and at the last column,
-instead of separating the number you obtain into two parts, write it
-all down before the rest.</p>
-
-<p><span class="smcap">Example.</span>&mdash;What is</p>
-
-<p class="f110">1805 + 36 + 19727 + 3 + 1474 + 2008</p>
-
-<ul class="index fontsize_120">
-<li class="isub1">&nbsp;&nbsp;1805</li>
-<li class="isub2">&nbsp;&nbsp;36</li>
-<li class="isub1">19727</li>
-<li class="isub3">3</li>
-<li class="isub1">&nbsp;&nbsp;1474</li>
-<li class="isub1">&nbsp;&nbsp;2008</li>
-<li class="isub1">&mdash;&mdash;-</li>
-<li class="isub1">25053</li>
-</ul>
-
-<p>The addition of the units’ line, or 8 + 4 + 3 + 7 + 6 + 5, gives
-33, that is, 3 tens and 3 units. Put 3 in the units’ place, and add
-together the line of tens, taking in at the beginning the 3 tens which
-were created by the addition of the units’ line. That is, find 3 + 0
-+ 7 + 2 + 3 + 0, which gives 15 for the number of tens; that is, 1
-hundred and 5 tens. Add the line of hundreds together, taking care to
-add the 1 hundred which arose in the addition of the line of tens;
-that is, find 1 + 0 + 4 + 7 + 8, which gives exactly 20 hundreds,
-or 2 thousands and no hundreds. Put a cipher in the hundreds’ place
-(because, if you do not, the next figure will be taken for hundreds
-instead of thousands), and add the figures in the thousands’ line
-together, remembering the 2 thousands which arose from the hundreds’
-<span class="pagenum" id="Page_18">[Pg 18]</span>
-line; that is, find 2 + 2 + 1 + 9 + 1, which gives 15 thousands, or 1
-ten thousand and 5 thousand. Write 5 under the line of thousands, and
-collect the figures in the line of tens of thousands, remembering the
-ten thousand which arose out of the thousands’ line; that is, find 1 +
-1, or 2 ten thousands. Write 2 under the ten thousands’ line, and the
-operation is completed.</p>
-
-<p>34. As an exercise in addition, you may satisfy yourself that what I
-now say of the following square is correct. The numbers in every row,
-whether reckoned upright, or from right to left, or from corner to
-corner, when added together give the number 24156.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols">
- <tbody><tr>
- <td class="tdc bb" colspan="11">&nbsp;</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;2016&nbsp;</td> <td class="tdc bb">&nbsp;4212&nbsp;</td>
- <td class="tdc bb">&nbsp;1656&nbsp;</td> <td class="tdc bb">&nbsp;3852&nbsp;</td>
- <td class="tdc bb">&nbsp;1296&nbsp;</td> <td class="tdc bb">&nbsp;3492&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;936&nbsp;</td> <td class="tdc bb">&nbsp;3132&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;576&nbsp;</td> <td class="tdc bb">2772&nbsp;</td>
- <td class="tdc bb">&nbsp;&nbsp;216&nbsp;</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;252</td> <td class="tdc bb">2052</td>
- <td class="tdc bb">4248</td> <td class="tdc bb">1692</td>
- <td class="tdc bb">3888</td> <td class="tdc bb">1332</td>
- <td class="tdc bb">3528</td> <td class="tdc bb">&nbsp;972</td>
- <td class="tdc bb">3168</td> <td class="tdc bb">&nbsp;612</td>
- <td class="tdc bb">2412</td>
- </tr><tr>
- <td class="tdc bb">2448</td> <td class="tdc bb">&nbsp;288</td>
- <td class="tdc bb">2088</td> <td class="tdc bb">4284</td>
- <td class="tdc bb">1728</td> <td class="tdc bb">3924</td>
- <td class="tdc bb">1368</td> <td class="tdc bb">3564</td>
- <td class="tdc bb">1008</td> <td class="tdc bb">2808</td>
- <td class="tdc bb">&nbsp;648</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;684</td> <td class="tdc bb">2484</td>
- <td class="tdc bb">&nbsp;324</td> <td class="tdc bb">2124</td>
- <td class="tdc bb">4320</td> <td class="tdc bb">1764</td>
- <td class="tdc bb">3960</td> <td class="tdc bb">1404</td>
- <td class="tdc bb">3204</td> <td class="tdc bb">1044</td>
- <td class="tdc bb">2844</td>
- </tr><tr>
- <td class="tdc bb">2880</td> <td class="tdc bb">&nbsp;720</td>
- <td class="tdc bb">2520</td> <td class="tdc bb">&nbsp;360</td>
- <td class="tdc bb">2160</td> <td class="tdc bb">4356</td>
- <td class="tdc bb">1800</td> <td class="tdc bb">3600</td>
- <td class="tdc bb">1440</td> <td class="tdc bb">3240</td>
- <td class="tdc bb">1080</td>
- </tr><tr>
- <td class="tdc bb">1116</td> <td class="tdc bb">2916</td>
- <td class="tdc bb">&nbsp;756</td> <td class="tdc bb">2556</td>
- <td class="tdc bb">&nbsp;396</td> <td class="tdc bb">2196</td>
- <td class="tdc bb">3996</td> <td class="tdc bb">1836</td>
- <td class="tdc bb">3636</td> <td class="tdc bb">1476</td>
- <td class="tdc bb">3276</td>
- </tr><tr>
- <td class="tdc bb">3312</td> <td class="tdc bb">1152</td>
- <td class="tdc bb">2952</td> <td class="tdc bb">&nbsp;792</td>
- <td class="tdc bb">2592</td> <td class="tdc bb">&nbsp;&nbsp;36</td>
- <td class="tdc bb">2232</td> <td class="tdc bb">4032</td>
- <td class="tdc bb">1872</td> <td class="tdc bb">3672</td>
- <td class="tdc bb">1512</td>
- </tr><tr>
- <td class="tdc bb">1548</td> <td class="tdc bb">3348</td>
- <td class="tdc bb">1188</td> <td class="tdc bb">2988</td>
- <td class="tdc bb">&nbsp;432</td> <td class="tdc bb">2628</td>
- <td class="tdc bb">&nbsp;&nbsp;72</td> <td class="tdc bb">2268</td>
- <td class="tdc bb">4068</td> <td class="tdc bb">1908</td>
- <td class="tdc bb">3708</td>
- </tr><tr>
- <td class="tdc bb">3744</td> <td class="tdc bb">1584</td>
- <td class="tdc bb">3384</td> <td class="tdc bb">&nbsp;828</td>
- <td class="tdc bb">3024</td> <td class="tdc bb">&nbsp;468</td>
- <td class="tdc bb">2664</td> <td class="tdc bb">&nbsp;108</td>
- <td class="tdc bb">2304</td> <td class="tdc bb">4104</td>
- <td class="tdc bb">1944</td>
- </tr><tr>
- <td class="tdc bb">1980</td> <td class="tdc bb">3780</td>
- <td class="tdc bb">1224</td> <td class="tdc bb">3420</td>
- <td class="tdc bb">&nbsp;864</td> <td class="tdc bb">3060</td>
- <td class="tdc bb">&nbsp;504</td> <td class="tdc bb">2700</td>
- <td class="tdc bb">&nbsp;144</td> <td class="tdc bb">2340</td>
- <td class="tdc bb">4140</td>
- </tr><tr>
- <td class="tdc bb">4176</td> <td class="tdc bb">1620</td>
- <td class="tdc bb">3816</td> <td class="tdc bb">1260</td>
- <td class="tdc bb">3456</td> <td class="tdc bb">&nbsp;900</td>
- <td class="tdc bb">3096</td> <td class="tdc bb">&nbsp;540</td>
- <td class="tdc bb">2736</td> <td class="tdc bb">&nbsp;180</td>
- <td class="tdc bb">2376</td>
- </tr><tr>
- <td class="tdc bt" colspan="11">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>35. If two numbers must be added together, it will not alter the sum if
-you take away a part of one, provided you put on as much to the other.
-It is plain that you will not alter the whole number of a collection
-of pebbles in two baskets by taking any number out of one, and putting
-them into the other. Thus, 15 + 7 is the same as 12 + 10, since 12 is 3
-less than 15, and 10 is three more than 7. This was the principle upon
-which the whole of the process in (29) was conducted.</p>
-
-<p>36. Let <i>a</i> and <i>b</i> stand for two numbers, as in (24). It is
-impossible to tell what their sum will be until the numbers themselves
-are known. In the mean while <i>a</i> + <i>b</i> stands for this sum.
-<span class="pagenum" id="Page_19">[Pg 19]</span>
-To say, in algebraical language, that the sum of <i>a</i> and <i>b</i>
-is not altered by adding <i>c</i> to <i>a</i>, provided we take away
-<i>c</i> from <i>b</i>, we have the following equation:</p>
-
-<p class="f110">(<i>a</i> + <i>c</i>) + (<i>b</i> - <i>c</i>) = <i>a</i> + <i>b</i>;</p>
-
-<p class="no-indent">which may be written without brackets, thus,</p>
-
-<p class="f110"><i>a</i> + <i>c</i> + <i>b</i> - <i>c</i> = <i>a</i> + <i>b</i>.</p>
-
-<p class="no-indent">For the meaning of these two equations will appear
-to be the same, on consideration.</p>
-
-<p>37. If <i>a</i> be taken twice, three times, &amp;c., the results are
-represented in algebra by 2<i>a</i>, 3<i>a</i>, 4<i>a</i>, &amp;c. The sum
-of any two of this series may be expressed in a shorter form than by
-writing the sign + between them; for though we do not know what number
-<i>a</i> stands for, we know that, be it what it may, 2<i>a</i> +
-2<i>a</i> = 4<i>a</i>, 3<i>a</i> + 2<i>a</i> = 5<i>a</i>, 4<i>a</i> +
-9<i>a</i> = 13<i>a</i>; and generally, if <i>a</i> taken <i>m</i> times
-be added to <i>a</i> taken <i>n</i> times, the result is <i>a</i> taken
-<i>m</i> + <i>n</i> times, or</p>
-
-<p class="f110"><i>ma</i> + <i>na</i> = (<i>m</i> + <i>n</i>)<i>a</i>.</p>
-
-<p>38. The use of the brackets must here be noticed. They mean, that the
-expression contained inside them must be used exactly as a single
-letter would be used in the same place. Thus, <i>pa</i> signifies that
-<i>a</i> is taken <i>p</i> times, and (<i>m</i> + <i>n</i>)<i>a</i>,
-that <i>a</i> is taken <i>m</i> + <i>n</i> times. It is, therefore, a
-different thing from <i>m</i> + <i>na</i>, which means that <i>a</i>,
-after being taken <i>n</i> times, is added to <i>m</i>. Thus (3 + 4) ×
-2 is 7 × 2 or 14; while 3 + 4 × 2 is 3 + 8, or 11.</p>
-
-<p>39. When one number is taken away from another, the number which is
-left is called the <i>difference</i> or <i>remainder</i>. The process
-of finding the difference is called <span class="smcap">subtraction</span>.
-The number which is to be taken away must be of course the lesser of the two.</p>
-
-<p>40. The process of subtraction depends upon these two principles.</p>
-
-<p>I. The difference of two numbers is not altered by adding a number to
-the first, if you add the same number to the second; or by subtracting
-a number from the first, if you subtract the same number from the
-second. Conceive two baskets with pebbles in them, in the first of
-which are 100 pebbles more than in the second. If I put 50 more pebbles
-<span class="pagenum" id="Page_20">[Pg 20]</span>
-into each of them, there are still only 100 more in the first than in
-the second, and the same if I take 50 from each. Therefore, in finding
-the difference of two numbers, if it should be convenient, I may add
-any number I please to both of them, because, though I alter the
-numbers themselves by so doing, I do not alter their difference.</p>
-
-<ul class="index">
-<li class="isub1">II. Since&nbsp; &nbsp;6 exceeds&nbsp; 4 by&nbsp; 2,</li>
-<li class="isub3">and&nbsp; &nbsp;3 exceeds&nbsp; 2 by&nbsp; 1,</li>
-<li class="isub3">and 12 exceeds&nbsp; 5 by&nbsp; 7,</li>
-</ul>
-
-<p class="no-indent">6, 3, and 12 together, or 21, exceed 4, 2, and 5
-together, or 11, by 2, 1, and 7 together, or 10: the same thing may be
-said of any other numbers.</p>
-
-<p>41. If <i>a</i>, <i>b</i>, and <i>c</i> be three numbers, of which
-<i>a</i> is greater than <i>b</i> (40), I. leads to the following,</p>
-
-<p class="f110">(<i>a</i> + <i>c</i>) - (<i>b</i> + <i>c</i>) = <i>a</i> - <i>b</i>.</p>
-
-<p class="no-indent">Again, if <i>c</i> be less than <i>a</i> and <i>b</i>,</p>
-
-<p class="f110">(<i>a</i> - <i>c</i>) - (<i>b</i> - <i>c</i>) = <i>a</i> - <i>b</i>.</p>
-
-<p>The brackets cannot be here removed as in (36). That is, <i>p</i>-
-(<i>q</i>-<i>r</i>) is not the same thing as <i>p</i>-<i>q</i>-
-<i>r</i>. For, in the first, the difference of <i>q</i> and <i>r</i> is
-subtracted from <i>p</i>; but in the second, first <i>q</i> and then
-<i>r</i> are subtracted from <i>p</i>, which is the same as subtracting
-as much as <i>q</i> and <i>r</i> together, or <i>q</i> + <i>r</i>.
-Therefore <i>p</i>-<i>q</i>-<i>r</i> is <i>p</i>-(<i>q</i> +
-<i>r</i>). In order to shew how to remove the brackets from <i>p</i>
--(<i>q</i>-<i>r</i>) without altering the value of the result, let
-us take the simple instance 12-(8-5). If we subtract 8 from 12, or
-form 12-8, we subtract too much; because it is not 8 which is to be
-taken away, but as much of 8 as is left after diminishing it by 5. In
-forming 12-8 we have therefore subtracted 5 too much. This must be
-set right by adding 5 to the result, which gives 12-8 + 5 for the
-value of 12-(8-5). The same reasoning applies to every case, and we
-have therefore,</p>
-
-<p class="f110"><i>p</i> - (<i>q</i> + <i>r</i>) = <i>p</i> - <i>q</i> - <i>r</i>.<br />
-<i>p</i> - (<i>q</i> - <i>r</i>) = <i>p</i> - <i>q</i> + <i>r</i>.</p>
-
-<p><span class="pagenum" id="Page_21">[Pg 21]</span></p>
-
-<p class="no-indent">By the same kind of reasoning,</p>
-
-<p class="f110 no-wrap"><i>a</i> - (<i>b</i> + <i>c</i> - <i>d</i> - <i>e</i>) = <i>a</i> - <i>b</i> - <i>c</i> + <i>d</i> + <i>e</i>.<br />
-2<i>a</i> + 3<i>b</i> - (<i>a</i> - 2<i>b</i>) = 2<i>a</i> + 3<i>b</i> - <i>a</i> + 2<i>b</i> = <i>a</i> + 5<i>b</i>.<br />
-4<i>x</i> + <i>y</i> - (17<i>x</i> - 9<i>y</i>) = 4<i>x</i> + <i>y</i> - 17<i>x</i> + 9<i>y</i> = 10<i>y</i> - 13<i>x</i>.</p>
-
-<p>42. I want to find the difference of the numbers 57762 and 34631. Take
-these to pieces as in (29) and</p>
-
-<p class="f110">57762 is 5 ten-th. 7 th. 7 hund. 6 tens and 2 units.</p>
-<p class="f110">34631 is 3 ten-th. 4 th. 6 hund. 3 tens and 1 unit.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl">Now 2 units exceed</td>
- <td class="tdl">1 unit</td>
- <td class="tdl">by 1 unit.</td>
- </tr><tr>
- <td class="tdl_ws2">6 tens</td>
- <td class="tdl">3 tens</td>
- <td class="tdl_ws1">3 tens.</td>
- </tr><tr>
- <td class="tdl_ws2">7 hundreds</td>
- <td class="tdl">6 hundreds</td>
- <td class="tdl_ws1">1 hundred.</td>
- </tr><tr>
- <td class="tdl_ws2">7 thousands</td>
- <td class="tdl">4 thousands</td>
- <td class="tdl_ws1">3 thousands.</td>
- </tr><tr>
- <td class="tdl_ws2">5 ten-thousands&emsp;&nbsp;</td>
- <td class="tdl">3 ten-thous.</td>
- <td class="tdl_ws1">2 ten-thous.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Therefore, by (40, Principle II.) all the first column <i>together</i>
-exceeds all the second column by all the third column, that is, by</p>
-
-<p class="f110">2 ten-th. 3 th. 1 hund. 3 tens and 1 unit,</p>
-
-<p class="no-indent">which is 23131. Therefore the difference of 57762 and 34631 is 23131,
-or 57762-34631 = 23131.</p>
-
-<p>43. Suppose I want to find the difference between 61274 and 39628.
-Write them at length, and</p>
-
-<p class="f110">61274 is 6 ten-th. 1 th. 2 hund. 7 tens and 4 units.<br />
-39628 is 3 ten-th. 9 th. 6 hund. 2 tens and 8 units.</p>
-
-<p>If we attempt to do the same as in the last article, there is a
-difficulty immediately, since 8, being greater than 4, cannot be
-taken from it. But from (40) it appears that we shall not alter the
-difference of two numbers if we add the same number to <i>both</i>
-of them. Add ten to the first number, that is, let there be 14 units
-instead of four, and add ten also to the second number, but instead of
-adding ten to the number of units, add one to the number of tens, which
-is the same thing. The numbers will then stand thus,</p>
-
-<p class="f110">6 ten-thous. 1 thous. 2 hund. 7 tens and 14 <i>units</i>.<a id="FNanchor_7" href="#Footnote_7" class="fnanchor">[7]</a>
-3 ten-thous. 9 thous. 6 hund. 3 <i>tens</i> and 8 units.</p>
-
-<p><span class="pagenum" id="Page_22">[Pg 22]</span>
-You now see that the units and tens in the lower can be subtracted from
-those in the upper line, but that the hundreds cannot. To remedy this,
-add one thousand or 10 hundred to both numbers, which will not alter
-their difference, and remember to increase the hundreds in the upper
-line by 10, and the thousands in the lower line by 1, which are the
-same things. And since the thousands in the lower cannot be subtracted
-from the thousands in the upper line, add 1 ten thousand or 10 thousand
-to both numbers, and increase the thousands in the upper line by 10,
-and the ten thousands in the lower line by 1, which are the same
-things; and at the close the numbers which we get will be,</p>
-
-<p class="f110">6 ten-thous. 11 <i>thous.</i> 12 <i>hund.</i> 7 tens and 14 <i>units</i>.<br />
-4 <i>ten-thous.</i> 10 <i>thous.</i> 6 hund. 3 <i>tens</i> and 8 units.</p>
-
-<p>These numbers are not, it is true, the same as those given at the
-beginning of this article, but their difference is the same, by (40).
-With the last-mentioned numbers proceed in the same way as in (42),
-which will give, as their difference,</p>
-
-<p class="f110">2 ten-thous. 1 thous. 6 hund. 4 tens, and 6 units, which is 21646.</p>
-
-<p>44. From this we deduce the following rules for subtraction:</p>
-
-<div class="blockquot">
-<p>I. Write the number which is <i>to be subtracted</i> (which is, of
-course, the lesser of the two, and is called the <i>subtrahend</i>)
-under the other, so that its units shall fall under the units of the
-other, and so on.</p>
-
-<p>II. Subtract each figure of the lower line from the one above it, if
-that can be done. Where that cannot be done, add ten to the upper
-figure, and then subtract the lower figure; but recollect in this case
-always to increase the next figure in the lower line by 1, before you
-begin to subtract it from the upper one.</p>
-</div>
-
-<p>45. If there should not be as many figures in the lower line as in
-the upper one, proceed as if there were as many ciphers at the beginning
-of the lower line as will make the number of figures equal. You
-do not alter a number by placing ciphers at the beginning of it. For
-example, 00818 is the same number as 818, for it means</p>
-
-<p class="f110">0 ten-thous. 0 thous. 8 hunds. 1 ten and 8 units;</p>
-
-<p class="no-indent"><span class="pagenum" id="Page_23">[Pg 23]</span>
-the first two signs are nothing, and the rest is</p>
-
-<p class="f110">8 hundreds, 1 ten, and 8 units, or 818.</p>
-
-<p>The second does not differ from the first, except in its being said
-that there are no thousands and no tens of thousands in the number,
-which may be known without their being mentioned at all. You may ask,
-perhaps, why this does not apply to a cipher placed in the middle of
-a number, or at the right of it, as, for example, in 28007 and 39700?
-But you must recollect, that if it were not for the two ciphers in the
-first, the 8 would be taken for 8 tens, instead of 8 thousands; and if
-it were not for the ciphers in the second, the 7 would be taken for 7
-units, instead of 7 hundreds.</p>
-
-<p class="center space-above1">46. EXAMPLE.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">What is the difference between&emsp;&nbsp;</td>
- <td class="tdr">3708291640030174</td>
- </tr><tr>
- <td class="tdr">and&emsp;&nbsp;</td>
- <td class="tdr bb">30813649276188</td>
- </tr><tr>
- <td class="tdr">Difference&emsp;&nbsp;</td>
- <td class="tdr">3677477990753986</td>
- </tr>
- </tbody>
-</table>
-
-<p class="center space-above2">EXERCISES.</p>
-
-<p>I. What is 18337 + 149263200 - 6472902?&mdash;<i>Answer</i> 142808635.</p>
-<p class="big_indent">What is 1000 - 464 + 3279 - 646?&mdash;<i>Ans.</i> 3169.</p>
-
-<p>II. Subtract</p>
-
-<p class="f110 no-wrap">64 + 76 + 144 - 18 from 33 - 2 + 100037.&mdash;<i>Ans.</i> 99802.</p>
-
-<p>III. What shorter rule might be made for subtraction when all the figures
-in the upper line are ciphers except the first? for example, in finding</p>
-
-<p class="f110">10000000 - 2731634.</p>
-
-<p>IV. Find 18362 + 2469 and 18362-2469, add the second result to the
-first, and then subtract 18362; subtract the second from the first, and
-then subtract 2469.&mdash;<i>Answer</i> 18362 and 2469.</p>
-
-<p>V. There are four places on the same line in the order <span class="allsmcap">a</span>,
-<span class="allsmcap">b</span>, <span class="allsmcap">c</span>, and <span class="allsmcap">d</span>. From <span class="allsmcap">a</span> to <span class="allsmcap">d</span>
-it is 1463 miles; from <span class="allsmcap">a</span> to <span class="allsmcap">c</span> it is 728 miles; and
-from <span class="allsmcap">b</span> to <span class="allsmcap">d</span> it is 1317 miles. How far is it from
-<span class="allsmcap">a</span> to <span class="allsmcap">b</span>, from <span class="allsmcap">b</span> to <span class="allsmcap">c</span>, and from
-<span class="allsmcap">c</span> to <span class="allsmcap">d</span>?&mdash;<i>Answer.</i> From <span class="allsmcap">a</span> to <span class="allsmcap">b</span>
-146, from <span class="allsmcap">b</span> to <span class="allsmcap">c</span> 582, and from <span class="allsmcap">c</span> to
-<span class="allsmcap">d</span> 735 miles.</p>
-
-<p><span class="pagenum" id="Page_24">[Pg 24]</span>
-VI. In the following table subtract <span class="allsmcap">b</span> from <span class="allsmcap">a</span>, and
-<span class="allsmcap">b</span> from the remainder, and so on until <span class="allsmcap">b</span> can be no
-longer subtracted. Find how many times <span class="allsmcap">b</span> can be subtracted
-from <span class="allsmcap">a</span>, and what is the last remainder.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <thead><tr>
- <th class="tdc"><big>&nbsp;&nbsp;A</big></th>
- <th class="tdc"><big>&nbsp;&nbsp;B</big></th>
- <th class="tdc">&nbsp;No. of&nbsp;<br />times.</th>
- <th class="tdc">&nbsp;Remainder.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdr">23604</td>
- <td class="tdr">9999</td>
- <td class="tdc">2</td>
- <td class="tdr">3606</td>
- </tr><tr>
- <td class="tdr">209961</td>
- <td class="tdr">37173</td>
- <td class="tdc">5</td>
- <td class="tdr">24096</td>
- </tr><tr>
- <td class="tdr">74712</td>
- <td class="tdr">6792</td>
- <td class="tdc">11</td>
- <td class="tdr">0</td>
- </tr><tr>
- <td class="tdr">4802469</td>
- <td class="tdr">654321</td>
- <td class="tdc">7</td>
- <td class="tdr">222222</td>
- </tr><tr>
- <td class="tdr">18849747</td>
- <td class="tdr">3141592</td>
- <td class="tdc">6</td>
- <td class="tdr">195</td>
- </tr><tr>
- <td class="tdr">987654321</td>
- <td class="tdr">&nbsp;&nbsp;123456789</td>
- <td class="tdc">8</td>
- <td class="tdr">9</td>
- </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="SECTION_III">SECTION III.<br />
-<span class="h_subtitle">MULTIPLICATION.</span></h3>
-</div>
-
-<p>47. I have said that all questions in arithmetic require nothing but
-addition and subtraction. I do not mean by this that no rule should
-ever be used except those given in the last section, but that all
-other rules only shew shorter ways of finding what might be found,
-if we pleased, by the methods there deduced. Even the last two rules
-themselves are only short and convenient ways of doing what may be done
-with a number of pebbles or counters.</p>
-
-<p>48. I want to know the sum of five seventeens, or I ask the following
-question: There are five heaps of pebbles, and seventeen pebbles in
-each heap; how many are there in all? Write five seventeens in a
-column, and make the addition, which gives 85. In this case 85 is
-called the <i>product</i> of 5 and 17, and the process of finding the
-product is called <span class="smcap">multiplication</span>, which gives nothing more
-than the addition of a number of the same quantities. Here 17 is called
-the <i>multiplicand</i>, and 5 is called the <i>multiplier</i>.</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">17</li>
-<li class="isub3">17</li>
-<li class="isub3">17</li>
-<li class="isub3">17</li>
-<li class="isub3 u">17</li>
-<li class="isub3">85</li>
-</ul>
-
-<p>49. If no question harder than this were ever proposed, there would be
-no occasion for a shorter way than the one here followed. But if there
-<span class="pagenum" id="Page_25">[Pg 25]</span>
-were 1367 heaps of pebbles, and 429 in each heap, the whole number is
-then 1367 times 429, or 429 multiplied by 1367. I should have to write
-429 1367 times, and then to make an addition of enormous length. To
-avoid this, a shorter rule is necessary, which I now proceed to explain.</p>
-
-<p>50. The student must first make himself acquainted with the products of
-all numbers as far as 10 times 10 by means of the following table,<a id="FNanchor_8" href="#Footnote_8" class="fnanchor">[8]</a>
-which must be committed to memory.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" rules="cols">
- <tbody><tr>
- <td class="tdc bb" colspan="12">&nbsp;</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;1</td> <td class="tdc bb">&nbsp;2</td>
- <td class="tdc bb">&nbsp;3</td> <td class="tdc bb">&nbsp;4</td>
- <td class="tdc bb">&nbsp;5</td> <td class="tdc bb">&nbsp;6</td>
- <td class="tdc bb">&nbsp;7</td> <td class="tdc bb">&nbsp;8</td>
- <td class="tdc bb">9</td> <td class="tdc bb">10</td>
- <td class="tdc bb">11</td> <td class="tdc bb">12</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;2</td> <td class="tdc bb">&nbsp;4</td>
- <td class="tdc bb">&nbsp;6</td> <td class="tdc bb">&nbsp;8</td>
- <td class="tdc bb">10</td> <td class="tdc bb">12</td>
- <td class="tdc bb">14</td> <td class="tdc bb">16</td>
- <td class="tdc bb">18</td> <td class="tdc bb">20</td>
- <td class="tdc bb">22</td> <td class="tdc bb">24</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;3</td> <td class="tdc bb">&nbsp;6</td>
- <td class="tdc bb">&nbsp;9</td> <td class="tdc bb">12</td>
- <td class="tdc bb">15</td> <td class="tdc bb">18</td>
- <td class="tdc bb">21</td> <td class="tdc bb">24</td>
- <td class="tdc bb">27</td> <td class="tdc bb">30</td>
- <td class="tdc bb">33</td> <td class="tdc bb">36</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;4</td> <td class="tdc bb">&nbsp;8</td>
- <td class="tdc bb">12</td> <td class="tdc bb">16</td>
- <td class="tdc bb">20</td> <td class="tdc bb">24</td>
- <td class="tdc bb">28</td> <td class="tdc bb">32</td>
- <td class="tdc bb">36</td> <td class="tdc bb">40</td>
- <td class="tdc bb">44</td> <td class="tdc bb">48</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;5</td> <td class="tdc bb">10</td>
- <td class="tdc bb">15</td> <td class="tdc bb">20</td>
- <td class="tdc bb">25</td> <td class="tdc bb">30</td>
- <td class="tdc bb">35</td> <td class="tdc bb">40</td>
- <td class="tdc bb">45</td> <td class="tdc bb">50</td>
- <td class="tdc bb">55</td> <td class="tdc bb">60</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;6</td> <td class="tdc bb">12</td>
- <td class="tdc bb">18</td> <td class="tdc bb">24</td>
- <td class="tdc bb">30</td> <td class="tdc bb">36</td>
- <td class="tdc bb">42</td> <td class="tdc bb">48</td>
- <td class="tdc bb">54</td> <td class="tdc bb">60</td>
- <td class="tdc bb">66</td> <td class="tdc bb">72</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;7</td> <td class="tdc bb">14</td>
- <td class="tdc bb">21</td> <td class="tdc bb">28</td>
- <td class="tdc bb">35</td> <td class="tdc bb">42</td>
- <td class="tdc bb">49</td> <td class="tdc bb">56</td>
- <td class="tdc bb">63</td> <td class="tdc bb">70</td>
- <td class="tdc bb">77</td> <td class="tdc bb">84</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;8</td> <td class="tdc bb">16</td>
- <td class="tdc bb">24</td> <td class="tdc bb">32</td>
- <td class="tdc bb">40</td> <td class="tdc bb">48</td>
- <td class="tdc bb">56</td> <td class="tdc bb">64</td>
- <td class="tdc bb">72</td> <td class="tdc bb">80</td>
- <td class="tdc bb">88</td> <td class="tdc bb">96</td>
- </tr><tr>
- <td class="tdc bb">&nbsp;9</td> <td class="tdc bb">18</td>
- <td class="tdc bb">27</td> <td class="tdc bb">36</td>
- <td class="tdc bb">45</td> <td class="tdc bb">54</td>
- <td class="tdc bb">63</td> <td class="tdc bb">72</td>
- <td class="tdc bb">81</td> <td class="tdc bb">90</td>
- <td class="tdc bb">99</td> <td class="tdc bb">108</td>
- </tr><tr>
- <td class="tdc bb">10</td> <td class="tdc bb">20</td>
- <td class="tdc bb">30</td> <td class="tdc bb">40</td>
- <td class="tdc bb">50</td> <td class="tdc bb">60</td>
- <td class="tdc bb">70</td> <td class="tdc bb">80</td>
- <td class="tdc bb">90</td> <td class="tdc bb">100</td>
- <td class="tdc bb">110</td> <td class="tdc bb">120</td>
- </tr><tr>
- <td class="tdc bb">11</td> <td class="tdc bb">22</td>
- <td class="tdc bb">33</td> <td class="tdc bb">44</td>
- <td class="tdc bb">55</td> <td class="tdc bb">66</td>
- <td class="tdc bb">77</td> <td class="tdc bb">88</td>
- <td class="tdc bb">99</td> <td class="tdc bb">110</td>
- <td class="tdc bb">121</td> <td class="tdc bb">132</td>
- </tr><tr>
- <td class="tdc bb">12</td> <td class="tdc bb">24</td>
- <td class="tdc bb">36</td> <td class="tdc bb">48</td>
- <td class="tdc bb">60</td> <td class="tdc bb">72</td>
- <td class="tdc bb">84</td> <td class="tdc bb">96</td>
- <td class="tdc bb">108</td> <td class="tdc bb">120</td>
- <td class="tdc bb">132</td> <td class="tdc bb">144</td>
- </tr><tr>
- <td class="tdc bt" colspan="12">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>If from this table you wish to know what is 7 times 6, look in the
-first upright column on the left for either of them; 6 for example.
-Proceed to the right until you come into the column marked 7 at the
-top. You there find 42, which is the product of 6 and 7.</p>
-
-<p>51. You may find, in this way, either 6 times 7, or 7 times 6, and for
-both you find 42. That is, six sevens is the same number as seven sixes.
-<span class="pagenum" id="Page_26">[Pg 26]</span>
-This may be shewn as follows: Place seven counters in a line, and
-repeat that line in all six times. The number of counters in the whole
-is 6 times 7, or six sevens, if I reckon the rows from the top to the
-bottom; but if I count the rows that stand side by side, I find seven
-of them, and six in each row, the whole number of which is 7 times 6,
-or seven sixes. And the whole number is 42, whichever way I count. The
-same method may be applied to any other two numbers. If the signs of
-(23) were used, it would be said that 7 × 6 = 6 × 7.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="6" summary=" " cellpadding="6" >
- <tbody><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr>
- </tbody>
-</table>
-
-<p>52. To take any quantity a number of times, it will be enough to take
-every one of its parts the same number of times. Thus, a sack of corn
-will be increased fifty-fold, if each bushel which it contains be
-replaced by 50 bushels. A country will be doubled by doubling every
-acre of land, or every county, which it contains. Simple as this
-may appear, it is necessary to state it, because it is one of the
-principles on which the rule of multiplication depends.</p>
-
-<p>53. In order to multiply by any number, you may multiply separately
-by any parts into which you choose to divide that number, and add the
-results. For example, 4 and 2 make 6. To multiply 7 by 6 first multiply
-7 by 4, and then by 2, and add the products. This will give 42, which
-is the product of 7 and 6. Again, since 57 is made up of 32 and 25, 57
-times 50 is made up of 32 times 50 and 25 times 50, and so on. If the
-signs were used, these would be written thus:</p>
-
-<p class="f110">7 × 6 = 7 × 4 + 7 × 2.<br />
-&nbsp; 50 × 57 = 50 × 32 + 50 × 25.</p>
-
-<p>54. The principles in the last two articles may be expressed thus: If
-<i>a</i> be made up of the parts <i>x</i>, <i>y</i>, and <i>x</i>,
-<i>ma</i> is made up of <i>mx</i>, <i>my</i>, and <i>mz</i>; or,</p>
-
-<p class="f110">if<span class="ws2"><i>a</i> = <i>x</i> + <i>y</i> + <i>z</i>.</span></p>
-<p class="f110"><i>ma</i> = <i>mx</i> + <i>my</i> + <i>mz</i>,</p>
-<p class="f110">or,<span class="ws2"><i>m</i>(<i>x</i> + <i>y</i> + <i>z</i>) = <i>mx</i> + <i>my</i> + <i>mz</i>.</span></p>
-
-<p><span class="pagenum" id="Page_27">[Pg 27]</span>
-A similar result may be obtained if <i>a</i>, instead of being made
-up of <i>x</i>, <i>y</i>, and <i>z</i>, is made by combined additions
-and subtractions, such as <i>x</i> + <i>y</i>-<i>z</i>, <i>x</i>-
-<i>y</i> + <i>z</i>, <i>x</i>-<i>y</i>-<i>z</i>, &amp;c. To take the
-first as an instance:</p>
-
-<p class="f110">Let<span class="ws4"><i>a</i> = <i>x</i> + <i>y</i> - <i>z</i>,</span></p>
-<p class="f110">then<span class="ws2"><i>ma</i> = <i>mx</i> + <i>my</i> - <i>mz</i>.</span></p>
-
-<p>For, if <i>a</i> had been <i>x</i> + <i>y</i>, <i>ma</i> would have
-been <i>mx</i> + <i>my</i>. But since <i>a</i> is less than <i>x</i>
-+ <i>y</i> by <i>z</i>, too much by <i>z</i> has been repeated every
-time that <i>x</i> + <i>y</i> has been repeated;&mdash;that is, <i>mz</i>
-too much has been taken; consequently, <i>ma</i> is not <i>mx</i> +
-<i>my</i>, but <i>mx</i> + <i>my</i>-<i>mz</i>. Similar reasoning may
-be applied to other cases, and the following results may be obtained:</p>
-
-<p class="f110 no-wrap"><i>m</i>(<i>a</i> + <i>b</i> + <i>c</i> - <i>d</i>) = <i>ma</i> + <i>mb</i> + <i>mc</i> - <i>md</i>.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr"><i>a</i>(<i>a</i> - <i>b</i>)</td>
- <td class="tdc">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdl"><i>aa</i> - <i>ab</i>.</td>
- </tr><tr>
- <td class="tdr"><i>b</i>(<i>a</i> - <i>b</i>)</td>
- <td class="tdc">=</td>
- <td class="tdl"><i>ba</i> - <i>bb</i>.</td>
- </tr><tr>
- <td class="tdr">3(2<i>a</i> - 4<i>b</i>)</td>
- <td class="tdc">=</td>
- <td class="tdl">6<i>a</i> - 12<i>b</i>.</td>
- </tr><tr>
- <td class="tdr">7<i>a</i>(7 + 2<i>b</i>)</td>
- <td class="tdc">=</td>
- <td class="tdl">49<i>a</i> + 14<i>ab</i>.</td>
- </tr><tr>
- <td class="tdr">(<i>aa</i> + <i>a</i> + 1)<i>a</i></td>
- <td class="tdc">=</td>
- <td class="tdl"><i>aaa</i> + <i>aa</i> + <i>a</i>.</td>
- </tr><tr>
- <td class="tdr">(3<i>ab</i> - 2<i>c</i>)4<i>abc</i></td>
- <td class="tdc">=</td>
- <td class="tdl">12<i>aabbc</i> - 8<i>abcc</i>.</td>
- </tr>
- </tbody>
-</table>
-
-<p>55. There is another way in which two numbers may be multiplied
-together. Since 8 is 4 times 2, 7 times 8 may be made by multiplying
-7 and 4, and then multiplying that <i>product</i> by 2. To shew this,
-place 7 counters in a line, and repeat that line in all 8 times, as in
-figures I. and II.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc fontsize_150" colspan="8"><b>I.</b></td>
- </tr><tr>
- <td class="tdc fontsize_150" rowspan="4"><b>A</b>&nbsp;</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdc fontsize_150" rowspan="4"><b>B</b>&nbsp;</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr>
- </tbody>
-</table>
-<p class="space-above2">&nbsp;</p>
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc fontsize_150" colspan="7"><b>II.</b></td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc" colspan="7">&nbsp;</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc" colspan="7">&nbsp;</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc" colspan="7">&nbsp;</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr><tr>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td> <td class="tdc">●</td>
- <td class="tdc">●</td>
- </tr>
- </tbody>
-</table>
-
-<p>The number of counters in all is 8 times 7, or 56. But (as in fig. I.)
-enclose each four rows in oblong figures, such as <span class="allsmcap">a</span>
-<span class="pagenum" id="Page_28">[Pg 28]</span>
-and <span class="allsmcap">b</span>. The number in each oblong is
-4 times 7, or 28, and there are two of those oblongs; so that in
-the whole the number of counters is twice 28, or 28 x 2, or 7 first
-multiplied by 4, and that product multiplied by 2. In figure II. it
-is shewn that 7 multiplied by 8 is also 7 first multiplied by 2, and
-that product multiplied by 4. The same method may be applied to other
-numbers. Thus, since 80 is 8 times 10, 256 times 80 is 256 multiplied
-by 8, and that product multiplied by 10. If we use the signs, the
-foregoing assertions are made thus:</p>
-
-<p class="f120 no-wrap">7 × 8 =&nbsp; &nbsp;7 × 4 × 2&nbsp; = 7 × 2 × 4.<br />
-256 × 80 = 256 × 8 × 10 = 256 × 10 × 8.</p>
-
-<p class="center space-above2">EXERCISES.</p>
-
-<p>Shew that 2 × 3 × 4 × 5 = 2 × 4 × 3 × 5 = 5 × 4 × 2 × 3, &amp;c.</p>
-
-<p>Shew that 18 × 100 = 18 × 57 + 18 × 43.</p>
-
-<p class="space-above1">56. Articles (51) and (55) may be expressed in
-the following way, where by <i>ab</i> we mean <i>a</i> taken <i>b</i>
-times; by <i>abc</i>, <i>a</i> taken <i>b</i> times, and the result
-taken <i>c</i> times.</p>
-
-<p class="f110"><i>ab</i> = <i>ba</i>.&emsp;&nbsp;<br />
-<i>abc</i> = <i>acb</i> = <i>bca</i> = <i>bac</i>, &amp;c.<br />
-<i>abc</i> = <i>a</i> × (<i>bc</i>) = <i>b</i> × (<i>ca</i>) = <i>c</i> × (<i>ab</i>).</p>
-
-<p>If we would say that the same results are produced by multiplying by
-<i>b</i>, <i>c</i>, and <i>d</i>, one after the other, and by the
-product <i>bcd</i> at once, we write the following:</p>
-
-<p class="f110"><i>a</i> × <i>b</i> × <i>c</i> × <i>d</i> = <i>a</i> × <i>bcd</i>.</p>
-
-<p>The fact is, that if any numbers are to be multiplied together, the
-product of any two or more may be formed, and substituted instead of
-those two or more; thus, the product <i>abcdef</i> may be formed by
-multiplying</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc">&nbsp;<i>ab</i></td>
- <td class="tdc"><i>cde</i></td>
- <td class="tdc"><i>f</i></td>
- </tr><tr>
- <td class="tdc"><i>abf</i></td>
- <td class="tdc">&nbsp;<i>de</i></td>
- <td class="tdc"><i>c</i></td>
- </tr><tr>
- <td class="tdc"><i>abc</i></td>
- <td class="tdc"><i>def</i></td>
- <td class="tdc">&amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p>57. In order to multiply by 10, annex a cipher to the right hand of the
-multiplicand. Thus, 10 times 2356 is 23560. To shew this, write 2356 at
-length which is
-<span class="pagenum" id="Page_29">[Pg 29]</span></p>
-
-<p class="f110">2 thousands, 3 hundreds, 5 tens, and 6 units.</p>
-
-<p class="no-indent">Take each of these parts ten times, which, by
-(52), is the same as multiplying the whole number by 10, and it will
-then become</p>
-
-<p class="f110">2 tens of thou. 3 tens of hun. 5 tens of tens, and 6 tens,</p>
-
-<p class="no-indent">which is</p>
-
-<p class="f110">2 ten-thou. 3 thous. 5 hun. and 6 tens.</p>
-
-<p class="no-indent">This must be written 23560, because 6 is not to be
-6 units, but 6 tens. Therefore 2356 × 10 = 23560.</p>
-
-<p>In the same way you may shew, that in order to multiply by 100 you
-must affix two ciphers to the right; to multiply by 1000 you must
-affix three ciphers, and so on. The rule will be best caught from the
-following table:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">13 ×</td>
- <td class="tdr_ws1">10 =</td>
- <td class="tdr_ws1">130</td>
- </tr><tr>
- <td class="tdr">13 ×</td>
- <td class="tdr_ws1">100 =</td>
- <td class="tdr_ws1">1300</td>
- </tr><tr>
- <td class="tdr">13 ×</td>
- <td class="tdr_ws1">1000 =</td>
- <td class="tdr_ws1">13000</td>
- </tr><tr>
- <td class="tdr">13 ×</td>
- <td class="tdr_ws1">10000 =</td>
- <td class="tdr_ws1">130000</td>
- </tr><tr>
- <td class="tdr">142 ×</td>
- <td class="tdr_ws1">1000 =</td>
- <td class="tdr_ws1">142000</td>
- </tr><tr>
- <td class="tdr">23700 ×</td>
- <td class="tdr_ws1">10 =</td>
- <td class="tdr_ws1">237000</td>
- </tr><tr>
- <td class="tdr">3040 ×</td>
- <td class="tdr_ws1">1000 =</td>
- <td class="tdr_ws1">3040000</td>
- </tr><tr>
- <td class="tdr">10000 ×</td>
- <td class="tdr_ws1">100000 =</td>
- <td class="tdr_ws1">1000000000</td>
- </tr>
- </tbody>
-</table>
-
-<p>58. I now shew how to multiply by one of the numbers, 2, 3, 4, 5, 6, 7,
-8, or 9. I do not include 1, because multiplying by 1, or taking the
-number once, is what is meant by simply writing down the number. I want
-to multiply 1368 by 8. Write the first number at full length, which is</p>
-
-<p class="f110">1 thousand, 3 hundreds, 6 tens, and 8 units.</p>
-
-<p>To multiply this by 8, multiply each of these parts by 8 (50) and (52),
-which will give</p>
-
-<p class="f110">8 thousands, 24 hundreds, 48 tens, and 64 units.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdl">Now</td>
- <td class="tdl_ws1">64 units are written thus</td>
- <td class="tdr">64</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1">48 tens</td>
- <td class="tdr">480</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1">24 hundreds</td>
- <td class="tdr">2400</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;8 thousands</td>
- <td class="tdr">8000</td>
- </tr>
-</tbody>
-</table>
-
-<p class="no-indent">Add these together, which gives 10944 as the
-product of 1368 and 8, or 1368 × 8 = 10944. By working a few examples
-in this way you will see for following rule.
-<span class="pagenum" id="Page_30">[Pg 30]</span></p>
-
-<p>59. I. Multiply the first figure of the multiplicand by the multiplier,
-write down the units’ figure, and reserve the tens.</p>
-
-<p>II. Do the same with the second figure of the multiplicand, and add
-to the product the number of tens from the first; put down the units’
-figure of this, and reserve the tens.</p>
-
-<p>III. Proceed in this way till you come to the last figure, and then
-write down the whole number obtained from that figure.</p>
-
-<p>IV. If there be a cipher in the multiplicand, treat it as if it were a
-number, observing that 0 × 1 = 0, 0 × 2 = 0, &amp;c.</p>
-
-<p>60. In a similar way a number can be multiplied by a figure which is
-accompanied by ciphers, as, for example, 8000. For 8000 is 8 × 1000,
-and therefore (55) you must first multiply by 8 and then by 1000, which
-last operation (57) is done by placing 3 ciphers on the right. Hence
-the rule in this case is, multiply by the simple number, and place the
-number of ciphers which follow it at the right of the product.</p>
-
-<p class="f120 space-above1">EXAMPLE.</p>
-
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">Multiply</td>
- <td class="tdl_ws1">1679423800872</td>
- </tr><tr>
- <td class="tdc">by</td>
- <td class="tdl_ws1 bb2"><span class="ws6">60000</span></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">100765428052320000</td>
- </tr>
-</tbody>
-</table>
-
-<p class="f120 space-above1">61. EXERCISES.</p>
-
-<p>What is 1007360 × 7?&nbsp;&nbsp;&nbsp;<i>Answer</i>, 7051520.</p>
-
-<p>123456789 × 9 + 10 and 123 × 9 + 4?&mdash;<i>Ans.</i> 1111111111 and 1111.</p>
-<p>What is 136 × 3 + 129 × 4 + 147 × 8 + 27 × 3000?&mdash;<i>Ans.</i> 83100.</p>
-
-<p>An army is made up of 33 regiments of infantry, each containing 800
-men; 14 of cavalry, each containing 600 men; and 2 of artillery, each
-containing 300 men. The enemy has 6 more regiments of infantry, each
-containing 100 more men; 3 more regiments of cavalry, each containing
-100 men less; and 4 corps of artillery of the same magnitude as those
-of the first: two regiments of cavalry and one of infantry desert from
-the former to the latter. How many men has the second army more than
-the first?&mdash;<i>Answer</i>, 13400.
-<span class="pagenum" id="Page_31">[Pg 31]</span></p>
-
-<p class="space-above1">62. Suppose it is required to multiply 23707 by
-4567. Since 4567 is made up of 4000, 500, 60, and 7, by (53) we must
-multiply 23707 by each of these, and add the products.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">Now (58)</td>
- <td class="tdl_ws1">23707 ×</td>
- <td class="tdr_ws1">7</td>
- <td class="tdc">&nbsp;is&nbsp;</td>
- <td class="tdr_ws1">165949</td>
- </tr><tr>
- <td class="tdr">(60)</td>
- <td class="tdl_ws1">23707 ×</td>
- <td class="tdr_ws1">60</td>
- <td class="tdc">is</td>
- <td class="tdr_ws1">1422420</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">23707 ×</td>
- <td class="tdr_ws1">500</td>
- <td class="tdc">is</td>
- <td class="tdr_ws1">11853500</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">23707 ×</td>
- <td class="tdr_ws1">4000</td>
- <td class="tdc">is</td>
- <td class="tdr_ws1">94828000</td>
- </tr><tr>
- <td class="tdr" colspan="3">The sum of these</td>
- <td class="tdc">is</td>
- <td class="tdr_ws1 bt2">108269869</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which is the product required.</p>
-
-<p>It will do as well if, instead of writing the ciphers at the end of
-each line, we keep the other figures in their places without them. If
-we take away the ciphers, the second line is one place to the left of
-the first, the third one place to the left of the second, and so on.
-Write the multiplier and the multiplicand over these lines, and the
-process will stand thus:</p>
-
-<ul class="index fontsize_120">
-<li class="isub5">23707</li>
-<li class="isub5 u">&nbsp;4567</li>
-<li class="isub4">165949</li>
-<li class="isub3">142242</li>
-<li class="isub2">118535</li>
-<li class="isub2">94828</li>
-<li class="isub1 over">108269869</li>
-</ul>
-
-<p>63. There is one more case to be noticed; that is, where there is a
-cipher in the middle of the multiplier. The following example will shew
-that in this case nothing more is necessary than to keep the first
-figure of each line in the column under the figure of the multiplier
-from which that line arises. Suppose it required to multiply 365 by
-101001. The multiplier is made up of 100000, 1000 and 1. Proceed as
-before, and</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">365 × 1</td>
- <td class="tdc">&nbsp;is&nbsp;</td>
- <td class="tdr_ws1">365</td>
- </tr><tr>
- <td class="tdr">(57)</td>
- <td class="tdl_ws1">365 × 1000</td>
- <td class="tdc">&nbsp;is&nbsp;</td>
- <td class="tdr_ws1">365000</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">365 × 100000</td>
- <td class="tdc">&nbsp;is&nbsp;</td>
- <td class="tdr_ws1">36500000</td>
- </tr><tr>
- <td class="tdr" colspan="2">The sum of which</td>
- <td class="tdc">&nbsp;is&nbsp;</td>
- <td class="tdr_ws1 over">36865365</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and the whole process with the ciphers struck off is:</p>
-
-<ul class="index fontsize_120">
-<li class="isub4">&nbsp;365</li>
-<li class="isub3 u">101001</li>
-<li class="isub4">&nbsp;365</li>
-<li class="isub3">365</li>
-<li class="isub1">&nbsp;365</li>
-<li class="isub1 over">36865365</li>
-</ul>
-
-<p>64. The following is the rule in all cases:</p>
-
-<p>I. Place the multiplier under the multiplicand, so that the units of
-one may be under those of the other.</p>
-
-<p>II. Multiply the whole multiplicand by each figure of the multiplier
-(59), and place the unit of each line in the column under the figure of
-the multiplier from which it came.
-<span class="pagenum" id="Page_32">[Pg 32]</span></p>
-
-<p>III. Add together the lines obtained by II. column by column.</p>
-
-<p>65. When the multiplier or multiplicand, or both, have ciphers on the
-right hand, multiply the two together without the ciphers, and then
-place on the right of the product all the ciphers that are on the right
-both of the multiplier and multiplicand. For example, what is 3200 ×
-3000? First, 3200 is 32 × 100, or one hundred times as great as 32.
-Again, 32 × 13000 is 32 × 13, with three ciphers affixed, that is 416,
-with three ciphers affixed, or 416000. But the product required must
-be 100 times as great as this, or must have two ciphers affixed. It is
-therefore 41600000, having as many ciphers as are in both multiplier
-and multiplicand.</p>
-
-<p>66. When any number is multiplied by itself any number of times, the
-result is called a <i>power</i> of that number. Thus:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdl">6 is called the</td>
- <td class="tdl_ws1">first power</td>
- <td class="tdr_ws1">of 6</td>
- </tr><tr>
- <td class="tdl">6 × 6</td>
- <td class="tdl_ws1">second power</td>
- <td class="tdr_ws1">of 6</td>
- </tr><tr>
- <td class="tdl">6 × 6 × 6</td>
- <td class="tdl_ws1">third power</td>
- <td class="tdr_ws1">of 6</td>
- </tr><tr>
- <td class="tdl">6 × 6 × 6 × 6</td>
- <td class="tdl_ws1">fourth power</td>
- <td class="tdr_ws1">of 6</td>
- </tr><tr>
- <td class="tdc">&amp;c.</td>
- <td class="tdc">&amp;c.</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>The second and third powers are usually called the <i>square</i> and
-<i>cube</i>, which are incorrect names, derived from certain connexions
-of the second and third power with the square and cube in geometry. As
-exercises in multiplication, the following powers are to be found.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <thead><tr>
- <th class="tdc">Number<br />proposed.</th>
- <th class="tdc">Square.</th>
- <th class="tdc">Cube.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdc">&nbsp;972</td>
- <td class="tdr_ws1">944784</td>
- <td class="tdr_ws1">918330048</td>
- </tr><tr>
- <td class="tdc">1008</td>
- <td class="tdr_ws1">1016064</td>
- <td class="tdr_ws1">1024192512</td>
- </tr><tr>
- <td class="tdc">3142</td>
- <td class="tdr_ws1">9872164</td>
- <td class="tdr_ws1">31018339288</td>
- </tr><tr>
- <td class="tdc">3163</td>
- <td class="tdr_ws1">10004569</td>
- <td class="tdr_ws1">31644451747</td>
- </tr><tr>
- <td class="tdc">5555</td>
- <td class="tdr_ws1">30858025</td>
- <td class="tdr_ws1">171416328875</td>
- </tr><tr>
- <td class="tdc">6789</td>
- <td class="tdr_ws1">46090521</td>
- <td class="tdr_ws1">312908547069</td>
- </tr><tr>
- <td class="tdr">The fifth</td>
- <td class="tdr_ws1">power of 36 is</td>
- <td class="tdr_ws1">60466176</td>
- </tr><tr>
- <td class="tdr">fourth</td>
- <td class="tdr_ws1">50&nbsp;&nbsp;&nbsp;</td>
- <td class="tdr_ws1">6250000</td>
- </tr><tr>
- <td class="tdr">fourth</td>
- <td class="tdr_ws1">108&nbsp;&nbsp;&nbsp;</td>
- <td class="tdr_ws1">136048896</td>
- </tr><tr>
- <td class="tdr">fourth</td>
- <td class="tdr_ws1">277&nbsp;&nbsp;&nbsp;</td>
- <td class="tdr_ws1">5887339441</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_33">[Pg 33]</span>
-67. It is required to multiply <i>a</i> + <i>b</i> by <i>c</i> +
-<i>d</i>, that is, to take <i>a</i> + <i>b</i> as many times as there
-are units in <i>c</i> + <i>d</i>. By (53) <i>a</i> + <i>b</i> must be
-taken <i>c</i> times, and <i>d</i> times, or the product required is
-(<i>a</i> + <i>b</i>)<i>c</i> + (<i>a</i> + <i>b</i>)<i>d</i>. But (52)
-(<i>a</i> + <i>b</i>)<i>c</i> is <i>ac</i> + <i>bc</i>, and (<i>a</i> +
-<i>b</i>)<i>d</i> is <i>ad</i> + <i>bd</i>; whence the product required
-is <i>ac</i> + <i>bc</i> + <i>ad</i> + <i>bd</i>; or,</p>
-
-<p class="f110 no-wrap">(<i>a</i> + <i>b</i>)(<i>c</i> + <i>d</i>) = <i>ac</i> + <i>bc</i> + <i>ad</i> + <i>bd</i>.</p>
-
-<p class="no-indent">By similar reasoning</p>
-
-<p class="f110 no-wrap">(<i>a</i> - <i>b</i>)(<i>c</i> + <i>d</i>) is (<i>a</i> - <i>b</i>)<i>c</i> + (<i>a</i> - <i>b</i>)<i>d</i>; or,<br />
-(<i>a</i> - <i>b</i>)(<i>c</i> + <i>d</i>) = <i>ac</i> - <i>bc</i> + <i>ad</i> - <i>bd</i>.</p>
-
-<p>To multiply <i>a</i>-<i>b</i> by <i>c</i>-<i>d</i>, first take
-<i>a</i>-<i>b</i> <i>c</i> times, which gives <i>ac</i>-<i>bc</i>.
-This is not correct; for in taking it <i>c</i> times instead of
-<i>c</i>-<i>d</i> times, we have taken it <i>d</i> times too many;
-or have made a result which is (<i>a</i>-<i>b</i>)<i>d</i> too
-great. The real result is therefore <i>ac</i>-<i>bc</i>-(<i>a</i>
--<i>b</i>)<i>d</i>. But (<i>a</i>-<i>b</i>)<i>d</i> is <i>ad</i>-
-<i>bd</i>, and therefore</p>
-
-<p class="f110 no-wrap">(<i>a</i> - <i>b</i>)(<i>c</i> - <i>d</i>) = <i>ac</i> - <i>bc</i> - <i>ad</i> - <i>bd</i><br />
-<span class="ws8">&nbsp;</span>= <i>ac</i> - <i>bc</i> - <i>ad</i> + <i>bd</i>&emsp;&emsp;(41)</p>
-
-<p>From these three examples may be collected the following rule for
-the multiplication of algebraic quantities: Multiply each term of the
-multiplicand by each term of the multiplier; when the two terms have
-both + or both-before them, put + before their product; when one has
-+ and the other-, put-before their product. In using the first terms,
-which have no sign, apply the rule as if they had the sign +.</p>
-
-<p>68. For example, (<i>a</i> + <i>b</i>)(<i>a</i> + <i>b</i>)
-gives <i>aa</i> + <i>ab</i> + <i>ab</i> + <i>bb</i>. But <i>ab</i>
-+ <i>ab</i> is 2<i>ab</i>; hence the <i>square</i> of <i>a</i> +
-<i>b</i> is <i>aa</i> + 2<i>ab</i> + <i>bb</i>. Again (<i>a</i>-
-<i>b</i>)(<i>a</i>-<i>b</i>) gives <i>aa</i>-<i>ab</i>-<i>ab</i>
-+ <i>bb</i>. But two subtractions of <i>ab</i> are equivalent
-to subtracting 2<i>ab</i>; hence the <i>square</i> of <i>a</i>-
-<i>b</i> is <i>aa</i>-2<i>ab</i> + <i>bb</i>. Again, (<i>a</i> +
-<i>b</i>)(<i>a</i>-<i>b</i>) gives <i>aa</i> + <i>ab</i>-<i>ab</i>
--<i>bb</i>. But the addition and subtraction of <i>ab</i> makes no
-change; hence the product of <i>a</i> + <i>b</i> and <i>a</i>- <i>b</i>
-is <i>aa</i>-<i>bb</i>.</p>
-
-<p>Again, the square of <i>a</i> + <i>b</i> + <i>c</i> + <i>d</i>
-or (<i>a</i> + <i>b</i> + <i>c</i> + <i>d</i>)(<i>a</i> + <i>b</i>
-+ <i>c</i> + <i>d</i>) will be found to be <i>aa</i> + 2<i>ab</i>
-+ 2<i>ac</i> + 2<i>ad</i> + <i>bb</i> + 2<i>bc</i> + 2<i>bd</i> +
-<i>cc</i> + 2<i>cd</i> + <i>dd</i>; or the rule for squaring such
-a quantity is: Square the first term, and multiply all that come
-<i>after</i> by twice that term; do the same with the second, and so on
-to the end.</p>
-
-<p><span class="pagenum" id="Page_34">[Pg 34]</span></p>
-<h3 class="nobreak" id="SECTION_IV">SECTION IV.<br />
-<span class="h_subtitle">DIVISION.</span></h3>
-
-<p>69. Suppose I ask whether 156 can be divided into a number of parts
-each of which is 13, or how many thirteens 156 contains; I propose a
-question, the solution of which is called <span class="allsmcap">DIVISION</span>. In this
-case, 156 is called the <i>dividend</i>, 13 the <i>divisor</i>, and the
-number of parts required is the <i>quotient</i>; and when I find the
-quotient, I am said to divide 156 by 13.</p>
-
-<p>70. The simplest method of doing this is to subtract 13 from 156,
-and then to subtract 13 from the remainder, and so on; or, in common
-language, to <i>tell off</i> 156 by thirteens. A similar process has
-already occurred in the exercises on subtraction, Art. (46). Do this,
-and mark one for every subtraction that is made, to remind you that
-each subtraction takes 13 once from 156, which operations will stand as
-follows:</p>
-
-<ul class="index">
-<li class="isub1">156</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1">143</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1">130</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1">117</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1">104</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">91</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">78</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">65</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">52</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">39</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">26</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub1-5">13</li>
-<li class="isub1-5">13&nbsp; 1</li>
-<li class="isub1">&mdash;&mdash;&mdash;</li>
-<li class="isub2">0</li>
-</ul>
-
-<p>Begin by subtracting 13 from 156, which leaves 143. Subtract 13 from
-143, which leaves 130; and so on. At last 13 only remains, from which
-when 13 is subtracted, there remains nothing. Upon counting the number
-of times which you have subtracted 13, you find that this number is 12;
-or 156 contains twelve thirteens, or contains 13 twelve times.</p>
-
-<p>This method is the most simple possible, and might be done with
-pebbles. Of these you would first count 156. You would then take 13
-from the heap, and put them into one heap by themselves. You would
-then take another 13 from the heap, and place them in another heap by
-themselves; and so on until there were none left. You would then count
-the number of heaps, which you would find to be 12.</p>
-
-<p>71. Division is the opposite of multiplication. In multiplication you
-have a number of heaps, with the same number of pebbles in each, and
-you want to know how many <i>pebbles</i> there are in all. In division
-<span class="pagenum" id="Page_35">[Pg 35]</span>
-you know how many there are in all, and how many there are to be in
-each heap, and you want to know how many <i>heaps</i> there are.</p>
-
-<p>72. In the last example a number was taken which contains an exact
-number of thirteens. But this does not happen with every number. Take,
-for example, 159. Follow the process of (70), and it will appear that
-after having subtracted 13 twelve times, there remains 3, from which
-13 cannot be subtracted. We may say then that 159 contains twelve
-thirteens and 3 <i>over</i>; or that 159, when divided by 13, gives a
-<i>quotient</i> 12, and a <i>remainder</i> 3. If we use signs,</p>
-
-<p class="f110">159 = 13 × 12 + 3.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">146</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">24 × 6 + 2, or 146 contains six twenty-fours and 2 over.</td>
- </tr><tr>
- <td class="tdr">146</td>
- <td class="tdc">=</td>
- <td class="tdl">6 × 24 + 2, or 146 contains twenty-four sixes and 2 over.</td>
- </tr><tr>
- <td class="tdr">300</td>
- <td class="tdc">=</td>
- <td class="tdl">42 × 7 + 6, or 300 contains seven forty-twos and 6 over.</td>
- </tr><tr>
- <td class="tdr">39624</td>
- <td class="tdc">=</td>
- <td class="tdl">&nbsp;7277 × 5 + 3239.</td>
- </tr>
- </tbody>
-</table>
-
-<p>73. If <i>a</i> contain <i>b</i> <i>q</i> times with a remainder
-<i>r</i>, <i>a</i> must be greater than <i>bq</i> by <i>r</i>; that is,</p>
-
-<p class="f110"><i>a</i> = <i>bq</i> + <i>r</i>.</p>
-
-<p class="no-indent">If there be no remainder, <i>a</i> = <i>bq</i>.
-Here <i>a</i> is the dividend, <i>b</i> the divisor, <i>q</i> the
-quotient, and <i>r</i> the remainder. In order to say that <i>a</i>
-contains <i>b</i> <i>q</i> times, we write,</p>
-
-<p class="f110"><i>a</i>/<i>b</i> = <i>q</i>, or <i>a</i> : <i>b</i> = <i>q</i>,</p>
-
-<p class="no-indent">which in old books is often found written thus:</p>
-
-<p class="f110"><i>a</i> ÷ <i>b</i> = <i>q</i>.</p>
-
-<p>74. If I divide 156 into several parts, and find how often 13 is
-contained in each of them, it is plain that 156 contains 13 as often as
-all its parts together. For example, 156 is made up of 91, 39, and 26.
-Of these</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">91</td>
- <td class="tdc">contains 13</td>
- <td class="tdl">7 times,</td>
- </tr><tr>
- <td class="tdr">39</td>
- <td class="tdc">contains 13</td>
- <td class="tdl">3 times,</td>
- </tr><tr>
- <td class="tdr">26</td>
- <td class="tdc">contains 13</td>
- <td class="tdl">2 times;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">therefore 91 + 39 + 26 contains 13 7 + 3 + 2 times, or 12 times.</p>
-
-<p>Again, 156 is made up of 100, 50, and 6.
-<span class="pagenum" id="Page_36">[Pg 36]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">Now</td>
- <td class="tdr">100 contains</td>
- <td class="tdl">13&nbsp; 7 times</td>
- <td class="tdl">and&nbsp; 9 over,</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">50 contains</td>
- <td class="tdl">13&nbsp; 3 times</td>
- <td class="tdl">and 11 over,</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">6 contains</td>
- <td class="tdl">13&nbsp; 0 times<a id="FNanchor_9" href="#Footnote_9" class="fnanchor">[9]</a></td>
- <td class="tdl">and 6 over.</td>
- </tr>
- </tbody>
-</table>
-
-<p>Therefore 100 + 50 + 6 contains 13 7 + 3 + 0 times and 9 + 11 + 6 over;
-or 156 contains 13 10 times and 26 over. But 26 is itself 2 thirteens;
-therefore 156 contains 10 thirteens and 2 thirteens, or 12 thirteens.</p>
-
-<p>75. The result of the last article is expressed by saying, that if</p>
-
-<p class="fontsize_110 big_indent"><i>a</i> = <i>b</i> + <i>c</i> + <i>d</i>, then</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc bb2"><i>a</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdc bb2"><i>b</i></td>
- <td class="tdc" rowspan="2">+</td>
- <td class="tdc bb2"><i>c</i></td>
- <td class="tdc" rowspan="2">+</td>
- <td class="tdc bb2"><i>d</i></td>
- </tr><tr>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>76. In the first example I did not take away 13 more than once at a
-time, in order that the method might be as simple as possible. But
-if I know what is twice 13, 3 times 13, &amp;c., I can take away as many
-thirteens at a time as I please, if I take care to mark at each step
-how many I take away. For example, take away 13 ten times at once from
-156, that is, take away 130, and afterwards take away 13 twice, or take
-away 26, and the process is as follows:</p>
-
-<ul class="index">
-<li class="isub2">156</li>
-<li class="isub2">130&nbsp; 10 times 13.</li>
-<li class="isub2 over">&nbsp;26</li>
-
-<li class="isub2">&nbsp;26&nbsp; 2 times 13.</li>
-<li class="isub2 over">&nbsp;&nbsp;0</li>
-</ul>
-
-<p class="no-indent">Therefore 156 contains 13 10 + 2, or 12 times.</p>
-
-<p>Again, to divide 3096 by 18.</p>
-
-<ul class="index">
-<li class="isub2">3096</li>
-<li class="isub2">1800&nbsp; 100 times 18.</li>
-<li class="isub2 over">1296</li>
-<li class="isub2">&nbsp;&nbsp;900 50 times 18.</li>
-<li class="isub2 over">&nbsp;&nbsp;396</li>
-<li class="isub2">&nbsp;&nbsp;360</li>
-<li class="isub2 over">&nbsp;&nbsp;&nbsp;36</li>
-<li class="isub2">&nbsp;&nbsp;&nbsp;36</li>
-<li class="isub2 over">&nbsp;&nbsp;&nbsp;&nbsp;0</li>
-</ul>
-
-<p class="no-indent">Therefore 3096 contains 18 100 + 50 + 20 + 2, or 172 times.</p>
-
-<p>77. You will now understand the following sentences, and be able to
-make similar assertions of other numbers.</p>
-
-<p>450 is 75 × 6; it therefore contains any number, as 5, 6 times as often
-as 75 contains it.
-<span class="pagenum" id="Page_37">[Pg 37]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">135</td>
- <td class="tdc"> contains &nbsp;3 more than</td>
- <td class="tdr">26</td>
- <td class="tdl">times; therefore,</td>
- </tr><tr>
- <td class="tdr">Twice 135</td>
- <td class="tdc">”<span class="ws2">3</span><span class="ws2">”</span></td>
- <td class="tdr">52</td>
- <td class="tdl">or twice 26</td>
- </tr><tr>
- <td class="tdr">10 times 135</td>
- <td class="tdc">”<span class="ws2">3</span><span class="ws2">”</span></td>
- <td class="tdr">260</td>
- <td class="tdl">or 10 times 26</td>
- </tr><tr>
- <td class="tdr">50 times 135</td>
- <td class="tdc">”<span class="ws2">3</span><span class="ws2">”</span></td>
- <td class="tdr">1300</td>
- <td class="tdl">or 50 times 26</td>
- </tr><tr>
- <td class="tdr">472</td>
- <td class="tdc">contains 18 more than</td>
- <td class="tdr">21</td>
- <td class="tdl">times; therefore,</td>
- </tr><tr>
- <td class="tdr">4720</td>
- <td class="tdc">contains 18 more than</td>
- <td class="tdr">210</td>
- <td class="tdl">times,</td>
- </tr><tr>
- <td class="tdr">47200</td>
- <td class="tdc">contains 18 more than</td>
- <td class="tdr">2100</td>
- <td class="tdl">times,</td>
- </tr><tr>
- <td class="tdr">472000</td>
- <td class="tdc">contains 18 more than</td>
- <td class="tdr">21000</td>
- <td class="tdl">times,</td>
- </tr><tr>
- <td class="tdr">32</td>
- <td class="tdc">contains 12 more than</td>
- <td class="tdr">2</td>
- <td class="tdl">times, and less than 3 times.</td>
- </tr><tr>
- <td class="tdr">320</td>
- <td class="tdc">”<span class="ws2">12</span><span class="ws2">”</span></td>
- <td class="tdr">20</td>
- <td class="tdl">times,&nbsp; ”<span class="ws2">&nbsp;</span>&emsp;”&emsp;30 times.</td>
- </tr><tr>
- <td class="tdr">3200</td>
- <td class="tdc">”<span class="ws2">12</span>&emsp;”</td>
- <td class="tdr">200</td>
- <td class="tdl">times,&nbsp; ”<span class="ws2">&nbsp;</span>&emsp;”&emsp;300 times.</td>
- </tr><tr>
- <td class="tdr">32000</td>
- <td class="tdc">”<span class="ws2">12</span><span class="ws2">”</span></td>
- <td class="tdr">2000</td>
- <td class="tdl">times,&nbsp; ”<span class="ws2">&nbsp;</span>&emsp;”&emsp;3000 times.</td>
- </tr><tr>
- <td class="tdr">&amp;c.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">&amp;c.</td>
- <td class="tdr">&amp;c.&emsp;&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>78. The foregoing articles contain the principles of division. The
-question now is, to apply them in the shortest and most convenient way.
-Suppose it required to divide 4068 by 18, or to find 4068/18 (23).</p>
-
-<p>If we divide 4068 into any number of parts, we may, by the process
-followed in (74), find how many times 18 is contained in each of these
-parts, and from thence how many times it is contained in the whole.
-Now, what separation of 4068 into parts will be most convenient?
-Observe that 4, the first figure of 4068, does not contain 18; but that
-40, the first and second figures together, <i>does contain 18 more than
-twice, but less than three times</i>.<a id="FNanchor_10" href="#Footnote_10" class="fnanchor">[10]</a>
-But 4068 (20) is made up of 40 hundreds, and 68; of which, 40 hundreds
-(77) contains 18 more than 200 times, and less than 300 times.
-Therefore, 4068 also contains more than 200 times 18, since it must
-contain 18 more times than 4000 does. It also contains 18 less than
-300 times, because 300 times 18 is 5400, a greater number than 4068.
-Subtract 18 200 times from 4068; that is, subtract 3600, and there
-remains 468. Therefore, 4068 contains 18 200 times, and as many more
-times as 468 contains 18.
-<span class="pagenum" id="Page_38">[Pg 38]</span></p>
-
-<p>It remains, then, to find how many times 468 contains 18. Proceed
-exactly as before. Observe that 46 contains 18 more than twice, and
-less than 3 times; therefore, 460 contains it more than 20, and less
-than 30 times (77); as does also 468. Subtract 18 20 times from 468,
-that is, subtract 360; the remainder is 108. Therefore, 468 contains
-18 20 times, and as many more as 108 contains it. Now, 108 is found to
-contain 18 6 times exactly; therefore, 468 contains it 20 + 6 times,
-and 4068 contains it 200 + 20 + 6 times, or 226 times. If we write down
-the process that has been followed, without any explanation, putting
-the divisor, dividend, and quotient, in a line separated by parentheses
-it will stand, as in example(A).</p>
-
-<p>Let it be required to divide 36326599 by 1342 (B).</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" colspan="3"><big><b>A.</b></big><span class="ws4">&nbsp;</span></td>
- <td class="tdc" colspan="3"><big><b>B.</b></big><span class="ws4">&nbsp;</span></td>
- </tr><tr>
- <td class="tdr">18<span class="fontsize_200">)</span></td>
- <td class="tdr">4068</td>
- <td class="tdl">&nbsp;(200 + 20 + 6<span class="ws2">&nbsp;</span></td>
- <td class="tdr">1342<span class="fontsize_200">)</span></td>
- <td class="tdr">36326599</td>
- <td class="tdl">&nbsp;(20000 + 7000 + 60 + 9</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">3600</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">26840000</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">468</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">9486599</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">360</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">9394000</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">108</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">92599</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">108</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">80520</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">0</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">12079</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">12078</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">1</td>
- <td class="tdl">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>As in the previous example, 36326599 is separated into 36320000 and
-6599; the first four figures 3632 being separated from the rest,
-because it takes four figures from the left of the dividend to make
-a number which is greater than the divisor. Again, 36320000 is found
-to contain 1342 more than 20000, and less than 30000 times; and 1342
-× 20000 is subtracted from the dividend, after which the remainder is
-9486599. The same operation is repeated again and again, and the result
-is found to be, that there is a quotient 20000 + 7000 + 60 + 9, or
-27069, and a remainder 1.</p>
-
-<p>Before you proceed, you should now repeat the foregoing article at
-length in the solution of the following questions. What are</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc bb">10093874</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- <td class="tdc bb">66779922</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- <td class="tdc bb">2718218</td>
- <td class="tdc" rowspan="2">&nbsp;?</td>
- </tr><tr>
- <td class="tdc">3207</td>
- <td class="tdc">114433</td>
- <td class="tdc">13352</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_39">[Pg 39]</span>
-the quotients of which are 3147, 583, 203; and the remainders 1445, 65483, 7762.</p>
-
-<p>79. In the examples of the last article, observe, 1st, that it is
-useless to write down the ciphers which are on the right of each
-subtrahend, provided that without them you keep each of the other
-figures in its proper place: 2d, that it is useless to put down the
-right hand figures of the dividend so long as they fall over ciphers,
-because they do not begin to have any share in the making of the
-quotient until, by continuing the process, they cease to have ciphers
-under them: 3d, that the quotient is only a number written at length,
-instead of the usual way. For example, the first quotient is 200 + 20
-+ 6, or 226; the second is 20000 + 7000 + 60 + 9, or 27069. Strike
-out, therefore, all the ciphers and the numbers which come above them,
-except those in the first line, and put the quotient in one line; and
-the two examples of the last article will stand thus:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">18<span class="fontsize_200">)</span></td>
- <td class="tdr">4068</td>
- <td class="tdl">&nbsp;(226<span class="ws2">&nbsp;</span></td>
- <td class="tdr">1342<span class="fontsize_200">)</span></td>
- <td class="tdr">36326599</td>
- <td class="tdl">&nbsp;(27069</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">36&nbsp;&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">2684&nbsp;&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">46&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">9486&nbsp;&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">36&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">9394&nbsp;&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">108</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">9259&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">108</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr"></td>
- <td class="tdr bb">8052&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">0</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">12079</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr bb">12078</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">1</td>
- <td class="tdl">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>80. Hence the following rule is deduced:</p>
-
-<p>I. Write the divisor and dividend in one line, and place parentheses on
-each side of the dividend.</p>
-
-<p>II. Take off from the left-hand of the dividend the least number of
-figures which make a number greater than the divisor; find what number
-of times the divisor is contained in these, and write this number as
-the first figure of the quotient.</p>
-
-<p>III. Multiply the divisor by the last-mentioned figure, and subtract
-the product from the number which was taken off at the left of the dividend.
-<span class="pagenum" id="Page_40">[Pg 40]</span></p>
-
-<p>IV. On the right of the remainder place the figure of the dividend
-which comes next after those already separated in II.: if the remainder
-thus increased be greater than the divisor, find how many times the
-divisor is contained in it; put this number at the right of the first
-figure of the quotient, and repeat the process: if not, on the right
-place the next figure of the dividend, and the next, and so on until it
-is greater; but remember to place a cipher in the quotient for every
-figure of the dividend which you are obliged to take, except the first.</p>
-
-<p>V. Proceed in this way until all the figures of the dividend are
-exhausted.</p>
-
-<p>In judging how often one large number is contained in another, a first
-and rough guess may be made by striking off the same number of figures
-from both, and using the results instead of the numbers themselves.
-Thus, 4,732 is contained in 14,379 about the same number of times
-that 4 is contained in 14, or about 3 times. The reason is, that 4
-being contained in 14 as often as 4000 is in 14000, and these last
-only differing from the proposed numbers by lower denominations, viz.
-hundreds, &amp;c. we may expect that there will not be much difference
-between the number of times which 14000 contains 4000, and that which
-14379 contains 4732: and it generally happens so. But if the second
-figure of the divisor be 5, or greater than 5, it will be more accurate
-to increase the first figure of the divisor by 1, before trying the
-method just explained. Nothing but practice can give facility in this
-sort of guess-work.</p>
-
-<p>81. This process may be made more simple when the divisor is not
-greater than 12, if you have sufficient knowledge of the multiplication
-table (50). For example, I want to divide 132976 by 4. At full length
-the process stands thus:
-<span class="pagenum" id="Page_41">[Pg 41]</span></p>
-
-<ul class="index">
-<li class="isub1">4<span class="fontsize_200">)</span>132976&nbsp;(33244</li>
-<li class="isub2 u">12</li>
-<li class="isub2">&nbsp;12</li>
-<li class="isub2 u">&nbsp;12</li>
-<li class="isub3">9</li>
-<li class="isub3 u">8&nbsp;</li>
-<li class="isub3">17</li>
-<li class="isub3 u">16</li>
-<li class="isub3">&nbsp;16</li>
-<li class="isub3 u">&nbsp;16</li>
-<li class="isub4">0</li>
-</ul>
-
-<p>But you will recollect, without the necessity of writing it down,
-that 13 contains 4 three times with a remainder 1; this 1 you will
-place before 2, the next figure of the dividend, and you know that 12
-contains 4 3 times exactly, and so on. It will be more convenient to
-write down the quotient thus:</p>
-
-<ul class="index">
-<li class="isub1">4<span class="fontsize_200">)</span>132976</li>
-<li class="isub2">&mdash;&mdash;&mdash;</li>
-<li class="isub2">33244</li>
-</ul>
-
-<p>While on this part of the subject, we may mention, that the shortest
-way to multiply by 5 is to annex a cipher and divide by 2, which is
-equivalent to taking the half of 10 times, or 5 times. To divide by
-5, multiply by 2 and strike off the last figure, which leaves the
-quotient; half the last figure is the remainder. To multiply by 25,
-annex two ciphers and divide by 4. To divide by 25, multiply by 4 and
-strike off the last two figures, which leaves the quotient; one fourth
-of the last two figures, taken as one number, is the remainder. To
-multiply a number by 9, annex a cipher, and subtract the number, which
-is equivalent to taking the number ten times, and then subtracting it
-once. To multiply by 99, annex two ciphers and subtract the number, &amp;c.</p>
-
-<p>In order that a number may be divisible by 2 without remainder, its
-units’ figure must be an even number.<a id="FNanchor_11" href="#Footnote_11" class="fnanchor">[11]</a>
-That it may be divisible by 4, its last two figures must be divisible
-by 4. Take the example 1236: this is composed of 12 hundreds and 36,
-the first part of which, being hundreds, is divisible by 4, and gives
-12 twenty-fives; it depends then upon 36, the last two figures, whether
-1236 is divisible by 4 or not. A number is divisible by 8 if the last
-three figures are divisible by 8; for every digit, except the last
-three, is a number of thousands, and 1000 is divisible by 8; whether
-therefore the whole shall be divisible by 8 or not depends on the last
-three figures: thus, 127946 is not divisible by 8, since 946 is not
-so. A number is divisible by 3 or 9 only when the sum of its digits is
-divisible by 3 or 9. Take for example 1234; this is
-<span class="pagenum" id="Page_42">[Pg 42]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">1 thousand,</td>
- <td class="tdc">&nbsp;&nbsp;or&nbsp;&nbsp;</td>
- <td class="tdr">999 and 1</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">2 hundred,</td>
- <td class="tdc">or</td>
- <td class="tdr">twice 99 and 2</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">3 tens,</td>
- <td class="tdc">or</td>
- <td class="tdr">three times 9 and 3</td>
- </tr><tr>
- <td class="tdr">and&nbsp;&nbsp;</td>
- <td class="tdl">4</td>
- <td class="tdc">or</td>
- <td class="tdr">4</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Now 9, 99, 999, &amp;c. are all obviously
-divisible by 9 and by 3, and so will be any number made by the
-repetition of all or any of them any number of times. It therefore
-depends on 1 + 2 + 3 + 4, or the sum of the digits, whether 1234 shall
-be divisible by 9 or 3, or not. From the above we gather, that a number
-is divisible by 6 when it is even, and when the sum of its digits is
-divisible by 3. Lastly, a number is divisible by 5 only when the last
-figure is 0 or 5.</p>
-
-<p>82. Where the divisor is unity followed by ciphers, the rule becomes
-extremely simple, as you will see by the following examples:</p>
-
-<ul class="index">
-<li class="isub1">100<span class="fontsize_200">)</span>&nbsp;33429&nbsp;(334</li>
-<li class="isub3-5 u">300</li>
-<li class="isub4">&nbsp;342</li>
-<li class="isub4 u">&nbsp;300</li>
-<li class="isub4-5">429</li>
-<li class="isub4-5 u">400</li>
-<li class="isub5">29</li>
-</ul>
-
-<p>This is, then, the rule: Cut off as many figures from the right hand of
-the dividend as there are ciphers. These figures will be the remainder,
-and the rest of the dividend will be the quotient.</p>
-
-<ul class="index">
-<li class="isub1">10<span class="fontsize_200">)</span><span class="bb">&nbsp;2717316</span></li>
-<li class="isub3-5">271731 and rem. 6.</li>
-</ul>
-
-<p>Or we may prove these results thus: from (20), 2717316 is 271731 tens
-and 6; of which the first contains 10 271731 times, and the second not
-at all; the quotient is therefore 271731, and the remainder 6 (72).
-Again (20), 33429 is 334 hundreds and 29; of which the first contains
-100 334 times, and the second not at all; the quotient is therefore
-334, and the remainder 29.</p>
-
-<p>83. The following examples will shew how the rule may be shortened when
-there are ciphers in the divisor. With each example is placed another
-containing the same process, all unnecessary figures being removed; and
-from the comparison of the two, the rule at the end of this article is derived.
-<span class="pagenum" id="Page_43">[Pg 43]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr"><b>I.</b>&nbsp;1782000<span class="fontsize_200">)</span></td>
- <td class="tdr">6424700000</td>
- <td class="tdl">&nbsp;(3605<span class="ws2">&nbsp;</span></td>
- <td class="tdr">1782<span class="fontsize_200">)</span></td>
- <td class="tdr">6424700</td>
- <td class="tdl">&nbsp;(3605</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">5346000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">5346</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">10787000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">10787</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">10692000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">10692</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">9500000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">9500</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr u">8910000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr u">8910</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">590000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr" colspan="2">590000&emsp;&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdr"><b>II.</b>&nbsp;12300000<span class="fontsize_200">)</span></td>
- <td class="tdr">42176189300</td>
- <td class="tdl">&nbsp;(3428<span class="ws2">&nbsp;</span></td>
- <td class="tdr">123<span class="fontsize_200">)</span></td>
- <td class="tdr">421761</td>
- <td class="tdl">&nbsp;(3428</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">36900000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;369</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;52761893</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;527</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;&nbsp;49200000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;&nbsp;492</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;35618930</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;356</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;&nbsp;&nbsp;24600000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;&nbsp;&nbsp;246</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;110189300</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;1101</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;&emsp;98400000</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl bb">&nbsp;&emsp;984</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&emsp;11789300</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl" colspan="2">&nbsp;&emsp;11789300</td>
- </tr>
- </tbody>
-</table>
-
-<p>The rule, then, is: Strike out as many <i>figures</i><a id="FNanchor_12" href="#Footnote_12" class="fnanchor">[12]</a>
-from the right of the dividend as there are <i>ciphers</i> at the
-right of the divisor. Strike out all the ciphers from the divisor, and
-divide in the usual way; but at the end of the process place on the
-right of the remainder all those figures which were struck out of the
-dividend.</p>
-
-<p class="f120 space-above1">84. EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <thead><tr>
- <th class="tdr">Dividend.</th>
- <th class="tdc">Divisor.</th>
- <th class="tdc">Quotient.</th>
- <th class="tdl_ws1">Remainder.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdr_ws1">9694</td>
- <td class="tdr_ws1">47</td>
- <td class="tdr_ws1">206</td>
- <td class="tdr">12</td>
- </tr><tr>
- <td class="tdr_ws1">175618</td>
- <td class="tdr_ws1">3136</td>
- <td class="tdr_ws1">56</td>
- <td class="tdr">2</td>
- </tr><tr>
- <td class="tdr_ws1">23796484</td>
- <td class="tdr_ws1">130000</td>
- <td class="tdr_ws1">183</td>
- <td class="tdr">6484</td>
- </tr><tr>
- <td class="tdr_ws1">14002564</td>
- <td class="tdr_ws1">1871</td>
- <td class="tdr_ws1">7484</td>
- <td class="tdr">0</td>
- </tr><tr>
- <td class="tdr_ws1">310314420</td>
- <td class="tdr_ws1">7878</td>
- <td class="tdr_ws1">39390</td>
- <td class="tdr">0</td>
- </tr><tr>
- <td class="tdr_ws1">3939040647</td>
- <td class="tdr_ws1">6889</td>
- <td class="tdr_ws1">571787</td>
- <td class="tdr">4</td>
- </tr><tr>
- <td class="tdr_ws1">22876792454961</td>
- <td class="tdr_ws1">43046721</td>
- <td class="tdr_ws1">531441</td>
- <td class="tdr">0</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_44">[Pg 44]</span>Shew that</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">100 × 100 × 100 - 43 × 43 × 43</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">I.</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">100 × 100 + 100 × 43 + 43 × 43.</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">100 - 43</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">100 × 100 × 100 + 43 × 43 × 43</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">II.</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">=</td>
- <td class="tdl">100 × 100 - 100 × 43 + 43 × 43.</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">100 + 43</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">76 × 76 + 2 × 76 × 52 + 52 × 52</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">III.</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">=</td>
- <td class="tdl">76 + 52.</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">76 + 52</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">12 × 12 × 12 × 12 - 1</td>
- </tr><tr>
- <td class="tdr_ws1">IV.</td>
- <td class="tdc">1 + 12 + 12 × 12 + 12 × 12 × 12</td>
- <td class="tdc">=</td>
- <td class="tdl">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;.</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1"><span class="ws2">12 - 1</span></td>
- </tr>
- </tbody>
-</table>
-
-<p>What is the nearest number to 1376429 which can be divided by 36300
-without remainder?&mdash;<i>Answer</i>, 1379400.</p>
-
-<p>If 36 oxen can eat 216 acres of grass in one year, and if a sheep eat
-half as much as an ox, how long will it take 49 oxen and 136 sheep
-together to eat 17550 acres?&mdash;<i>Answer</i>, 25 years.</p>
-
-<p>85. Take any two numbers, one of which divides the other without
-remainder; for example, 32 and 4. Multiply both these numbers by any
-other number; for example, 6. The products will be 192 and 24. Now,
-192 contains 24 just as often as 32 contains 4. Suppose 6 baskets,
-each containing 32 pebbles, the whole number of which will be 192.
-Take 4 from one basket, time after time, until that basket is empty.
-It is plain that if, instead of taking 4 from that basket, I take 4
-from each, the whole 6 will be emptied together: that is, 6 times 32
-contains 6 times 4 just as often as 32 contains 4. The same reasoning
-applies to other numbers, and therefore <i>we do not alter the quotient
-if we multiply the dividend and divisor by the same number</i>.</p>
-
-<p>86. Again, suppose that 200 is to be divided by 50. Divide both the
-dividend and divisor by the same number; for example, 5. Then, 200 is 5
-times 40, and 50 is 5 times 10. But by (85), 40 divided by 10 gives the
-same quotient as 5 times 40 divided by 5 times 10, and therefore <i>the
-quotient of two numbers is not altered by dividing both the dividend
-and divisor by the same number</i>.</p>
-
-<p>87. From (55), if a number be multiplied successively by two others, it
-is multiplied by their product. Thus, 27, first multiplied by 5, and
-the product multiplied by 3, is the same as 27 multiplied by 5 times 3,
-or 15. Also, if a number be divided by any number, and the quotient be
-<span class="pagenum" id="Page_45">[Pg 45]</span>
-divided by another, it is the same as if the first number had been
-divided by the product of the other two. For example, divide 60 by 4,
-which gives 15, and the quotient by 3, which gives 5. It is plain, that
-if each of the four fifteens of which 60 is composed be divided into
-three equal parts, there are twelve equal parts in all; or, a division
-by 4, and then by 3, is equivalent to a division by 4 × 3, or 12.</p>
-
-<p>88. The following rules will be better understood by stating them in
-an example. If 32 be multiplied by 24 and divided by 6, the result is
-the same as if 32 had been multiplied by the quotient of 24 divided
-by 6, that is, by 4; for the sixth part of 24 being 4, the sixth part
-of any number repeated 24 times is that number repeated 4 times; or,
-multiplying by 24 and dividing by 6 is equivalent to multiplying by 4.</p>
-
-<p>89. Again, if 48 be multiplied by 4, and that product be divided by
-24, it is the same thing as if 48 were divided at once by the quotient
-of 24 divided by 4, that is, by 6. For, every unit which is repeated 6
-times in 48 is repeated 4 times as often, or 24 times, in 4 times 48,
-or the quotient of 48 and 6 is the same as the quotient of 48 × 4 and 6 × 4.</p>
-
-<p>90. The results of the last five articles may be algebraically
-expressed thus:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc bb"><i>ma</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc bb"><i>a</i></td>
- <td class="tdc" rowspan="2"><span class="ws2">(85)</span></td>
- </tr><tr>
- <td class="tdc"><i>mb</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>If <i>n</i> divide <i>a</i> and <i>b</i> without remainder,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc bb"><i>a/n</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc bb"><i>a</i></td>
- <td class="tdc" rowspan="2"><span class="ws2">(86)</span></td>
- </tr><tr>
- <td class="tdc"><i>b/n</i></td>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdc bb"><i>a/b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc bb"><i>a</i></td>
- <td class="tdc" rowspan="2"><span class="ws2">(87)</span></td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>bc</i></td>
- </tr><tr>
- <td class="tdc bb"><i>ab</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;<i>a</i> ×&nbsp;</td>
- <td class="tdc bb"><i>b</i></td>
- <td class="tdc" rowspan="2"><span class="ws2">(88)</span></td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>c</i></td>
- </tr><tr>
- <td class="tdc bb"><i>ac</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc bb"><i>a</i></td>
- <td class="tdc" rowspan="2"><span class="ws2">(89)</span></td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>b/c</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>It must be recollected, however, that these have only been proved in
-the case where all the divisions are without remainder.</p>
-
-<p>91. When one number divides another without leaving any remainder,
-or is contained an exact number of times in it, it is said to be a
-<i>measure</i> of that number, or to <i>measure</i> it. Thus, 4 is
-a measure of 136, or measures 136; but it does not measure 137. The
-<span class="pagenum" id="Page_46">[Pg 46]</span>
-reason for using the word measure is this: Suppose you have a rod 4
-feet long, with nothing marked upon it, with which you want to measure
-some length; for example, the length of a street. If that street should
-happen to be 136 feet in length, you will be able to <i>measure</i> it
-with the rod, because, since 136 contains 4 34 times, you will find
-that the street is exactly 34 times the length of the rod. But if the
-street should happen to be 137 feet long, you cannot measure it with
-the rod; for when you have measured 34 of the rods, you will find a
-remainder, whose length you cannot tell without some shorter measure.
-Hence 4 is said to measure 136, but not to measure 137. A measure,
-then, is a divisor which leaves no remainder.</p>
-
-<p>92. When one number is a measure of two others, it is called a
-<i>common measure</i> of the two. Thus, 15 is a common measure of 180
-and 75. Two numbers may have several common measures. For example, 360
-and 168 have the common measures 2, 3, 4, 6, 24, and several others.
-Now, this question maybe asked: Of all the common measures of 360 and
-168, which is the greatest? The answer to this question is derived from
-a rule of arithmetic, called the rule for finding the <span class="smcap">greatest
-common measure</span>, which we proceed to consider.</p>
-
-<p>93. If one quantity measure two others, it measures their sum and
-difference. Thus, 7 measures 21 and 56. It therefore measures 56 + 21
-and 56-21, or 77 and 35. This is only another way of saying what was
-said in (74).</p>
-
-<p>94. If one number measure a second, it measures every number which the
-second measures. Thus, 5 measures 15, and 15 measures 30, 45, 60, 75,
-&amp;c.; all which numbers are measured by 5. It is plain that if</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">15 contains 5</td>
- <td class="tdl_ws1">3 times,</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">30, or 15 + 15 contains 5</td>
- <td class="tdl_ws1">3 + 3 times,</td>
- <td class="tdl">&nbsp;or 6 times,</td>
- </tr><tr>
- <td class="tdr_ws1">45, or 15 + 15 + 15 contains 5</td>
- <td class="tdl_ws1">3 + 3 + 3</td>
- <td class="tdl">&nbsp;or 9 times;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on.</p>
-
-<p>95. Every number which measures both the dividend and divisor
-measures the remainder also. To shew this, divide 360 by 112. The
-quotient is 3, and the remainder 24, that is (72) 360 is three times 112
-<span class="pagenum" id="Page_47">[Pg 47]</span>
-and 24, or 360 = 112 × 3 + 24. From this it follows, that 24 is the
-difference between 360 and 3 times 112, or 24 = 360-112 × 3. Take any
-number which measures both 360 and 112; for example, 4. Then</p>
-
-<ul class="index fontsize_110">
-<li class="isub2">4 measures 360,</li>
-<li class="isub2">4 measures 112, and therefore (94) measures 112 × 3,</li>
-<li class="isub1">or 112 + 112 + 112.</li>
-</ul>
-
-<p>Therefore (93) it measures 360-112 × 3, which is the remainder 24.
-The same reasoning may be applied to all other measures of 360 and 112;
-and the result is, that every quantity which measures both the dividend
-and divisor also measures the remainder. Hence, every <i>common
-measure</i> of a dividend and divisor is also a <i>common measure</i>
-of the divisor and remainder.</p>
-
-<p>96. Every common measure of the divisor and remainder is also a
-common measure of the dividend and divisor. Take the same example,
-and recollect that 360 = 112 × 3 + 24. Take any common measure of the
-remainder 24 and the divisor 112; for example, 8. Then</p>
-
-<ul class="index fontsize_110">
-<li class="isub3">8 measures 24;</li>
-<li class="isub1">and 8 measures 112, and therefore (94) measures 112 × 3.</li>
-</ul>
-
-<p>Therefore (93) 8 measures 112 × 3 + 24, or measures the dividend 360.
-Then every common measure of the remainder and divisor is also a common
-measure of the divisor and dividend, or there is no common measure of
-the remainder and divisor which is not also a common measure of the
-divisor and dividend.</p>
-
-<p>97. I. It is proved in (95) that the remainder and divisor have all the
-common measures which are in the dividend and divisor.</p>
-
-<p>II. It is proved in (96) that they have no others.</p>
-
-<p>It therefore follows, that the greatest of the common measures of the
-first two is the greatest of those of the second two, which shews how
-to find the greatest common measure of any two numbers,<a id="FNanchor_13" href="#Footnote_13" class="fnanchor">[13]</a>
-as follows:</p>
-
-<p>98. Take the preceding example, and let it be required to find the g.
-c. m. of 360 and 112, and observe that
-<span class="pagenum" id="Page_48">[Pg 48]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">360 divided by</td>
- <td class="tdr_ws1">112 gives the remainder</td>
- <td class="tdl">24,</td>
- </tr><tr>
- <td class="tdr_ws1">112 divided by</td>
- <td class="tdr_ws1">24 gives the remainder</td>
- <td class="tdl">16,</td>
- </tr><tr>
- <td class="tdr_ws1">24 divided by</td>
- <td class="tdr_ws1">16 gives the remainder</td>
- <td class="tdl">8,</td>
- </tr><tr>
- <td class="tdr_ws1">16 divided by</td>
- <td class="tdl_ws1" colspan="2">8 gives no remainder.</td>
- </tr>
- </tbody>
-</table>
-
-<p>Now, since 8 divides 16 without remainder, and since it also divides
-itself without remainder, 8 is the g. c. m. of 8 and 16, because it is
-impossible to divide 8 by any number greater than 8; so that, even if
-16 had a greater measure than 8, it could not be <i>common</i> to 16 and 8.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdl">Therefore</td>
- <td class="tdr_ws1">8</td>
- <td class="tdr_ws1">is g. c. m. of</td>
- <td class="tdr">16 and 8,</td>
- </tr><tr>
- <td class="tdr_ws1">(97) g. c. m. of</td>
- <td class="tdr_ws1">16 and 8</td>
- <td class="tdr_ws1">is g. c. m. of</td>
- <td class="tdr">24 and 16,</td>
- </tr><tr>
- <td class="tdr_ws1">g. c. m. of</td>
- <td class="tdr_ws1">24 and 16</td>
- <td class="tdr_ws1">is g. c. m. of</td>
- <td class="tdr">112 and 24,</td>
- </tr><tr>
- <td class="tdr_ws1">g. c. m. of</td>
- <td class="tdr_ws1">112 and 24</td>
- <td class="tdr_ws1">is g. c. m. of</td>
- <td class="tdr">360 and 112,</td>
- </tr><tr>
- <td class="tdl">Therefore</td>
- <td class="tdr_ws1">8</td>
- <td class="tdr_ws1">is g. c. m. of</td>
- <td class="tdr">360 and 112.</td>
- </tr>
- </tbody>
-</table>
-
-<p>The process carried on may be written down in either of the following ways:</p>
-
-<ul class="index">
-<li class="isub1">112<span class="fontsize_200">)</span>&nbsp;360&nbsp;(3</li>
-<li class="isub3-5 u">336</li>
-<li class="isub4">24<span class="fontsize_200">)</span>&nbsp;112&nbsp;(4</li>
-<li class="isub6 u">&nbsp;96</li>
-<li class="isub6">16<span class="fontsize_200">)</span>&nbsp;24&nbsp;(1</li>
-<li class="isub8 u">16</li>
-<li class="isub8-5">8<span class="fontsize_200">)</span>&nbsp;16&nbsp;(2</li>
-<li class="isub10 u">16</li>
-<li class="isub10">&nbsp;0</li>
-</ul>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" rules="cols">
- <tbody><tr>
- <td class="tdr_ws1">112</td>
- <td class="tdr_ws1">360</td>
- <td class="tdr"><span class="ws2">3</span></td>
- </tr><tr>
- <td class="tdr_ws1 bb">96</td>
- <td class="tdr_ws1 bb">336</td>
- <td class="tdr bb">4</td>
- </tr><tr>
- <td class="tdr_ws1">16</td>
- <td class="tdr_ws1">24</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr_ws1 bb">16</td>
- <td class="tdr_ws1 bb">16</td>
- <td class="tdr bb">2</td>
- </tr><tr>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">8</td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>The rule for finding the greatest common measure of two numbers is,</p>
-
-<p>I. Divide the greater of the two by the less.</p>
-
-<p>II. Make the remainder a divisor, and the divisor a dividend, and find
-another remainder.</p>
-
-<p>III. Proceed in this way until there is no remainder, and the last
-divisor is the greatest common measure required.</p>
-
-<p>99. You may perhaps ask how the rule is to shew when the two numbers
-have no common measure. The fact is, that there are, strictly speaking,
-no such numbers, because all numbers are measured by 1; that is,
-contain an exact number of units, and therefore 1 is a common measure
-of every two numbers. If they have no other common measure, the last
-divisor will be 1, as in the following example, where the greatest
-common measure of 87 and 25 is found.
-<span class="pagenum" id="Page_49">[Pg 49]</span></p>
-
-<ul class="index">
-<li class="isub1">25<span class="fontsize_200">)</span>&nbsp;87&nbsp;(3</li>
-<li class="isub3 u">75</li>
-<li class="isub3">12<span class="fontsize_200">)</span>&nbsp;25&nbsp;(2</li>
-<li class="isub4-5 u">&nbsp;24</li>
-<li class="isub5">1<span class="fontsize_200">)</span>&nbsp;12&nbsp;(12</li>
-<li class="isub6-5 u">12</li>
-<li class="isub6-5">&nbsp;0</li>
-</ul>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <thead><tr>
- <th class="tdc" colspan="2">Numbers.</th>
- <th class="tdr">&emsp;g. c. m.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdr_ws1">6197</td>
- <td class="tdr_ws1">9521</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr_ws1">58363</td>
- <td class="tdr_ws1">2602</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr_ws1">5547</td>
- <td class="tdr_ws1">&emsp;147008443</td>
- <td class="tdr">1849</td>
- </tr><tr>
- <td class="tdr_ws1">6281</td>
- <td class="tdr_ws1">326041</td>
- <td class="tdr">571</td>
- </tr><tr>
- <td class="tdr_ws1">28915</td>
- <td class="tdr_ws1">31495</td>
- <td class="tdr">5</td>
- </tr><tr>
- <td class="tdr_ws1">1509</td>
- <td class="tdr_ws1">300309</td>
- <td class="tdr">3</td>
- </tr>
- </tbody>
-</table>
-
-<ul class="index">
-<li class="isub1">What are 36 × 36 + 2 × 36 × 72 + 72 × 72</li>
-<li class="isub3-5">and 36 × 36 × 36 + 72 × 72 × 72;</li>
-</ul>
-
-<p class="no-indent">and what is their greatest common measure?&mdash;<i>Answer</i>, 11664.</p>
-
-<p class="space-above1">100. If two numbers be divisible by a third,
-and if the quotients be again divisible by a fourth, that third is
-not the greatest common measure. For example, 360 and 504 are both
-divisible by 4. The quotients are 90 and 126. Now 90 and 126 are both
-divisible by 9, the quotients of which division are 10 and 14. By (87),
-dividing a number by 4, and then dividing the quotient by 9, is the
-same thing as dividing the number itself by 4 × 9, or by 36. Then,
-since 36 is a common measure of 360 and 504, and is greater than 4, 4
-is not the greatest common measure. Again, since 10 and 14 are both
-divisible by 2, 36 is not the greatest common measure. It therefore
-follows, that when two numbers are divided by their greatest common
-measure, the quotients have no common measure except 1 (99). Otherwise,
-the number which was called the greatest common measure in the last
-sentence is not so in reality.</p>
-
-<p>101. To find the greatest common measure of three numbers, find the g.
-c. m. of the first and second, and of this and the third. For since
-all common divisors of the first and second are contained in their g.
-c. m., and no others, whatever is common to the first, second, and
-third, is common also to the third and the g. c. m. of the first and
-second, and no others. Similarly, to find the g. c. m. of four numbers,
-find the g. c. m. of the first, second, and third, and of that and the fourth.</p>
-
-<p>102. When a first number contains a second, or is divisible by it
-without remainder, the first is called a multiple of the second. The
-words <i>multiple</i> and <i>measure</i> are thus connected: Since 4 is
-<span class="pagenum" id="Page_50">[Pg 50]</span>
-a measure of 24, 24 is a multiple of 4. The number 96 is a multiple of
-8, 12, 24, 48, and several others. It is therefore called a <i>common
-multiple</i> of 8, 12, 24. 48, &amp;c. The product of any two numbers is
-evidently a common multiple of both. Thus, 36 × 8, or 288, is a common
-multiple of 36 and 8. But there are common multiples of 36 and 8 less
-than 288; and because it is convenient, when a common multiple of two
-quantities is wanted, to use the least of them, I now shew how to find
-the least common multiple of two numbers.</p>
-
-<p>103. Take, for example, 36 and 8. Find their greatest common measure,
-which is 4, and observe that 36 is 9 × 4, and 8 is 2 × 4. The quotients
-of 36 and 8, when divided by their greatest common measure, are
-therefore 9 and 2. Multiply these quotients together, and multiply the
-product by the greatest common measure, 4, which gives 9 × 2 × 4, or
-72. This is a multiple of 8, or of 4 × 2 by (55); and also of 36 or of
-4 × 9. It is also the least common multiple; but this cannot be proved
-to you, because the demonstration cannot be thoroughly understood
-without more practice in the use of letters to stand for numbers. But
-you may satisfy yourself that it is the least in this case, and that
-the same process will give the least common multiple in any other case
-which you may take. It is not even necessary that you should know it is
-the least. Whenever a common multiple is to be used, any one will do as
-well as the least. It is only to avoid large numbers that the least is
-used in preference to any other.</p>
-
-<p>When the greatest common measure is 1, the least common multiple of the
-two numbers is their product.</p>
-
-<p>The rule then is: To find the least common multiple of two numbers,
-find their greatest common measure, and multiply one of the numbers by
-the quotient which the other gives when divided by the greatest common
-measure. To find the least common multiple of three numbers, find the
-least common multiple of the first two, and find the least common
-multiple of that multiple and the third, and so on.
-<span class="pagenum" id="Page_51">[Pg 51]</span></p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" rules="cols">
- <thead><tr>
- <th class="tdc">Numbers proposed.</th>
- <th class="tdr">Least<br /> common<br />&nbsp;multiple.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdc">14, 21</td>
- <td class="tdr">42</td>
- </tr><tr>
- <td class="tdc">16, 5, 24</td>
- <td class="tdr">240</td>
- </tr><tr>
- <td class="tdc">1, 2, 3, 4, 5, 6, 7, 8, 9, 10&nbsp;</td>
- <td class="tdr">2520</td>
- </tr><tr>
- <td class="tdc">6, 8, 11, 16, 20</td>
- <td class="tdr">2640</td>
- </tr><tr>
- <td class="tdc">876, 864</td>
- <td class="tdr">63072</td>
- </tr><tr>
- <td class="tdc">868, 854</td>
- <td class="tdr">52948</td>
- </tr>
- </tbody>
-</table>
-
-<p>A convenient mode of finding the least common multiple of several
-numbers is as follows, when the common measures are easily visible:
-Pick out a number of common measures of two or more, which have
-themselves no divisors greater than unity. Write them as divisors,
-and divide every number which will divide by one or more of them.
-Bring down the quotients, and also the numbers which will not divide
-by any of them. Repeat the process with the results, and so on until
-the numbers brought down have no two of them any common measure except
-unity. Then, for the least common multiple, multiply all the divisors
-by all the numbers last brought down. For instance, let it be required
-to find the least common multiple of all the numbers from 11 to 21.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2">
- <tbody><tr>
- <td class="tdr">2, 2, 3, 5, 7<span class="fontsize_200">)</span></td>
- <td class="tdl bb">11 12 13 14 15 16 17 18 19 20 21</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">11  1  13   1   1  4  17  3  19   1  1</td>
- </tr>
- </tbody>
-</table>
-
-<p>There are now no common measures left in the row, and the least common
-multiple required is the product of 2, 2, 3, 5, 7, 11, 13, 4, 17, 3,
-and 19; or 232792560.</p>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 id="SECTION_V">SECTION V.<br /><span class="h_subtitle">FRACTIONS.</span></h3>
-</div>
-
-<p>104. Suppose it required to divide 49 yards into five equal parts, or,
-as it is called, to find the fifth part of 49 yards. If we divide 45 by 5,
-the quotient is 9, and the remainder is 4; that is (72), 49 is made up of
-5 times 9 and 4. Let the line <span class="smcap">a b</span> represent 49 yards:
-<span class="pagenum" id="Page_52">[Pg 52]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2">
- <tbody><tr>
- <td class="tdc" colspan="6">A&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;B</td>
- </tr><tr>
- <td class="tdc"><span class="ws5">&nbsp;</span></td>
- <td class="tdc">C</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">I</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc"><span class="ws5">&nbsp;</span></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">D</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">K</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">E</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">L</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">F</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">M</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">G</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">N</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="2">
- <tbody><tr>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 bb">I</td>
- <td class="tdc_ws1 bb">K</td>
- <td class="tdc_ws1 bb">L</td>
- <td class="tdc_ws1 bb">M</td>
- <td class="tdc_ws1 bb">N</td>
- </tr><tr>
- <td class="tdc">H</td>
- <td class="tdl">|</td>
- <td class="tdl">|</td>
- <td class="tdl">|</td>
- <td class="tdl">|</td>
- <td class="tdl">|<span class="ws2">&nbsp;</span>|</td>
- </tr>
- </tbody>
-</table>
-
-<p>Take 5 lines, <span class="allsmcap">c</span>, <span class="allsmcap">d</span>, <span class="allsmcap">e</span>, <span class="allsmcap">f</span>, and
-<span class="allsmcap">g</span>, each 9 yards in length, and the line <span class="allsmcap">h</span>, 4 yards
-in length. Then, since 49 is 5 nines and 4, <span class="allsmcap">c</span>, <span class="allsmcap">d</span>,
-<span class="allsmcap">e</span>, <span class="allsmcap">f</span>, <span class="allsmcap">g</span>, and <span class="allsmcap">h</span>, are together equal
-to <span class="smcap">a b</span>. Divide <span class="allsmcap">h</span>, which is 4 yards, into five equal
-parts, <span class="allsmcap">i</span>, <span class="allsmcap">k</span>, <span class="allsmcap">l</span>, <span class="allsmcap">m</span>, and <span class="allsmcap">n</span>,
-and place one of these parts opposite to each of the lines, <span class="allsmcap">c</span>,
-<span class="allsmcap">d</span>, <span class="allsmcap">e</span>, <span class="allsmcap">f</span>, and <span class="allsmcap">g</span>. It follows that
-the ten lines, <span class="allsmcap">c</span>, <span class="allsmcap">d</span>, <span class="allsmcap">e</span>, <span class="allsmcap">f</span>,
-<span class="allsmcap">g</span>, <span class="allsmcap">i</span>, <span class="allsmcap">k</span>, <span class="allsmcap">l</span>, <span class="allsmcap">m</span>, <span class="allsmcap">n</span>,
-are together equal to <span class="smcap">a b</span>, or 49 yards. Now <span class="allsmcap">d</span>
-and <span class="allsmcap">k</span> together are of the same length as <span class="allsmcap">c</span> and
-<span class="allsmcap">i</span> together, and so are <span class="allsmcap">e</span> and <span class="allsmcap">l</span>, <span class="allsmcap">f</span>
-and <span class="allsmcap">m</span>, and <span class="allsmcap">g</span> and <span class="allsmcap">n</span>. Therefore, <span class="allsmcap">c</span>
-and <span class="allsmcap">i</span> together, repeated 5 times, will be 49 yards; that is,
-<span class="allsmcap">c</span> and <span class="allsmcap">i</span> together make up the fifth part of 49 yards.</p>
-
-<p>105. <span class="allsmcap">c</span> is a certain number of yards, viz. 9; but <span class="allsmcap">i</span>
-is a new sort of quantity, to which hitherto we have never come. It
-is not an exact number of yards, for it arises from dividing 4 yards
-into 5 parts, and taking one of those parts. It is the fifth part of 4
-yards, and is called a <span class="smcap">fraction</span> of a yard. It is written thus,
-⁴/₅(23), and is what we must add to 9 yards in order to make up the
-fifth part of 49 yards.</p>
-
-<p>The same reasoning would apply to dividing 49 bushels of corn, or 49
-acres of land, into 5 equal parts. We should find for the fifth part
-of the first, 9 bushels and the fifth part of 4 bushels; and for the
-second, 9 acres and the fifth part of 4 acres.</p>
-
-<p>We say, then, once for all, that the fifth part of 49 is 9 and ⁴/₅, or
-9 + ⁴/₅; which is usually written (9⁴/₅), or if we use signs, 49/5 =
-(9⁴/₅).</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>What is the seventeenth part of 1237?&mdash;<i>Answer</i>, (72-¹³/₁₇).
-<span class="pagenum" id="Page_53">[Pg 53]</span></p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="0" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdl" rowspan="3">What are</td>
- <td class="tdc_bott">10032</td>
- <td class="tdc_bott">663819</td>
- <td class="tdc" rowspan="3">and</td>
- <td class="tdc_bott">22773399</td>
- <td class="tdc" rowspan="3">?</td>
- </tr><tr>
- <td class="tdc_ws1">&mdash;&mdash;&mdash;,</td>
- <td class="tdc_ws1">&mdash;&mdash;&mdash;,</td>
- <td class="tdc_ws1">&mdash;&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdc_top">1974</td>
- <td class="tdc_top">23710</td>
- <td class="tdc_top">2424</td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="3"><i>Answer</i>,</td>
- <td class="tdc_bott">162</td>
- <td class="tdc_bott">&emsp;23649</td>
- <td class="tdc" rowspan="3">and</td>
- <td class="tdc_bott">&nbsp;&emsp;2343</td>
- <td class="tdc" rowspan="3">.</td>
- </tr><tr>
- <td class="tdc_ws1">(5&nbsp;&mdash;&mdash;),</td>
- <td class="tdc_ws1">(27&nbsp;&mdash;&mdash;&mdash;),</td>
- <td class="tdc_ws1">(9394&nbsp;&mdash;&mdash;)</td>
- </tr><tr>
- <td class="tdc_top">1974</td>
- <td class="tdc_top">&emsp;23710</td>
- <td class="tdc_top">&nbsp;&emsp;2424</td>
- </tr>
- </tbody>
-</table>
-
-<p>106. By the term fraction is understood a part of any number, or the
-sum of any of the equal parts into which a number is divided. Thus,
-⁴⁹/₅, ⁴/₅, ²⁰/₇, are fractions. The term fraction even includes whole
-numbers:<a id="FNanchor_14" href="#Footnote_14" class="fnanchor">[14]</a>
-for example, 17 is ¹⁷/₁, ³⁴/₂, ⁵¹/₃, &amp;c.</p>
-
-<p>The upper number is called the <i>numerator</i>, the lower number is
-called the <i>denominator</i>, and both of these are called <i>terms</i> of the fraction.
-As long as the numerator is less than the denominator, the fraction is
-less than a unit: thus, ⁶/₁₇ is less than a unit; for 6 divided into 6 parts
-gives 1 for each part, and must give less when divided into 17 parts.
-Similarly, the fraction is equal to a unit when the numerator and denominator
-are equal, and greater than a unit when the numerator is
-greater than the denominator.</p>
-
-<p>107. By ⅔ is meant the third part of 2. This is the same as twice the
-third part of 1.</p>
-
-<p>To prove this, let <span class="smcap">a b</span> be two yards, and divide each of the
-yards <span class="smcap">a c</span> and <span class="smcap">c b</span> into three equal parts.</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="4" summary=" " cellpadding="4">
- <tbody><tr>
- <td class="tdc bb" colspan="7">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1">|</td>
- <td class="tdc_ws1">|</td>
- <td class="tdc_ws1">|</td>
- <td class="tdc_ws1">|</td>
- <td class="tdc_ws1">|</td>
- <td class="tdc_ws1">|</td>
- <td class="tdc_ws1">|</td>
- </tr><tr>
- <td class="tdc_ws1">A</td>
- <td class="tdc_ws1">D</td>
- <td class="tdc_ws1">E</td>
- <td class="tdc_ws1">C</td>
- <td class="tdc_ws1">F</td>
- <td class="tdc_ws1">G</td>
- <td class="tdc_ws1">B</td>
- </tr>
- </tbody>
-</table>
-
-<p>Then, because <span class="smcap">a e</span>, <span class="smcap">e f</span>, and <span class="smcap">f b</span>, are all
-equal to one another, <span class="smcap">a e</span> is the third part of 2. It is
-therefore ⅔. But <span class="smcap">a e</span> is twice <span class="smcap">a d</span>, and <span class="smcap">a d</span>
-is the third part of one yard, or ⅓; therefore ⅔ is twice ⅓; that is,
-in order to get the length ⅔, it makes no difference whether we divide
-<i>two</i> yards at once into three parts, and take <i>one</i> of
-them, or whether we divide <i>one</i> yard into three parts, and take
-<i>two</i> of them. By the same reasoning, ⅝ may be found either by
-dividing 5 into 8 parts, and taking one of them, or by dividing 1 into
-8 parts, and taking five of them. In future, of these two meanings I
-shall use that which is most convenient at the time, as it is proved
-<span class="pagenum" id="Page_54">[Pg 54]</span>
-that they are the same thing. This principle is the same as the
-following: The third part of any number may be obtained by adding
-together the thirds of all the units of which it consists. Thus, the
-third part of 2, or of two units, is made by taking one-third out of
-each of the units, that is,</p>
-
-<p class="f150">⅔ = ⅓ × 2.</p>
-
-<p>This meaning appears ambiguous when the numerator is greater than the
-denominator: thus, ¹⁵/₇ would mean that 1 is to be divided into 7
-parts, and 15 of them are to be taken. We should here let as many units
-be each divided into 7 parts as will give more than 15 of those parts,
-and take 15 of them.</p>
-
-<p>108. The value of a fraction is not altered by multiplying the
-numerator and denominator by the same quantity. Take the fraction ¾,
-multiply its numerator and denominator by 5, and it becomes ¹⁵/₂₀,
-which is the same thing as ¾; that is, one-twentieth part of 15 yards
-is the same thing as one-fourth of 3 yards: or, if our second meaning
-of the word fraction be used, you get the same length by dividing a
-yard into 20 parts and taking 15 of them, as you get by dividing it
-into 4 parts and taking 3 of them. To prove this,</p>
-
-<div class="figcenter">
- <img src="images/i_062.jpg" alt="" width="600" height="117" />
-</div>
-
-<p>let <span class="smcap">a b</span> represent a yard; divide it into 4 equal parts, <span class="smcap">a
-c</span>, <span class="smcap">c d</span>, <span class="smcap">d e</span>, and <span class="smcap">e b</span>, and divide each
-of these parts into 5 equal parts. Then <span class="smcap">a e</span> is ¾. But the
-second division cuts the line into 20 equal parts, of which <span class="smcap">a
-e</span> contains 15. It is therefore ¹⁵/₂₀. Therefore, ¹⁵/₂₀ and ¾ are
-the same thing.</p>
-
-<p>Again, since ¾ is made from ¹⁵/₂₀ by dividing both the numerator
-and denominator by 5, the value of a fraction is not altered by
-dividing both its numerator and denominator by the same quantity. This
-principle, which is of so much importance in every part of arithmetic,
-is often used in common language, as when we say that 14 out of 21 is 2
-out of 3, &amp;c.</p>
-
-<p>109. Though the two fractions ¾ and ¹⁵/₂₀ are the same in value, and
-<span class="pagenum" id="Page_55">[Pg 55]</span>
-either of them may be used for the other without error, yet the first
-is more convenient than the second, not only because you have a
-clearer idea of the fourth of three yards than of the twentieth part
-of fifteen yards, but because the numbers in the first being smaller,
-are more convenient for multiplication and division. It is therefore
-useful, when a fraction is given, to find out whether its numerator
-and denominator have any common divisors or common measures. In (98)
-was given a rule for finding the greatest common measure of any two
-numbers; and it was shewn that when the two numbers are divided by
-their greatest common measure, the quotients have no common measure
-except 1. Find the greatest common measure of the terms of the
-fraction, and divide them by that number. The fraction is then said to
-be <i>reduced to its lowest terms</i>, and is in the state in which the
-best notion can be formed of its magnitude.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>With each fraction is written the same reduced to its lowest terms.</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdr">2794</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">22 × 127</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">22</td>
- </tr><tr>
- <td class="tdr over">2921</td>
- <td class="tdr over">23 × 127</td>
- <td class="tdr over">23</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdr">2788</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">17 × 164</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">17</td>
- </tr><tr>
- <td class="tdr over">4920</td>
- <td class="tdr over">30 × 164</td>
- <td class="tdr over">30</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdr">93280</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">764 × 122</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">764</td>
- </tr><tr>
- <td class="tdr over">13786</td>
- <td class="tdr over">113 × 122</td>
- <td class="tdr over">113</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc">888800</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">22 × 40400</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">22</td>
- </tr><tr>
- <td class="tdr over">40359600</td>
- <td class="tdr over">999 × 40400</td>
- <td class="tdr over">999</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdr">95469</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">121 × 789</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">121</td>
- </tr><tr>
- <td class="tdr over">359784</td>
- <td class="tdr over">456 × 789</td>
- <td class="tdr over">456</td>
- </tr>
- </tbody>
-</table>
-
-<p>110. When the terms of the fraction given are already in
-factors,<a id="FNanchor_15" href="#Footnote_15" class="fnanchor">[15]</a>
-any one factor in the numerator may be divided by a number, provided
-some one factor in the denominator is divided by the same. This follows
-from (88) and (108). In the following examples the figures altered by
-division are accented.
-<span class="pagenum" id="Page_56">[Pg 56]</span></p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdr">12 × 11 × 10</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">3′ × 11 × 10</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">1′ × 11 × 5′</td>
- <td class="tdc" rowspan="2">&nbsp;=&emsp;55</td>
- </tr><tr>
- <td class="tdc over">&nbsp;&nbsp;2 × 3 × 4&nbsp;&nbsp;</td>
- <td class="tdc over">&nbsp;&nbsp;2 × 3 × 1′&nbsp;&nbsp;</td>
- <td class="tdc over">1′ × 1′ × 1′</td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdr">18 × 15 × 13</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">2′ × 3′ × 1′</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">1′ × 1′ × 1′</td>
- <td class="tdc" rowspan="2">&nbsp;=&emsp;<big>¹/₁₆</big>.</td>
- </tr><tr>
- <td class="tdr over">20 × 54 × 52</td>
- <td class="tdr over">4′ × 6′ × 4′</td>
- <td class="tdr over">2′ × 2′ × 4′</td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdr">27 × 28</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">3′ × 4′&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr">3′ × 2′</td>
- <td class="tdc" rowspan="2">&nbsp;=&emsp;<big>⁶/₅.</big></td>
- </tr><tr>
- <td class="tdr over">&nbsp;9 × 70</td>
- <td class="tdr over">1′ × 10′</td>
- <td class="tdr over">1′ × 5′</td>
- </tr>
- </tbody>
-</table>
-
-<p>111. As we can, by (108), multiply the numerator and denominator of a
-fraction by any number, without altering its value, we can now readily
-reduce two fractions to two others, which shall have the same value as
-the first two, and which shall have the same denominator. Take, for
-example, ⅔ and ⁴/₇; multiply both terms of ⅔ by 7, and both terms of
-⁴/₇ by 3. It then appears that</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdl" rowspan="2"><big>⅔ is</big></td>
- <td class="tdc_ws1">2 × 7</td>
- <td class="tdc" rowspan="2">&nbsp;<big>or&emsp;¹⁴/₂₁</big></td>
- </tr><tr>
- <td class="tdc_ws1 over">3 × 7</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2"><big>⁴/₇ is</big></td>
- <td class="tdc_ws1">4 × 3</td>
- <td class="tdc" rowspan="2">&nbsp;<big>or&emsp;¹²/₂₁</big></td>
- </tr><tr>
- <td class="tdc_ws1 over">7 × 3</td>
- </tr>
- </tbody>
-</table>
-
-<p>Here are then two fractions ¹⁴/₂₁ and ¹²/₂₁, equal to ⅔ and ⁴/₇, and
-having the same denominator, 21; in this case, ⅔ and ⁴/₇ are said to be
-<i>reduced to a common denominator</i>.</p>
-
-<p>It is required to reduce ⅒, ⅚, and ⁷/₉ to a common denominator.
-Multiply both terms of the first by the product of 6 and 9; of the
-second by the product of 10 and 9; and of the third by the product of
-10 and 6. Then it appears (108) that</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdl" rowspan="2"><big>⅒ is</big></td>
- <td class="tdc_ws1">1 × 6 × 9</td>
- <td class="tdc" rowspan="2">&nbsp;<big>or&emsp;⁵⁴/₅₄₀</big>.</td>
- </tr><tr>
- <td class="tdc_ws1 over">10 × 6 × 9</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2"><big>⅚&nbsp;is</big></td>
- <td class="tdc_ws1">5 × 10 × 9</td>
- <td class="tdc" rowspan="2">&nbsp;<big>or&emsp;⁴⁵⁰/₅₄₀</big>.</td>
- </tr><tr>
- <td class="tdc_ws1 over">6 × 10 × 9</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2"><big>⁷/₉&nbsp;is</big></td>
- <td class="tdc_ws1">7 × 10 × 6</td>
- <td class="tdc" rowspan="2">&nbsp;<big>or&emsp;⁴²⁰/₅₄₀</big>.</td>
- </tr><tr>
- <td class="tdc_ws1 over">9 × 10 × 6</td>
- </tr>
- </tbody>
-</table>
-
-<p>On looking at these last fractions, we see that all the numerators and
-the common denominator are divisible by 6, and (108) this division will
-not alter their values. On dividing the numerators and denominators of
-⁵⁴/₅₄₀, ⁴⁵⁰/₅₄₀, and ⁴²⁰/₅₄₀ by 6, the resulting fractions are, ⁹/₉₀,
-⁷⁵/₉₀, and ⁷⁰/₉₀. These are fractions with a common denominator, and
-<span class="pagenum" id="Page_57">[Pg 57]</span>
-which are the same as ⅒, ⅚, and ⁷/₉; and therefore these are a more
-simple answer to the question than the first fractions. Observe also
-that 540 is one common multiple of 10, 6, and 9, namely, 10 × 6 × 9,
-but that 90 is <i>the least</i> common multiple of 10, 6, and 9 (103).
-The following process, therefore, is better. To reduce the fractions ⅒,
-⅚, and ⁷/₉, to others having the same value and a common denominator,
-begin by finding the least common multiple of 10, 6, and 9, by the rule
-in (103), which is 90. Observe that 10, 6, and 9 are contained in 90 9,
-15, and 10 times. Multiply both terms of the first by 9, of the second
-by 15, and of the third by 10, and the fractions thus produced are
-⁹/₉₀, ⁷⁵/₉₀, and ⁷⁰/₉₀, the same as before.</p>
-
-<p>If one of the numbers be a whole number, it may be reduced to a
-fraction having the common denominator of the rest, by (106).</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <thead><tr>
- <th class="tdc" colspan="5">Fractions proposed</th>
- <th class="tdc" colspan="5">reduced to a common denominator.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdc br" colspan="5">&nbsp;</td>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1">2</td>
- <td class="tdc_ws1">1</td>
- <td class="tdc_ws1">1</td>
- <td class="tdc_ws1 br">&nbsp;</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1">20</td>
- <td class="tdc_ws1">6</td>
- <td class="tdc_ws1">5</td>
- <td class="tdc_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 over">3</td>
- <td class="tdc_ws1 over">5</td>
- <td class="tdc_ws1 over">6</td>
- <td class="tdc_ws1 br">&nbsp;</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 over">30</td>
- <td class="tdc_ws1 over">30</td>
- <td class="tdc_ws1 over">30</td>
- <td class="tdc_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc br" colspan="5">&nbsp;</td>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1">1</td>
- <td class="tdc_ws1">2</td>
- <td class="tdc_ws1">3</td>
- <td class="tdc_ws1">12</td>
- <td class="tdc_ws1 br">3</td>
- <td class="tdc_ws1">28</td>
- <td class="tdc_ws1">24</td>
- <td class="tdc_ws1">18</td>
- <td class="tdc_ws1">48</td>
- <td class="tdc_ws1">63</td>
- </tr><tr>
- <td class="tdc_ws1 over">3</td>
- <td class="tdc_ws1 over">7</td>
- <td class="tdc_ws1 over">14</td>
- <td class="tdc_ws1 over">21</td>
- <td class="tdc_ws1 over br">4</td>
- <td class="tdc_ws1 over">84</td>
- <td class="tdc_ws1 over">84</td>
- <td class="tdc_ws1 over">84</td>
- <td class="tdc_ws1 over">84</td>
- <td class="tdc_ws1 over">84</td>
- </tr><tr>
- <td class="tdc br" colspan="5">&nbsp;</td>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1" rowspan="2"><span class="fontsize_150">3</span></td>
- <td class="tdc_ws1">4</td>
- <td class="tdc_ws1">5</td>
- <td class="tdc_ws1">6</td>
- <td class="tdc_ws1 br">&nbsp;</td>
- <td class="tdc_ws1">3000</td>
- <td class="tdc_ws1">400</td>
- <td class="tdc_ws1">50</td>
- <td class="tdc_ws1">6</td>
- <td class="tdc_ws1">&nbsp;</td>
- </tr><tr>
-
- <td class="tdc_ws1 over">10</td>
- <td class="tdc_ws1 over">100</td>
- <td class="tdc_ws1 over">1000</td>
- <td class="tdc_ws1 br">&nbsp;</td>
- <td class="tdc_ws1 over">1000</td>
- <td class="tdc_ws1 over">1000</td>
- <td class="tdc_ws1 over">1000</td>
- <td class="tdc_ws1 over">1000</td>
- <td class="tdc_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc br" colspan="5">&nbsp;</td>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1">33</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1">281</td>
- <td class="tdc_ws1 br">&nbsp;</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1">22341</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1">106499</td>
- <td class="tdc_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 over">379</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 over">677</td>
- <td class="tdc_ws1 br">&nbsp;</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 over">256583</td>
- <td class="tdc_ws1">&nbsp;</td>
- <td class="tdc_ws1 over">256583</td>
- <td class="tdc_ws1">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>112. By reducing two fractions to a common denominator, we are able
-to compare them; that is, to tell which is the greater and which the
-less of the two. For example, take ½ and ⁷/₁₅. These fractions reduced,
-without alteration of their value, to a common denominator, are ¹⁵/₃₀
-and ¹⁴/₃₁. Of these the first must be the greater, because (107) it may
-be obtained by dividing 1 into 30 equal parts and taking 15 of them,
-but the second is made by taking 14 of those parts.</p>
-
-<p>It is evident that of two fractions which have the same denominator,
-the greater has the greater numerator; and also that of two fractions
-which have the same numerator, the greater has the less denominator.
-<span class="pagenum" id="Page_58">[Pg 58]</span>
-Thus, ⁸/₇ is greater than ⁸/⁹, since the first is a 7th, and the
-last only a 9th part of 8. Also, any numerator may be made to belong
-to as small a fraction as we please, by sufficiently increasing the
-denominator. Thus, ¹⁰/₁₀₀ is ¹/₁₀, ¹⁰/₁₀₀₀ is ¹/₁₀₀, and ¹⁰/₁₀₀₀₀₀₀ is
-¹/₁₀₀₀₀₀₀ (108).</p>
-
-<p>We can now also increase and diminish the first fraction by the second.
-For the first fraction is made up of 15 of the 30 equal parts into
-which 1 is divided. The second fraction is 14 of those parts. The sum
-of the two, therefore, must be 15 + 14, or 29 of those parts; that is,
-½ + ⁷/₁₅ is ²⁹/₃₀. The difference of the two must be 15-14, or 1 of
-those parts; that is, ½-⁷/₁₅ = ¹/₃₀.</p>
-
-<p>113. From the last two articles the following rules are obtained:</p>
-
-<p>I. To compare, to add, or to subtract fractions, first reduce them to
-a common denominator. When this has been done, that is the greatest of
-the fractions which has the greatest numerator.</p>
-
-<p>Their sum has the sum of the numerators for its numerator, and the
-common denominator for its denominator.</p>
-
-<p>Their difference has the difference of the numerators for its
-numerator, and the common denominator for its denominator.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">53</td>
- </tr><tr>
- <td class="tdc over">2</td>
- <td class="tdc over">3</td>
- <td class="tdc over">4</td>
- <td class="tdc over">5</td>
- <td class="tdc over">60</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">44</td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc">153</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">18329</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">&nbsp;3&nbsp;</td>
- <td class="tdc over">427</td>
- <td class="tdc over">1282</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2"><span class="fontsize_150">1</span></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">8</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">1834</td>
- </tr><tr>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">1000</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2"><span class="fontsize_150">2</span></td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">12</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">253</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc over">7</td>
- <td class="tdc over">13</td>
- <td class="tdc over">91</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">8</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">94</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc over">2</td>
- <td class="tdc over">16</td>
- <td class="tdc over">188</td>
- <td class="tdc over">2</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">163</td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc">97</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">93066</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">521</td>
- <td class="tdc over">881</td>
- <td class="tdc over">459001</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>114. Suppose it required to add a whole number to a fraction, for
-example, 6 to ⁴/₉. By (106) 6 is ⁵⁴/₉, and ⁵⁴/₉ + ⁴/₉ is ⁵⁸/⁹; that is,
-6 + ⁴/⁹, or as it is usually written, (6⁴/₉), is ⁵⁸/₉. The rule in this
-case is: Multiply the whole number by the denominator of the fraction,
-and to the product add the numerator of the fraction; the sum will be
-the numerator of the result, and the denominator of the fraction will
-be its denominator. Thus, (3¼) = ¹³/₄, (22⁵/₉) = ²⁰³/₉, (74²/₅₅) =
-⁴⁰⁷²/₅₅. This rule is the opposite of that in (105).</p>
-
-<p><span class="pagenum" id="Page_59">[Pg 59]</span></p>
-
-<p>115. From the last rule it appears that</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdr" rowspan="2"><span class="fontsize_120">1723</span></td>
- <td class="tdc">907</td>
- <td class="tdc" rowspan="2">&nbsp;is&nbsp;</td>
- <td class="tdc">17230907</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- </tr><tr>
- <td class="tdc over">10000</td>
- <td class="tdc over">&nbsp;&emsp;10000&emsp;&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2"><span class="fontsize_120">667</span></td>
- <td class="tdc">225</td>
- <td class="tdc" rowspan="2">&nbsp;is&nbsp;</td>
- <td class="tdc">667225</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- </tr><tr>
- <td class="tdc over">&nbsp;1000&nbsp;</td>
- <td class="tdc over">&nbsp;&emsp;1000&emsp;&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2">and&nbsp; <span class="fontsize_120">23</span></td>
- <td class="tdc">99</td>
- <td class="tdc" rowspan="2">&nbsp;is&nbsp;</td>
- <td class="tdc">2300099</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- </tr><tr>
- <td class="tdc over">10000</td>
- <td class="tdc over">&nbsp;&emsp;10000&emsp;&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Hence, when a whole number is to be added to a fraction whose
-denominator is 1 followed by <i>ciphers</i>, the number of which is not
-less than the number of <i>figures</i> in the numerator, the rule is:
-Write the whole number first, and then the numerator of the fraction,
-with as many ciphers between them as the number of <i>ciphers</i>
-in the denominator exceeds the number of <i>figures</i> in the
-numerator. This is the numerator of the result, and the denominator
-of the fraction is its denominator. If the number of ciphers in the
-denominator be equal to the number of figures in the numerator, write
-no ciphers between the whole number and the numerator.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Reduce the following mixed quantities to fractions:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdr" rowspan="2"><span class="fontsize_120">1</span></td>
- <td class="tdl">23707</td>
- <td class="tdl" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdl over">&nbsp;100000&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2"><span class="fontsize_120">2457</span></td>
- <td class="tdl">6</td>
- <td class="tdl" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdl over">10</td>
- </tr><tr>
- <td class="tdr" rowspan="2"> <span class="fontsize_120">233</span></td>
- <td class="tdl">2210</td>
- <td class="tdl" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdl over">10000</td>
- </tr>
- </tbody>
-</table>
-
-<p>116. Suppose it required to multiply ⅔ by 4. This by (48) is taking ⅔
-four times; that is, finding ⅔ + ⅔ + ⅔ + ⅔. This by (112) is ⁸/₃; so
-that to multiply a fraction by a whole number the rule is: Multiply the
-numerator by the whole number, and let the denominator remain.</p>
-
-<p>117. If the denominator of the fraction be divisible by the whole
-number, the rule may be stated thus: Divide the denominator of the
-fraction by the whole number, and let the numerator remain. For
-example, multiply ⁷/₃₆ by 6. This (116) is ⁴²/₃₆, which, since the
-numerator and denominator are now divisible by 6, is (108) the same as ⁷/₆.
-It is plain that ⁷/₆ is made from ⁷/₃₆ in the manner stated in the rule.</p>
-
-<p>118. Multiplication has been defined to be the taking as many of one
-number as there are units in another. Thus, to multiply 12 by 7 is to
-take as many twelves as there are units in 7, or to take 12 as many
-times as you must take 1 in order to make 7. Thus, what is done with 1
-in order to make 7, is done with 12 to make 7 times 12. For example,</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdc">7</td>
- <td class="tdr">is</td>
- <td class="tdl">&nbsp;1 + 1 + 1 + 1 + 1 + 1 + 1</td>
- </tr><tr>
- <td class="tdc">7</td>
- <td class="tdl">&nbsp;times 12 is</td>
- <td class="tdl">&nbsp;12 + 12 + 12 + 12 + 12 + 12 + 12.</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_60">[Pg 60]</span>
-When the same thing is done with two fractions, the result is still
-called their product, and the process is still called multiplication.
-There is this difference, that whereas a whole number is made by adding
-1 to itself a number of times, a fraction is made by dividing 1 into a
-number of equal parts, and adding <i>one of these parts</i> to itself
-a number of times. This being the meaning of the word multiplication,
-as applied to fractions, what is ¾ multiplied by ⅞? Whatever is done
-with 1 in order to make ⅞ must now be done with ¾; but to make ⅞, 1 is
-divided into 8 parts, and 7 of them are taken. Therefore, to make ¾ ×
-⅞, ¾ must be divided into 8 parts, and 7 of them must be taken. Now ¾
-is, by (108), the same thing as ²⁴/₃₂. Since ²⁴/₃₂ is made by dividing
-1 into 32 parts, and taking 24 of them, or, which is the same thing,
-taking 3 of them 8 times, if ²⁴/₃₂ be divided into 8 equal parts, each
-of them is ³/₃₂; and if 7 of these parts be taken, the result is ²¹/₃₂
-(116): therefore ¾ multiplied by ⅞ is ²¹/₃₂; and the same reasoning
-may be applied to any other fractions. But ²¹/₃₂ is made from ¾ and ⅞
-by multiplying the two numerators together for the numerator, and the
-two denominators for the denominator; which furnishes a rule for the
-multiplication of fractions.</p>
-
-<p>119. If this product ²¹/₃₂ is to be multiplied by a third fraction, for
-example, by ⁵/₉, the result is, by the same rule, ¹⁰⁵/₂₈₈; and so on.
-The general rule for multiplying any number of fractions together is
-therefore:</p>
-
-<p>Multiply all the numerators together for the numerator of the product,
-and all the denominators together for its denominator.</p>
-
-<p>120. Suppose it required to multiply together ¹⁵/₁₆ and ⁸/₁₀. The
-product may be written thus:</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdc">15 × 8</td>
- <td class="tdr" rowspan="2">&nbsp;,&nbsp;and is,&nbsp;</td>
- <td class="tdc">120</td>
- <td class="tdr" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc over">16 × 10</td>
- <td class="tdl over">&nbsp;160</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which reduced to its lowest terms (109) is ¾. This
-result might have been obtained directly, by observing that 15 and 10
-are both measured by 5, and 8 and 16 are both measured by 8, and that
-the fraction may be written thus:</p>
-
-<ul class="index fontsize_120">
-<li class="isub4"> 3 × 5 × 8</li>
-<li class="isub3 over">2 × 8 × 2 × 5.</li>
-</ul>
-
-<p class="no-indent">Divide both its numerator and denominator by 5
-× 8 (108) and (87), and the result is at once ¾; therefore, before
-proceeding to multiply any number of fractions together, if there
-be any numerator and any denominator, whether belonging to the same
-fraction or not, which have a common measure, divide them both by that
-common measure, and use the quotients instead of the dividends.
-<span class="pagenum" id="Page_61">[Pg 61]</span></p>
-
-<p>A whole number may be considered as a fraction whose denominator is 1;
-thus, 16 is ¹⁶/₁ (106); and the same rule will apply when one or more
-of the quantities are whole numbers.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">136</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">268</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">36448</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">18224</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">7470</td>
- <td class="tdc over">919</td>
- <td class="tdc over">6864930</td>
- <td class="tdc over">3432465</td>
- </tr><tr>
- <td class="tdc" colspan="10">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">1</td>
- </tr><tr>
- <td class="tdc over">2</td>
- <td class="tdc over">3</td>
- <td class="tdc over">4</td>
- <td class="tdc over">5</td>
- <td class="tdc over">&nbsp;5&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="10">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">17</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">2</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">17</td>
- <td class="tdc over">45</td>
- <td class="tdc over">45</td>
- </tr><tr>
- <td class="tdc" colspan="10">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">13</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">241</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">6266</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">59</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdc over">&nbsp;19&nbsp;</td>
- <td class="tdc over">7874</td>
- </tr><tr>
- <td class="tdc" colspan="10">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">13</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc">601</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">7813</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">461</td>
- <td class="tdc over">&nbsp;11&nbsp;</td>
- <td class="tdc over">5071</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <thead><tr>
- <th class="tdc">Fraction<br />proposed.</th>
- <th class="tdr"><span class="ws2">Square.</span>&nbsp;</th>
- <th class="tdc">Cube.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdc">701</td>
- <td class="tdr_ws1">491401</td>
- <td class="tdr_ws1">&nbsp;&nbsp;344472101</td>
- </tr><tr>
- <td class="tdc over">158</td>
- <td class="tdr_ws1 over">&nbsp;24964&nbsp;</td>
- <td class="tdr_ws1 over">&nbsp;&nbsp;3944312&nbsp;&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">140</td>
- <td class="tdr_ws1">19600</td>
- <td class="tdr_ws1">2744000</td>
- </tr><tr>
- <td class="tdc over">141</td>
- <td class="tdr_ws1 over">19881</td>
- <td class="tdr_ws1 over">2803221</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">355</td>
- <td class="tdr_ws1">126025</td>
- <td class="tdr_ws1">44738875</td>
- </tr><tr>
- <td class="tdc over">113</td>
- <td class="tdr_ws1 over">12769</td>
- <td class="tdr_ws1 over">1442897</td>
- </tr>
- </tbody>
-</table>
-
-<p>From 100 acres of ground, two-thirds of them are taken away; 50 acres
-are then added to the result, and ⁵/₇ of the whole is taken; what
-number of acres does this produce?&mdash;<i>Answer</i>, (59¹¹/₂₁).</p>
-
-<p>121. In dividing one whole number by another, for example, 108 by 9,
-this question is asked,&mdash;Can we, by the addition of any number of
-nines, produce 108? and if so, how many nines will be sufficient for
-that purpose?</p>
-
-<p>Suppose we take two fractions, for example, ⅔ and ⅘, and ask, Can we,
-by dividing ⅘ into some number of equal parts, and adding a number of
-these parts together, produce ⅔? if so, into <i>how many parts</i>
-must we divide ⅘, and <i>how many of them</i> must we add together?
-The solution of this question is still called the division of ⅔ by ⅘;
-and the fraction whose denominator is the number of parts into which ⅘
-is divided, and whose numerator is the number of them which is taken,
-is called the quotient. The solution of this question is as follows:
-Reduce both these fractions to a common denominator (111), which does
-not alter their value (108); they then become ¹⁰/₁₅ and ¹²/₁₅. The
-<span class="pagenum" id="Page_62">[Pg 62]</span>
-question now is, to divide ¹²/₁₅ into a number of parts, and to
-produce ¹⁰/₁₅ by taking a number of these parts. Since ¹²/₁₅ is made
-by dividing 1 into 15 parts and taking 12 of them, if we divide ¹²/₁₅
-into 12 equal parts, each of these parts is ¹/₁₅; if we take 10 of
-these parts, the result is ¹⁰/₁₅. Therefore, in order to produce ¹⁰/₁₅
-or ⅔ (108), we must divide ¹²/₁₅ or ⅘ into 12 parts, and take 10 of
-them; that is, the quotient is ¹⁰/₁₂. If we call ⅔ the dividend, and ⅘
-the divisor, as before, the quotient in this case is derived from the
-following rule, which the same reasoning will shew to apply to other cases:</p>
-
-<p>The numerator of the quotient is the numerator of the dividend
-multiplied by the denominator of the divisor. The denominator of the
-quotient is the denominator of the dividend multiplied by the numerator
-of the divisor. This rule is the reverse of multiplication, as will be
-seen by comparing what is required in both cases. In multiplying ⅘ by
-¹⁰/₁₂, I ask, if out of ⅘ be taken 10 parts out of 12, how much <i>of a
-unit</i> is taken, and the answer is ⁴⁰/⁶⁰, or ⅔. Again, in dividing ⅔
-by ⅘, I ask what part of ⅘ is ⅔, the answer to which is ¹⁰/₁₂.</p>
-
-<p>122. By taking the following instance, we shall see that this rule can
-be sometimes simplified. Divide ¹⁶/₃₃ by ²⁸/₁₅. Observe that 16 is 4 ×
-4, and 28 is 4 × 7; 33 is 3 × 11, and 15 is 3 × 5; therefore the two
-fractions are</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdc">4 × 4</td>
- <td class="tdr" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc">4 × 7</td>
- <td class="tdr" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc over">3 × 11</td>
- <td class="tdl over">3 × 5</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and their quotient, according to the rule, is</p>
-
-<ul class="index fontsize_120">
-<li class="isub4">4 × 4 × 3 × 5</li>
-<li class="isub3 over">3 × 11 × 4 × 7,</li>
-</ul>
-
-<p class="no-indent">in which 4 × 3 is found both in the numerator and denominator. The
-fraction is therefore (108) the same as</p>
-
-<table class="fontsize_110 no-wrap space-above2" border="0" cellspacing="2" summary=" " cellpadding="0">
- <tbody><tr>
- <td class="tdc">4 × 5</td>
- <td class="tdr" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc">20</td>
- <td class="tdr" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc over">11 × 7</td>
- <td class="tdl over">77</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">The rule of the last article, therefore, admits of
-this modification: If the two numerators or the two denominators have
-a common measure, divide by that common measure, and use the quotients
-instead of the dividends.</p>
-
-<p>123. In dividing a fraction by a whole number, for example, ⅔ by 15,
-consider 15 as the fraction ¹⁵/₁. The rule gives ²/⁴⁵ as the quotient.
-Therefore, to divide a fraction by a whole number, multiply the
-denominator by that whole number.
-<span class="pagenum" id="Page_63">[Pg 63]</span></p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="0" >
- <thead><tr>
- <th class="tdr">Dividend.</th>
- <th class="tdc">Divisor.</th>
- <th class="tdc">Quotient.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdc">41</td>
- <td class="tdc">63</td>
- <td class="tdc">41</td>
- </tr><tr>
- <td class="tdc over">33</td>
- <td class="tdc over">11</td>
- <td class="tdc over">189</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">467</td>
- <td class="tdc">907</td>
- <td class="tdc">47167</td>
- </tr><tr>
- <td class="tdc over">151</td>
- <td class="tdc over">101</td>
- <td class="tdc over">136957</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">7813</td>
- <td class="tdc">601</td>
- <td class="tdc">13</td>
- </tr><tr>
- <td class="tdc over">5071</td>
- <td class="tdc over">&nbsp;11&nbsp;</td>
- <td class="tdc over">461</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1" rowspan="2">What are</td>
- <td class="tdc u">¹/₅ × ¹/₅ × ¹/₅ - ²/₁₇× ²/₁₇ × ²/₁₇</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">¹/₅ - ²/₁₇</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" rowspan="2">and</td>
- <td class="tdc u">⁸/₁₁ × ⁸/₁₁ - ³/₁₁ × ³/₁₁</td>
- <td class="tdc" rowspan="2">&nbsp;?</td>
- </tr><tr>
- <td class="tdc">⁸/₁₁ - ³/₁₁</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" rowspan="2"><i>Answer</i>,</td>
- <td class="tdl u">&nbsp;559</td>
- <td class="tdl" rowspan="2">and 1.</td>
- </tr><tr>
- <td class="tdl">7225</td>
- </tr>
- </tbody>
-</table>
-
-<p>A can reap a field in 12 days, B in 6, and C in 4 days; in what time
-can they all do it together?<a id="FNanchor_16" href="#Footnote_16" class="fnanchor">[16]</a>&mdash;<i>Answer</i>, 2 days.</p>
-
-<p>In what time would a cistern be filled by cocks which would separately
-fill it in 12, 11, 10, and 9 hours?&mdash;<i>Answer</i>, (2⁴⁵⁴/₇₆₃) hours.</p>
-
-<p>124. The principal results of this section may be exhibited
-algebraically as follows; let <i>a</i>, <i>b</i>, <i>c</i>, &amp;c. stand
-for any whole numbers. Then</p>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">(107)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc" rowspan="2"><i>a</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>a</i></td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2">(108)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>ma</i></td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>ma</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">(111)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;are the same as&nbsp;</td>
- <td class="tdc"><i>ad</i></td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc"><i>bc</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>d</i></td>
- <td class="tdc over"><i>bd</i></td>
- <td class="tdc over"><i>bd</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">(112)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>a</i> + <i>b</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>c</i></td>
- <td class="tdc over"><i>c</i></td>
- <td class="tdc"><i>c</i></td>
- </tr><tr>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>a</i> - <i>b</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>c</i></td>
- <td class="tdc over"><i>c</i></td>
- <td class="tdc"><i>c</i></td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2">(113)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>ad</i> + <i>bc</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>d</i></td>
- <td class="tdc"><i>bd</i></td>
- </tr><tr>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>ad</i> - <i>bc</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>d</i></td>
- <td class="tdc"><i>bd</i></td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2">(118)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>ac</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>d</i></td>
- <td class="tdc"><i>bd</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">(121)</td>
- <td class="tdl_ws1"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;divᵈ. by&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc"><i>a</i>/<i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>ad</i></td>
- </tr><tr>
- <td class="tdl_ws1 over"><i>b</i></td>
- <td class="tdc over"><i>d</i></td>
- <td class="tdc over"><i>c</i>/<i>d</i></td>
- <td class="tdc over"><i>bc</i></td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_64">[Pg 64]</span>
-125. These results are true even when the letters themselves represent
-fractions. For example, take the fraction</p>
-
-<ul class="index fontsize_120">
-<li class="isub1"><i>a</i>/<i>b</i></li>
-<li class="isub1 over"><i>c</i>/<i>d</i></li>
-</ul>
-
-<p class="no-indent">whose numerator and denominator are fractional,
-and multiply its numerator and denominator by the fraction</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr"><i>e</i></td>
- <td class="tdl" rowspan="2">&nbsp;, which gives&nbsp;&nbsp;</td>
- <td class="tdc"><i>ae</i>/<i>bf</i></td>
- </tr><tr>
- <td class="tdr over">&nbsp;<i>f</i>&nbsp;</td>
- <td class="tdc over"><i>ce</i>/<i>df</i></td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr" rowspan="2">which (121) is&nbsp;&nbsp;</td>
- <td class="tdl"><i>aedf</i></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl over"><i>bfce</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which, dividing the numerator and denominator
-by <i>ef</i> (108), is</p>
-
-<ul class="index fontsize_120">
-<li class="isub1"><i>ad</i></li>
-<li class="isub1 over"><i>bc</i></li>
-</ul>
-
-<p class="no-indent">But the original fraction itself is</p>
-
-<ul class="index fontsize_120">
-<li class="isub1"><i>ad</i></li>
-<li class="isub1 over"><i>bc</i></li>
-</ul>
-
-<p class="no-indent">hence</p>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl"><i>a</i>/<i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>a</i>/<i>b</i></td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>e</i>/<i>f</i></td>
- </tr><tr>
- <td class="tdl over"><i>c</i>/<i>d</i></td>
- <td class="tdc over"><i>c</i>/<i>d</i></td>
- <td class="tdc over">&nbsp;×&nbsp;</td>
- <td class="tdc over"><i>e</i>/<i>f</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which corresponds to the second formula<a id="FNanchor_17" href="#Footnote_17" class="fnanchor">[17]</a>
-in (124). In a similar manner it may be shewn, that the other formulæ
-of the same article are true when the letters there used either
-represent fractions, or are removed and fractions introduced in their
-place. All formulæ established throughout this work are equally true
-when fractions are substituted for whole numbers. For example (54),
-(<i>m</i> + <i>n</i>)<i>a</i> = <i>ma</i> + <i>na</i>. Let <i>m</i>,
-<i>n</i>, and <i>a</i> be respectively the fractions</p>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc" rowspan="2">&nbsp;, and&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdl over">&nbsp;<i>q</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>s</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Then <i>m</i> + <i>n</i> is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc" rowspan="2">, &nbsp;or&nbsp;&nbsp;</td>
- <td class="tdc u"><i>ps</i> + <i>qr</i></td>
- </tr><tr>
- <td class="tdl over">&nbsp;<i>q</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>s</i>&nbsp;</td>
- <td class="tdc"><i>qs</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and (<i>m</i> + <i>n</i>)<i>a</i> is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>ps</i> + <i>qr</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">, &nbsp;or&nbsp;&nbsp;</td>
- <td class="tdc u">(<i>ps</i> + <i>qr</i>)<i>b</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>qs</i></td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc"><i>qsc</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2">or</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdc u"><i>psb</i> + <i>qrb</i></td>
- <td class="tdc" rowspan="2"> .</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdc"><i>qsc</i></td>
- </tr><tr>
- <td class="tdc"></td>
- <td class="tdc u"></td>
- <td class="tdc"></td>
- <td class="tdc"></td>
- <td class="tdc"></td>
- <td class="tdc"></td>
- </tr><tr>
- <td class="tdc"></td>
- <td class="tdc over"></td>
- <td class="tdc"></td>
- <td class="tdc"></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">But this (112) is&nbsp;&nbsp;</td>
- <td class="tdc"><i>psb</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>qrb</i></td>
- <td class="tdc" rowspan="2">, which is&nbsp;&nbsp;</td>
- <td class="tdc"><i>pb</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>rb</i></td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc over"><i>qsc</i></td>
- <td class="tdc over"><i>qsc</i></td>
- <td class="tdc over"><i>qc</i></td>
- <td class="tdc over"><i>sc</i></td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2">since&nbsp;&nbsp;</td>
- <td class="tdc"><i>psb</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>pb</i></td>
- <td class="tdl" rowspan="2">&nbsp;, and</td>
- <td class="tdc"><i>qrb</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>rb</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;(103).</td>
- </tr><tr>
- <td class="tdc over"><i>qsc</i></td>
- <td class="tdc over"><i>qc</i></td>
- <td class="tdc over"><i>qsc</i></td>
- <td class="tdc over"><i>sc</i></td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">But&nbsp;&nbsp;</td>
- <td class="tdc"><i>pb</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>p</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">, and&nbsp;&nbsp;</td>
- <td class="tdc"><i>rb</i></td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">.</td>
- </tr><tr>
- <td class="tdc over"><i>qc</i></td>
- <td class="tdc over">&nbsp;<i>q</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc over"><i>sc</i></td>
- <td class="tdc over">&nbsp;<i>s</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120">Therefore (<i>m</i> + <i>n</i>)<i>a</i>, or</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2"><span class="fontsize_200">(</span></td>
- <td class="tdc"><i>p</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc" rowspan="2"><span class="fontsize_200">)</span>&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>p</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">.</td>
- </tr><tr>
- <td class="tdc over">&nbsp;<i>q&nbsp;</i></td>
- <td class="tdc over">&nbsp;<i>s&nbsp;</i></td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>q</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>s</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>c</i>&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">In a similar manner the same may be proved of any other formula.</p>
-
-<p>The following examples may be useful:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>e</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>g</i></td>
- <td class="tdc" rowspan="5">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc_bott" rowspan="2"><i>acfh</i> + <i>bdeg</i></td>
- </tr><tr>
- <td class="tdc over">&nbsp;<i>b&nbsp;</i></td>
- <td class="tdc over">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>f</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>h</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="7">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>e</i></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc"><i>g</i></td>
- <td class="tdc_top" rowspan="2"><i>aedh</i> + <i>bcfg</i></td>
- </tr><tr>
- <td class="tdc over">&nbsp;<i>b&nbsp;</i></td>
- <td class="tdc over">&nbsp;<i>f&nbsp;</i></td>
- <td class="tdc over">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc over">&nbsp;<i>h</i>&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above1" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc bb" colspan="3">1</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;1&nbsp;</td>
- <td class="tdc over"><i>ab</i> + 1</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above1" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" colspan="3">1</td>
- <td class="tdc" rowspan="3">&nbsp;=&nbsp;</td>
- <td class="tdc" colspan="2">1</td>
- <td class="tdc" rowspan="3">&nbsp;=&nbsp;</td>
- <td class="tdc"><i>bc</i> + 1</td>
- </tr><tr>
- <td class="tdc" colspan="3">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc" colspan="2">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" colspan="2">1</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>abc</i> + <i>a</i> + <i>c</i></td>
- </tr><tr>
- <td class="tdr"><i>a</i> +</td>
- <td class="tdc" colspan="2">&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc"><i>a</i> +</td>
- <td class="tdc">&mdash;&mdash;&mdash;</td>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" colspan="3">1&nbsp;&nbsp;</td>
- <td class="tdr_ws1" colspan="2"><i>bc</i> + 1</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr"><i>b +</i></td>
- <td class="tdc">&mdash;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" colspan="3"><i>c</i>&nbsp;&nbsp;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_65">[Pg 65]</span>
-Thus,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" colspan="3">1</td>
- <td class="tdc" rowspan="3">&nbsp;=&nbsp;</td>
- <td class="tdc" colspan="2">1</td>
- <td class="tdc" rowspan="3">&nbsp;=&nbsp;</td>
- <td class="tdc">57</td>
- </tr><tr>
- <td class="tdc" colspan="3">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc" colspan="2">&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc">&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" colspan="2">1</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">8</td>
- <td class="tdc">350</td>
- </tr><tr>
- <td class="tdr">6 +</td>
- <td class="tdc" colspan="2">&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc">6 +</td>
- <td class="tdc">&mdash;&mdash;</td>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" colspan="3">1&nbsp;&nbsp;</td>
- <td class="tdr_ws1" colspan="2">57&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">7 +</td>
- <td class="tdc">&mdash;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" colspan="3">8&nbsp;&nbsp;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>The rules that have been proved to hold good for all numbers may be
-applied when the numbers are represented by letters.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="SECTION_VI">SECTION VI.<br />
-<span class="h_subtitle">DECIMAL FRACTIONS.</span></h3>
-</div>
-
-<p>126. We have seen (112) (121) the necessity of reducing fractions
-to a common denominator, in order to compare their magnitudes. We
-have seen also how much more readily operations are performed upon
-fractions which have the same, than upon those which have different,
-denominators. On this account it has long been customary, in all
-those parts of mathematics where fractions are often required, to
-use none but such as either have, or can be easily reduced to others
-having, the same denominators. Now, of all numbers, those which can
-be most easily managed are such as 10, 100, 1000, &amp;c., where 1 is
-followed by ciphers. These are called <span class="smcap">decimal numbers</span>; and a
-fraction whose denominator is any one of them, is called a <span class="smcap">decimal
-fraction</span>, or more commonly, a <span class="smcap">decimal</span>.</p>
-
-<p>127. A whole number may be reduced to a decimal fraction, or one
-decimal fraction to another, with the greatest ease. For example,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="Ordinal Names" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2" colspan="2">94 is&nbsp;</td>
- <td class="tdc u">940</td>
- <td class="tdc" rowspan="2">&nbsp;, or&nbsp;</td>
- <td class="tdc u">9400</td>
- <td class="tdc" rowspan="2">&nbsp;, or&nbsp;</td>
- <td class="tdc u">94000</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;(106);</td>
- </tr><tr>
- <td class="tdc">10</td>
- <td class="tdc">100</td>
- <td class="tdc">1000</td>
- </tr><tr>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdc u">&nbsp;3&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;is&nbsp;</td>
- <td class="tdc u">&nbsp;30&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;, or&nbsp;</td>
- <td class="tdc u">&nbsp;300&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;, or&nbsp;</td>
- <td class="tdc u">&nbsp;3000&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;(108).</td>
- </tr><tr>
- <td class="tdc">30</td>
- <td class="tdc">100</td>
- <td class="tdc">1000</td>
- <td class="tdc">10000</td>
- </tr>
- </tbody>
-</table>
-
-<p>The placing of a cipher on the right hand of any number is the same
-thing as multiplying that number by 10 (57), and this may be done as
-often as we please in the numerator of a fraction, provided it be done
-as often in the denominator (108).</p>
-
-<p>128. The next question is, How can we reduce a fraction which is not
-decimal to another which is, without altering its value? Take, for
-example, the fraction ⁷/₁₆, multiply both the numerator and denominator
-successively by 10, 100, 1000, &amp;c., which will give a series of
-fractions, each of which is equal to ⁷/₁₆ (108), viz. ⁷⁰/₁₆₀, ⁷⁰⁰/₁₆₀₀,
-<span class="pagenum" id="Page_66">[Pg 66]</span>
-⁷⁰⁰⁰/₁₆₀₀₀, ⁷⁰⁰⁰⁰/₁₆₀₀₀₀, &amp;c. The denominator of each of these
-fractions can be divided without remainder by 16, the quotients of
-which divisions form the series of decimal numbers 10, 100, 1000,
-10000, &amp;c. If, therefore, one of the numerators be divisible by
-16, the fraction to which that numerator belongs has a numerator and
-denominator both divisible by 16. When that division has been made,
-which (108) does not alter the value of the fraction, we shall have a
-fraction whose denominator is one of the series 10, 100, 1000, &amp;c.,
-and which is equal in value to ⁷/₁₆. The question is then reduced to
-finding the first of the numbers 70, 700, 7000, 70000, &amp;c., which
-can be divided by 16 without remainder.</p>
-
-<p>Divide these numbers, one after the other, by 16, as follows:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">16<span class="fontsize_120">)</span></td>
- <td class="tdc">70</td>
- <td class="tdc">(4</td>
- <td class="tdc">&nbsp;&emsp;&nbsp;</td>
- <td class="tdc">16<span class="fontsize_120">)</span></td>
- <td class="tdc">700</td>
- <td class="tdc">(43</td>
- <td class="tdc">&nbsp;&emsp;&nbsp;</td>
- <td class="tdc">16<span class="fontsize_120">)</span></td>
- <td class="tdc">7000</td>
- <td class="tdc">(437</td>
- <td class="tdc">&nbsp;&emsp;&nbsp;</td>
- <td class="tdc">16<span class="fontsize_120">)</span></td>
- <td class="tdc">70000</td>
- <td class="tdc">(4375</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">64</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl">64</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl">64</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl" colspan="2">64</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl over">&nbsp;&nbsp;6</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl over">&nbsp;&nbsp;60</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl over">&nbsp;&nbsp;60</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl over" colspan="2">&nbsp;&nbsp;60</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;48</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;48</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl" colspan="2">&nbsp;&nbsp;48</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- <td class="tdl over">&nbsp;&nbsp;12</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl over">&nbsp;&nbsp;120</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl over" colspan="2">&nbsp;&nbsp;120</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- <td class="tdl u">&nbsp;&nbsp;112</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdl u">&nbsp;&nbsp;112</td>
- </tr><tr>
- <td class="tdc" colspan="9">&nbsp;</td>
- <td class="tdr">8</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdr">80</td>
- </tr><tr>
- <td class="tdc" colspan="13">&nbsp;</td>
- <td class="tdr u">80</td>
- </tr><tr>
- <td class="tdc" colspan="13">&nbsp;</td>
- <td class="tdr">0</td>
- </tr>
- </tbody>
-</table>
-
-<p>It appears, then, that 70000 is the first of the numerators which is
-divisible by 16. But it is not necessary to write down each of these
-divisions, since it is plain that the last contains all which came
-before. It will do, then, to proceed at once as if the number of
-ciphers were without end, to stop when the remainder is nothing, and
-then count the number of ciphers which have been used. In this case,
-since 70000 is 16 × 4375,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">70000</td>
- <td class="tdl" rowspan="2">&nbsp;, which is&nbsp;&nbsp;</td>
- <td class="tdc">16 × 4375</td>
- <td class="tdl" rowspan="2">&nbsp;, or&nbsp;&nbsp;</td>
- <td class="tdc">4375</td>
- <td class="tdl" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc over">160000</td>
- <td class="tdc over">16 × 10000</td>
- <td class="tdc over">10000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">gives the fraction required.</p>
-
-<p>Therefore, to reduce a fraction to a decimal fraction, annex ciphers
-to the numerator, and divide by the denominator until there is no
-remainder. The quotient will be the numerator of the required fraction,
-and the denominator will be unity, followed by as many ciphers as were
-used in obtaining the quotient.
-<span class="pagenum" id="Page_67">[Pg 67]</span></p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Reduce to decimal fractions</p>
-
-<p class="big_indent"><span class="fontsize_150">½, ¼, ²/₂₅, ¹/₅₀, ³⁹²⁷/₁₂₅₀</span>,
-and <span class="fontsize_150">⁴⁵³/₆₂₅</span>.</p>
-
-<p class="big_indent"><i>Answer</i>, <span class="fontsize_150">⁵/₁₀, ²⁵/₁₀₀, ⁸/₁₀₀, ²/₁₀₀, ³¹⁴¹⁶/₁₀₀₀₀,</span>
-and <span class="fontsize_150">⁷²⁴⁸/₁₀₀₀₀</span>.</p>
-
-<p>129. It will happen in most cases that the annexing of ciphers to
-the numerator will never make it divisible by the denominator without
-remainder. For example, try to reduce ¹/₇ to a decimal fraction.</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">7)1000000000000000000, &amp;c.</li>
-<li class="isub4 over">142857142857142857, &amp;c.</li></ul>
-
-<p>The quotient here is a continual repetition of the figures 1, 4, 2, 8,
-5, 7, in the same order; therefore ¹/₇ cannot be reduced to a decimal
-fraction. But, nevertheless, if we take as a numerator any number of
-figures from the quotient 142857142857, &amp;c., and as a denominator
-1 followed by as many ciphers as were used in making that part of the
-quotient, we shall get a fraction which differs very little from ¹/₇,
-and which will differ still less from it if we put more figures in the
-numerator and more ciphers in the denominator.</p>
-
-<p>Thus,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdr">1</td>
- <td class="tdc" rowspan="2"><img src="images/cbl-2.jpg" alt="" width="9" height="32" /></td>
- <td class="tdc">is less</td>
- <td class="tdc" rowspan="2"><img src="images/cbr-2.jpg" alt="" width="9" height="32" /></td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;by&nbsp;</td>
- <td class="tdr">3</td>
- <td class="tdc" rowspan="2"><img src="images/cbl-2.jpg" alt="" width="9" height="32" /></td>
- <td class="tdc">which is not</td>
- <td class="tdc" rowspan="2"><img src="images/cbr-2.jpg" alt="" width="9" height="32" /></td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">10</td>
- <td class="tdc">than</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdr over">70</td>
- <td class="tdc">so much as</td>
- <td class="tdr over">10</td>
- </tr><tr>
- <td class="tdr">14</td>
- <td class="tdc" colspan="3" rowspan="12">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="12">&nbsp;</td>
- <td class="tdr">2</td>
- <td class="tdc" colspan="3" rowspan="11">&nbsp;</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">100</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdr over">700</td>
- <td class="tdr over">100</td>
- </tr><tr>
- <td class="tdr">142</td>
- <td class="tdc">1</td>
- <td class="tdr">6</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">1000</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdr over">7000</td>
- <td class="tdr over">1000</td>
- </tr><tr>
- <td class="tdr">1428</td>
- <td class="tdc">1</td>
- <td class="tdr">4</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">10000</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdr over">70000</td>
- <td class="tdr over">10000</td>
- </tr><tr>
- <td class="tdr">14285</td>
- <td class="tdc">1</td>
- <td class="tdr">5</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">100000</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdr over">700000</td>
- <td class="tdr over">100000</td>
- </tr><tr>
- <td class="tdr">142857</td>
- <td class="tdc">1</td>
- <td class="tdr">1</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">1000000</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdr over">7000000</td>
- <td class="tdr over">1000000</td>
- </tr><tr>
- <td class="tdc">&amp;c.</td>
- <td class="tdc">&amp;c.</td>
- <td class="tdc">&amp;c.</td>
- <td class="tdc">&amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p>In the first column is a series of decimal fractions, which come nearer
-and nearer to ¹/₇, as the third column shews. Therefore, though we
-cannot find a decimal fraction which is exactly ¹/₇, we can find one
-which differs from it as little as we please.
-<span class="pagenum" id="Page_68">[Pg 68]</span></p>
-
-<p>This may also be illustrated thus: It is required to reduce ¹/₇ to
-a decimal fraction without the error of say a millionth of a unit;
-multiply the numerator and denominator of ¹/₇ by a million, and then
-divide both by 7; we have then</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">1000000</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">1428571¹/₇</td>
- </tr><tr>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdc over">7000000</td>
- <td class="tdc">1000000</td>
- </tr>
- </tbody>
-</table>
-
-<p>If we reject the fraction ¹/₇ in the numerator, what we reject is
-really the 7th part of the millionth part of a unit; or less than the
-millionth part of a unit. Therefore ¹⁴²⁸⁵⁷/₁₀₀₀₀₀₀ is the fraction
-required.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_110 no-wrap space-below2" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdl">Make similar tables</td>
- <td class="tdc" rowspan="2"><img src="images/cbr-2.jpg" alt="" width="9" height="32" /></td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">,&nbsp;&nbsp;</td>
- <td class="tdc">17</td>
- <td class="tdc" rowspan="2">, and&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdl">with these fractions</td>
- <td class="tdc over">&nbsp;91&nbsp;</td>
- <td class="tdc over">143</td>
- <td class="tdc over">247</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdr">The recurring&nbsp;</td>
- <td class="tdc" rowspan="2"><img src="images/cbr-2.jpg" alt="" width="9" height="32" /></td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;is&nbsp;</td>
- <td class="tdl" rowspan="2" colspan="4">329670,329670, &amp;c.</td>
- </tr><tr>
- <td class="tdr">quotient of&nbsp;</td>
- <td class="tdc over">91</td>
- </tr><tr>
- <td class="tdc" colspan="2" rowspan="2">&nbsp;</td>
- <td class="tdc">17</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdl" rowspan="2" colspan="4">118881,118881, &amp;c.</td>
- </tr><tr>
- <td class="tdc over">143</td>
- </tr><tr>
- <td class="tdc" colspan="2" rowspan="2">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdl" rowspan="2" colspan="4">404858299595141700,4048582 &amp;c.</td>
- </tr><tr>
- <td class="tdc over">247</td>
- </tr>
- </tbody>
-</table>
-
-<p>130. The reason for the <i>recurrence</i> of the figures of the
-quotient in the same order is as follows: If 1000, &amp;c. be divided by
-the number 247, the remainder at each step of the division is less than
-247, being either 0, or one of the first 246 numbers. If, then, the
-remainder never become nothing, by carrying the division far enough,
-one remainder will occur a second time. If possible, let the first
-246 remainders be all different, that is, let them be 1, 2, 3, &amp;c.,
-up to 246, variously distributed. As the 247th remainder cannot be so
-great as 247, it must be one of these which have preceded. From the
-step where the remainder becomes the same as a former remainder, it is
-evident that former figures of the quotient must be repeated in the
-same order.</p>
-
-<p>131. You will here naturally ask, What is the use of decimal
-fractions, if the greater number of fractions cannot be reduced at
-all to decimals? The answer is this: The addition, subtraction,
-multiplication, and division of decimal fractions are much easier than
-<span class="pagenum" id="Page_69">[Pg 69]</span>
-those of common fractions; and though we cannot reduce all common
-fractions to decimals, yet we can find decimal fractions so near to
-each of them, that the error arising from using the decimal instead
-of the common fraction will not be perceptible. For example, if we
-suppose an inch to be divided into ten million of equal parts, one of
-those parts by itself will not be visible to the eye. Therefore, in
-finding a length, an error of a ten-millionth part of an inch is of no
-consequence, even where the finest measurement is necessary. Now, by
-carrying on the table in (129), we shall see that</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1428571</td>
- <td class="tdc" rowspan="2">&nbsp;does not differ from&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;by&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc over">10000000</td>
- <td class="tdc over">&nbsp;7&nbsp;</td>
- <td class="tdc over">10000000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and if these fractions represented parts of an
-inch, the first might be used for the second, since the difference is
-not perceptible. In applying arithmetic to practice, nothing can be
-measured so accurately as to be represented in numbers without any
-error whatever, whether it be length, weight, or any other species of
-magnitude. It is therefore unnecessary to use any other than decimal
-fractions, since, by means of them, any quantity may be represented
-with as much correctness as by any other method.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Find decimal fractions which do not differ from the following fractions
-by <span class="fontsize_150">¹/₁₀₀₀₀₀₀₀₀</span>.</p>
-
-<table class="fontsize_150 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdl">⅓</td>
- <td class="tdl_top" rowspan="4">&nbsp;&emsp;<span class="fontsize_80"><i>Answer</i>,</span>&nbsp;</td>
- <td class="tdc">³³³³³³³³/₁₀₀₀₀₀₀₀₀.</td>
- </tr><tr>
- <td class="tdl">⁴/₇</td>
- <td class="tdc">⁵⁷¹⁴²⁸⁵⁷/₁₀₀₀₀₀₀₀₀.</td>
- </tr><tr>
- <td class="tdl">¹¹³/₃₅₅</td>
- <td class="tdc">³¹⁸³⁰⁹⁸⁵/₁₀₀₀₀₀₀₀₀.</td>
- </tr><tr>
- <td class="tdl">³⁵⁵/₁₁₃</td>
- <td class="tdc">³¹⁴¹⁵⁹²⁹²/₁₀₀₀₀₀₀₀₀.</td>
- </tr>
- </tbody>
-</table>
-
-<p>132. Every decimal may be immediately reduced to a quantity consisting
-either of a whole number and more simple decimals, or of more
-simple decimals alone, having one figure only in each of the numerators.
-Take, for example,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">147326</td>
- <td class="tdc" rowspan="2">.&nbsp;&emsp;By (115)&nbsp;</td>
- <td class="tdc">147326</td>
- <td class="tdc" rowspan="2">&nbsp;is 147</td>
- <td class="tdc">326</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc over">1000</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">1000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and since 326 is made up of 300, and 20, and 6; by (112)
-³²⁶/₁₀₀₀₀ = ³⁰⁰/₁₀₀₀ + ²⁰/₁₀₀₀ + ⁶/₁₀₀₀. But (108) ³⁰⁰/₁₀₀₀ is ³/₁₀, and ²⁰/₁₀₀₀
-is ²/₁₀₀. Therefore, ¹¹⁴⁷³²6/₁₀₀₀ is made up of 147 + ³/₁₀ + ²/₁₀₀ +
-6/₁₀₀₀. Now, take any number, for example, 147326, and form a number
-of fractions having for their numerators this number, and for their
-<span class="pagenum" id="Page_70">[Pg 70]</span>
-denominators 1, 10, 100, 1000, 10000, &amp;c., and
-reduce these fractions into numbers and more simple decimals, in the
-foregoing manner, which will give the table below.</p>
-
-<p class="f120 space-above1">DECOMPOSITION OF A DECIMAL FRACTION.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr u">147326</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr" rowspan="2">147326</td>
- <td class="tdc" colspan="14" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;</td>
- </tr><tr>
- <td class="tdr u">147326</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr" rowspan="2">14732</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- <td class="tdc" colspan="12" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">10&nbsp;&nbsp;&nbsp;&nbsp;</td>
- <td class="tdc over">10</td>
- </tr><tr>
- <td class="tdr u">147326</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr" rowspan="2">1473</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- <td class="tdc" colspan="10" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">100&nbsp;&nbsp;&nbsp;</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- </tr><tr>
- <td class="tdr u">147326</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr" rowspan="2">147</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- <td class="tdc" colspan="8" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1000&nbsp;&nbsp;</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- </tr><tr>
- <td class="tdr u">147326</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr" rowspan="2">14</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- <td class="tdc" colspan="6" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">10000&nbsp;</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- </tr><tr>
- <td class="tdr">147326</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdr" rowspan="2">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- <td class="tdc" colspan="4" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr over">100000</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- </tr><tr>
- <td class="tdr">147326&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr over">1000000</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc over">1000000</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">147326&nbsp;&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- </tr><tr>
- <td class="tdr over">10000000</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc over">1000000</td>
- <td class="tdc over">10000000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="blockquot no-indent fontsize_120">N.B. The student should write this table himself,
-and then proceed to make similar tables from the following exercises.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Reduce the following fractions into a series of numbers and more simple
-fractions:</p>
-
-<table class="no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdl u">31415926</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&nbsp;</span></td>
- <td class="tdc u">31415926</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&amp;c.</span></td>
- </tr><tr>
- <td class="tdc">10</td>
- <td class="tdc">100</td>
- </tr><tr>
- <td class="tdl u">2700031</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&nbsp;</span></td>
- <td class="tdc u">2700031</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&amp;c.</span></td>
- </tr><tr>
- <td class="tdc">10</td>
- <td class="tdc">100</td>
- </tr><tr>
- <td class="tdl u">2073000</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&nbsp;</span></td>
- <td class="tdc u">2073000</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&amp;c.</span></td>
- </tr><tr>
- <td class="tdc">10</td>
- <td class="tdc">100</td>
- </tr><tr>
- <td class="tdl u">3331303</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&nbsp;</span></td>
- <td class="tdc u">3331303</td>
- <td class="tdc" rowspan="2">,<span class="ws2">&amp;c.</span></td>
- </tr><tr>
- <td class="tdc">1000</td>
- <td class="tdc">10000</td>
- </tr>
- </tbody>
-</table>
-
-<p>133. If, in this table, and others made in the same manner, you look at
-those fractions which contain a whole number, you will see that they may
-<span class="pagenum" id="Page_71">[Pg 71]</span>
-be made thus: Mark off, from the right hand of the numerator, as many
-<i>figures</i> as there are <i>ciphers</i> in the denominator by a
-point, or any other convenient mark.</p>
-
-<table class="no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdl" rowspan="2">This will give</td>
- <td class="tdr" rowspan="2">14732·6</td>
- <td class="tdc" rowspan="2">when the fraction is</td>
- <td class="tdr u">147326</td>
- </tr><tr>
- <td class="tdc">10</td>
- </tr><tr>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdr" rowspan="2">1473·26</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdr u">147326</td>
- </tr><tr>
- <td class="tdc">100</td>
- </tr><tr>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdr" rowspan="2">147·326</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdr u">147326</td>
- </tr><tr>
- <td class="tdc">1000</td>
- </tr><tr>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc" rowspan="2">&amp;c.</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">&amp;c.</td>
- </tr>
-</tbody>
-</table>
-
-<p>The figures on the left of the point by themselves make the whole
-number which the fraction contains. Of those on its right, the first
-is the numerator of the fraction whose denominator is 10, the second
-of that whose denominator is 100, and so on. We now come to those
-fractions which do not contain a whole number.</p>
-
-<p>134. The first of these is <big>¹⁴⁷³²⁶/₁₀₀₀₀₀₀</big> which the number of
-<i>ciphers</i> in the denominator is the same as the number of
-<i>figures</i> in the numerator. If we still follow the same rule, and
-mark off all the figures, by placing the point before them all, thus,
-·147326, the observation in (133) still holds good; for, on looking at
-<big>¹⁴⁷³²⁶/₁₀₀₀₀₀₀</big> in the table, we find it is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- </tr><tr>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc over">1000000</td>
- </tr>
- </tbody>
-</table>
-
-<p>The next fraction is <big>¹⁴⁷³²⁶/₁₀₀₀₀₀₀₀</big>, which we find by the table to be</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- </tr><tr>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc over">1000000</td>
- <td class="tdc over">10000000</td>
- </tr>
- </tbody>
-</table>
-
-<p>In this, 1 is not divided by 10, but by 100; if, therefore, we put a
-point before the whole, the rule is not true, for the first figure on
-the left of the point has the denominator which, according to the rule,
-the second ought to have, the second that which the third ought to
-have, and so on. In order to keep the same rule for this case, we must
-contrive to make 1 the second figure on the right of the point instead
-of the first. This may be done by placing a cipher between it and the
-<span class="pagenum" id="Page_72">[Pg 72]</span>
-point, thus, ·0147326. Here the rule holds good, for by that rule this
-fraction is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">0</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">7</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">6</td>
- </tr><tr>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc over">1000000</td>
- <td class="tdc over">10000000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which is the same as the preceding line, since <big>⁰/₁₀</big> is 0,
-and need not be reckoned.</p>
-
-<p>Similarly, when there are two ciphers more in the denominator than
-there are figures in the numerator, the rule will be true if we place
-two ciphers between the point and the numerator. The rule, therefore,
-stated fully, is this:</p>
-
-<p>To reduce a decimal fraction to a whole number and more simple
-decimals, or to more simple decimals alone if it do not contain a whole
-number, mark off by a point as many figures from the numerator as
-there are ciphers in the denominator. If the numerator have not places
-enough for this, write as many ciphers before it as it wants places,
-and put the point before these ciphers. Then, if there be any figures
-before the point, they make the <i>whole number</i> which the fraction
-contains. The first figure after the point with the denominator 10, the
-second with the denominator 100, and so on, are the <i>fractions</i> of
-which the first fraction is composed.</p>
-
-<p>135. Decimal fractions are not usually written at full length. It is
-more convenient to write the numerator only, and to cut off from the
-numerator as many figures as there are ciphers in the denominator,
-when that is possible, by a point. When there are more ciphers in the
-denominator than figures in the numerator, as many ciphers are placed
-before the numerator as will supply the deficiency, and the point is
-placed before the ciphers. Thus, ·7 will be used in future to denote
-⁷/₁₀, ·07 for ⁷/₁₀₀, and so on. The following tables will give the
-whole of this notation at one view, and will shew its connexion with
-the decimal notation explained in the first section. You will observe
-that the numbers on the right of the units’ place stand for units
-<i>divided</i> by 10, 100, 1000, &amp;c. while those on the left are
-units <i>multiplied</i> by 10, 100, 1000, &amp;c.
-<span class="pagenum" id="Page_73">[Pg 73]</span></p>
-
-<p>The student is recommended always to write the decimal point in a line
-with the top of the figures or in the middle, as is done here, and
-never at the bottom. The reason is, that it is usual in the higher
-branches of mathematics to use a point placed between two numbers
-or letters which are multiplied together; thus, 15. 16, <i>a</i>.
-<i>b</i>, (<span class="over"><i>a</i> + <i>b</i></span>). (<span class="over"><i>c</i> + <i>d</i></span>)
-stand for the products of those numbers or letters.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdr_top" rowspan="12">I.&nbsp;&nbsp;</td>
- <td class="tdl" rowspan="2">123·4  stands for</td>
- <td class="tdc u">1234</td>
- <td class="tdl" rowspan="2">or <big>123</big></td>
- <td class="tdc">4</td>
- <td class="tdc" rowspan="2">or <big>123</big> +</td>
- <td class="tdc">4</td>
- <td class="tdc" colspan="10">&nbsp;</td>
- </tr><tr>
- <td class="tdc">10</td>
- <td class="tdc over">10</td>
- <td class="tdc over">10</td>
- <td class="tdc" colspan="10">&nbsp;</td>
- </tr><tr class="greyish">
- <td class="tdl" rowspan="2">12·34</td>
- <td class="tdc u">1234</td>
- <td class="tdr" rowspan="2">or <big>12</big></td>
- <td class="tdc">34</td>
- <td class="tdc" rowspan="2">or <big>12</big> +</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr class="greyish">
- <td class="tdc">100</td>
- <td class="tdc over">100</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2">1·234</td>
- <td class="tdc u">1234</td>
- <td class="tdr" rowspan="2">or <big>1</big></td>
- <td class="tdc">234</td>
- <td class="tdc" rowspan="2">or <big>1</big> +</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1000</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr class="greyish">
- <td class="tdl" rowspan="2">·1234</td>
- <td class="tdc">1234</td>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">or</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr class="greyish">
- <td class="tdc over">10000</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdl" rowspan="2">·01234</td>
- <td class="tdc">1234</td>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">or</td>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc over">100000</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr class="greyish">
- <td class="tdl" rowspan="2">·001234</td>
- <td class="tdc">1234</td>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">or</td>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">4</td>
- </tr><tr class="greyish">
- <td class="tdc over">1000000</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- <td class="tdc over">100000</td>
- <td class="tdc over">1000000</td>
- </tr>
- </tbody>
-</table>
-<hr class="chap x-ebookmaker-drop" />
-<table class="fontsize_120 no-wrap space-above2" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdr_top" rowspan="8">II.&nbsp;&nbsp;</td>
- <td class="tdl" rowspan="2">·01003  is&nbsp;</td>
- <td class="tdc">1003</td>
- <td class="tdl" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- </tr><tr>
- <td class="tdc over">100000</td>
- <td class="tdc over">100</td>
- <td class="tdc over">100000</td>
- </tr><tr class="greyish">
- <td class="tdl" rowspan="2">·1003  is&nbsp;</td>
- <td class="tdc">1003</td>
- <td class="tdl" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- </tr><tr class="greyish">
- <td class="tdc over">10000</td>
- <td class="tdc over">&nbsp;10&nbsp;</td>
- <td class="tdc over">10000</td>
- </tr><tr>
- <td class="tdl" rowspan="2">10·03  is&nbsp;</td>
- <td class="tdc u">1003</td>
- <td class="tdl" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc" rowspan="2"><big>10</big></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- </tr><tr>
- <td class="tdc">100</td>
- <td class="tdc over">100</td>
- </tr><tr class="greyish">
- <td class="tdl" rowspan="2">100·3  is&nbsp;</td>
- <td class="tdc u">1003</td>
- <td class="tdl" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc" rowspan="2"><big>100</big></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- </tr><tr class="greyish">
- <td class="tdc">10</td>
- <td class="tdc over">10</td>
- </tr>
- </tbody>
-</table>
-<hr class="chap x-ebookmaker-drop" />
-<table class="fontsize_120 no-wrap space-above2" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdr_top" rowspan="6">III.&nbsp;&nbsp;</td>
- <td class="tdl_top" rowspan="6">·1238 </td>
- <td class="tdl" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">8</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">3</td>
- </tr><tr>
- <td class="tdc over">10</td>
- <td class="tdc over">100</td>
- <td class="tdc over">1000</td>
- <td class="tdc over">10000</td>
- </tr><tr>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">&nbsp;·1</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdl">·02</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">·008</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">·0003</td>
- </tr><tr>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">&nbsp;·1</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">·0283</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">·12</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">·0083</td>
- </tr><tr>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">&nbsp;·128</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">·0003</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">·108</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">·0203</td>
- </tr><tr>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">&nbsp;·1003</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdl">·028</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">·1203</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdl">·008
- <span class="pagenum" id="Page_74">[Pg 74]</span></td>
- </tr>
- </tbody>
-</table>
-<hr class="chap x-ebookmaker-drop" />
-
-<table class="fontsize_120 no-wrap space-above2" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdr_top" rowspan="9">IV.&nbsp;&nbsp;</td>
- <td class="tdr" rowspan="9">In 1234·56789&nbsp;<br />inches the&nbsp;</td>
- <td class="tdl" rowspan="9"><img src="images/cbl-9.jpg" alt="" width="46" height="196" />&nbsp;</td>
- <td class="tdl">1 is&nbsp;</td>
- <td class="tdl">1000</td>
- <td class="tdl_ws1">inches</td>
- </tr><tr>
- <td class="tdl">2 is&nbsp;</td>
- <td class="tdl">200</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdl">3 is&nbsp;</td>
- <td class="tdl">30</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdl">4 is&nbsp;</td>
- <td class="tdl">4</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdl">5 is&nbsp;</td>
- <td class="tdl"><big>⁵/₁₀</big></td>
- <td class="tdl_ws1">of an inch</td>
- </tr><tr>
- <td class="tdl">6 is&nbsp;</td>
- <td class="tdl"><big>⁶/₁₀₀</big></td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdl">7 is&nbsp;</td>
- <td class="tdl"><big>⁷/₁₀₀₀</big></td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdl">8 is&nbsp;</td>
- <td class="tdl"><big>⁸/₁₀₀₀₀</big></td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdl">9 is&nbsp;</td>
- <td class="tdl"><big>⁹/₁₀₀₀₀₀</big></td>
- <td class="tdl">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="space-above1">136. The ciphers on the right hand of the
-decimal point serve the same purpose as the ciphers in (10). They are
-not counted as any thing themselves, but serve to shew the place in
-which the accompanying numbers stand. They might be dispensed with by
-writing the numbers in ruled columns, as in the first section. They
-are distinguished from the numbers which accompany them by calling the
-latter <i>significant figures</i>. Thus, ·0003747 is a decimal of seven
-places with four significant figures, ·346 is a decimal of three places
-with three significant figures, &amp;c.</p>
-
-<p>137. The value of a decimal is not altered by putting any number of
-ciphers on its right. Take, for example, ·3 and ·300. The first (135)
-is <big>³/₁₀</big>, and the second <big>³⁰⁰/₁₀₀₀</big>, which is made
-from the first by multiplying both its numerator and denominator by
-100, and (108) is the same quantity.</p>
-
-<p>138. To reduce two decimals to a common denominator, put as many
-ciphers on the right of that which has the smaller number of places
-as will make the number of places in both fractions the same. Take,
-for example, ·54 and 4·3297. The first is ⁵⁴/₁₀₀, and the second
-<big>⁴³²⁹⁷/₁₀₀₀₀</big>. Multiply the numerator and denominator of
-the first by 100 (108), which reduces it to <big>⁵⁴⁰⁰/₁₀₀₀₀</big>,
-which has the same denominator as <big>⁴³²⁹⁷/₁₀₀₀₀</big>. But
-<big>⁵⁴⁰⁰/₁₀₀₀₀</big> is ·5400 (135). In whole numbers, the <span
-class="pagenum" id="Page_75">[Pg 75]</span> decimal point should
-be placed at the end: thus, 129 should be written 129·. It is,
-however, usual to omit the point; but you must recollect that 129 and
-129·000 are of the same value, since the first is 129 and the second
-<big>¹²⁹⁰⁰⁰/₁₀₀₀</big>.</p>
-
-<p>139. The rules which were given in the last chapter for addition,
-subtraction, multiplication, and division, apply to all fractions, and
-therefore to decimal fractions among the rest. But the way of writing
-decimal fractions, which is explained in this chapter, makes the
-application of these rules more simple. We proceed to the different cases.</p>
-
-<p>Suppose it required to add 42·634, 45·2806, 2·001, and 54. By (112)
-these must be reduced to a common denominator, which is done (138) by
-writing them as follows: 42·6340, 45·2806, 2·0010, and 54·0000. These
-are decimal fractions, whose numerators are 426340, 452806, 20010, and
-540000, and whose common denominator is 10000. By (112) their sum is</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl u">426340 + 452806 + 20010 + 540000</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;which is&nbsp;&nbsp;</td>
- <td class="tdl u">1439156</td>
- </tr><tr>
- <td class="tdc">10000</td>
- <td class="tdc">10000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">or 143·9156. The simplest way of doing this is as
-follows: write the decimals down under one another, so that the decimal
-points may fall under one another, thus:</p>
-
-<ul class="index">
-<li class="isub1">42·634</li>
-<li class="isub1">45·2806</li>
-<li class="isub1">&#8199;2·001</li>
-<li class="isub1">54</li>
-<li class="isub1 over">143·9156</li>
-</ul>
-
-<p class="no-indent">Add the different columns together as in common addition, and place the
-decimal point under the other decimal points.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">What are</td>
- <td class="tdl_ws1">1527 + 64·732094 + 2·0013 + ·00001974;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">2276·3 + ·107 + ·9 + 26·3172 + 56732·001;</td>
- </tr><tr>
- <td class="tdr">and</td>
- <td class="tdl_ws1">&#8199;&#8199;1·11 + 7·7 + ·0039 + ·00142 + ·8838?</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr"><i>Answer</i>,</td>
- <td class="tdl_ws1">1593·73341374, 59035·6252, 9·69912.</td>
- </tr>
- </tbody>
-</table>
-
-<p>140. Suppose it required to subtract 91·07324 from 137·321. These
-fractions when reduced to a common denominator are 91·07324 and
-137·32100 (138). Their difference is therefore</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl u">13732100 - 9107324</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;which is&nbsp;&nbsp;</td>
- <td class="tdl u">4624776</td>
- </tr><tr>
- <td class="tdc">100000</td>
- <td class="tdc">100000</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_76">[Pg 76]</span>
-or 46·24776. This may be most simply done as follows: write the less
-number under the greater, so that its decimal point may fall under that
-of the greater, thus:</p>
-
-<ul class="index">
-<li class="isub1">137·321</li>
-<li class="isub1">&#8199;91·07324</li>
-<li class="isub1 over">&#8199;46·24776</li>
-</ul>
-
-<p class="no-indent">Subtract the lower from the upper line, and
-wherever there is a figure in one line and not in the other, proceed as
-if there were a cipher in the vacant place.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">What is</td>
- <td class="tdl_ws1">12362 - 274·22107 + ·5;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">9976·2073942 - ·00143976728;</td>
- </tr><tr>
- <td class="tdr">and</td>
- <td class="tdl_ws1">1·2 + ·03 + ·004 - ·0005?</td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr"><i>Answer</i>,</td>
- <td class="tdl_ws1">12088·27893, 9976·20595443272; and 1·2335.</td>
- </tr>
- </tbody>
-</table>
-
-<p>141. The multiplication of a decimal by 10, 100, 1000, &amp;c.,
-is performed by merely moving the decimal point to the right.
-Suppose, for example, 13·2079 is to be multiplied by 100. The
-decimal is <big>¹³²⁰⁷⁹/₁₀₀₀₀</big>, which multiplied by 100 is
-(117) <big>¹³²⁰⁷⁹/₁₀₀</big>, or 1320·79. Again, 1·309 × 100000 is
-<big>¹³⁰⁹/₁₀₀₀</big> × 100000, or (116) <big>¹³⁰⁹⁰⁰⁰⁰⁰/₁₀₀₀</big> or
-130900. From these and other instances we get the following rule: To
-multiply a decimal fraction by a decimal number (126), move the decimal
-point as many places to the right as there are ciphers in the decimal
-number. When this cannot be done, annex ciphers to the right of the
-decimal (137) until it can.</p>
-
-<p>142. Suppose it required to multiply 17·036 by 4·27. The
-first of these decimals is <big>¹⁷⁰³⁶/₁₀₀₀</big>, and the second
-<big>⁴²⁷/₁₀₀</big>. By (118) the product of these fractions has
-for its numerator the product of 17036 and 427, and for its
-denominator the product of 1000 and 100; therefore this product is
-<big>⁷²⁷⁴³⁷²/₁₀₀₀₀₀</big>, or 72·74372. This may be done more shortly
-by multiplying the two numbers 17036 and 427, and cutting off by the
-decimal point as many places as there are decimal places both in 17·036
-and 4·27, because the product of two decimal numbers will contain as
-many ciphers as there are ciphers in both.
-<span class="pagenum" id="Page_77">[Pg 77]</span></p>
-
-<p>143. This question now arises: What if there should not be as many
-figures in the product as there are decimal places in the multiplier
-and multiplicand together? To see what must be done in this case,
-multiply ·172 by ·101, or <big>¹⁷²/₁₀₀₀</big> by <big>¹⁰¹/₁₀₀₀</big>.
-The product of these two is <big>¹⁷³⁷²/₁₀₀₀₀₀₀</big>, or ·017372 (135).
-Therefore, when the number of places in the product is not sufficient
-to allow the rule of the last article to be followed, as many ciphers
-must be placed at the beginning as will make up the deficiency.</p>
-
-<p class="f120 space-above1">ADDITIONAL EXAMPLES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">·001 × ·01 is</td>
- <td class="tdl_ws1">·00001</td>
- </tr><tr>
- <td class="tdr">56 × ·0001 is</td>
- <td class="tdl_ws1">·0056.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Shew that</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">3·002 × 3·002</td>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">3 × 3 + 2 × 3 × ·002 + ·002 × ·002</td>
- </tr><tr>
- <td class="tdr">11·5609 × 5·3191</td>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">8·44 × 8·44 - 3·1209 × 3·1209</td>
- </tr><tr>
- <td class="tdr">8·217 × 10·001</td>
- <td class="tdl">&nbsp;=&nbsp;</td>
- <td class="tdl">8 × 10 + 8 × ·001 + 10 × ·217 + ·001 × ·217.</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above1" border="0" cellspacing="2" summary=" " cellpadding="2" rules="cols">
- <thead><tr>
- <th class="tdc bb">Fraction.</th>
- <th class="tdc bb">Square.</th>
- <th class="tdc bb">Cube.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdr_ws1">82·92</td>
- <td class="tdr_ws1">6875·7264</td>
- <td class="tdr_ws1">570135·233088</td>
- </tr><tr>
- <td class="tdr_ws1">·0173</td>
- <td class="tdr_ws1">·00029929</td>
- <td class="tdr_ws1">·000005177717</td>
- </tr><tr>
- <td class="tdr_ws1">1·43</td>
- <td class="tdr_ws1">2·0449</td>
- <td class="tdr_ws1">2·924207</td>
- </tr><tr>
- <td class="tdr_ws1">·009</td>
- <td class="tdr_ws1">·000081</td>
- <td class="tdr_ws1">·000000729</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap space-above1" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">15·625</td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdl">&nbsp;64</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">1000</td>
- </tr><tr>
- <td class="tdr">1·5625</td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdl">·64</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">1</td>
- </tr><tr>
- <td class="tdr">·015625</td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdl">·0064</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">·0001</td>
- </tr><tr>
- <td class="tdr">·15625</td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdl">·64</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">·1</td>
- </tr><tr>
- <td class="tdr">1562·5</td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdl">·064</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">100</td>
- </tr><tr>
- <td class="tdr">15625000</td>
- <td class="tdc">&nbsp;×&nbsp;</td>
- <td class="tdl">·064</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">1000000</td>
- </tr>
- </tbody>
-</table>
-
-<p>144. The division of a decimal by a decimal number, such as 10, 100,
-1000, &amp;c., is performed by moving the decimal point as many places to
-the left as there are ciphers in the decimal number. If there are not
-places enough in the dividend to allow of this, annex ciphers to the
-beginning of it until there are. For example, divide 1734·229 by 1000:
-the decimal fraction is <big>¹⁷³⁴²²⁹/₁₀₀₀</big>, which divided by 1000 (123) is
-<big>¹⁷³⁴²²⁹/₁₀₀₀₀₀₀</big>, or 1·734229. If, in the same way, 1·2106 be divided by
-10000, the result is ·00012106.
-<span class="pagenum" id="Page_78">[Pg 78]</span></p>
-
-<p>145. Before proceeding to shorten the rule for the division of one
-decimal fraction by another, it will be necessary to resume what was
-said in (128) upon the reduction of any fraction to a decimal fraction.
-It was there shewn that <big>⁷/₁₆</big> is the same fraction as <big>⁴³⁷⁵/₁₀₀₀₀</big> or ·4375.
-As another example, convert <big>³/₁₂₈</big> into a decimal fraction. Follow the
-same process as in (128), thus:</p>
-
-<ul class="index">
-<li class="isub3">128)300000000000(234375</li>
-<li class="isub5 u">256</li>
-<li class="isub5-5">440</li>
-<li class="isub5-5 u">384</li>
-<li class="isub6">560</li>
-<li class="isub6 u">512</li>
-<li class="isub6-5">480</li>
-<li class="isub6-5 u">384</li>
-<li class="isub7">960</li>
-<li class="isub7 u">896</li>
-<li class="isub7-5">640</li>
-<li class="isub7-5 u">640</li>
-<li class="isub8-5">0</li>
-</ul>
-
-<p>Since 7 ciphers are used, it appears that 30000000 is the first of the
-series 30, 300, &amp;c., which is divisible by 128; and therefore ³/₁₂₈
-or, which is the same thing (108), <big>³⁰⁰⁰⁰⁰⁰⁰/₁₂₈₀₀₀₀₀₀₀</big> is equal to
-<big>²³⁴³⁷⁵/₁₀₀₀₀₀₀₀</big> or ·0234375 (135).</p>
-
-<p>From these examples the rule for reducing a fraction to a decimal is:
-Annex ciphers to the numerator; divide by the denominator, and annex
-a cipher to each remainder after the figures of the numerator are all
-used, proceeding exactly as if the numerator had an unlimited number
-of ciphers annexed to it, and was to be divided by the denominator.
-Continue this process until there is no remainder, and observe how many
-ciphers have been used. Place the decimal point in the quotient so as
-to cut off as many figures as you have used ciphers; and if there be
-not figures enough for this, annex ciphers to the beginning until there
-are places enough.</p>
-
-<p>146. From what was shewn in (129), it appears that it is not every
-fraction which can be reduced to a decimal fraction. It was there
-shewn, however, that there is no fraction to which we may not find a
-decimal fraction as near as we please. Thus, <big>¹/₁₀, ¹⁴/₁₀₀, ¹⁴²/₁₀₀₀,
-¹⁴²⁸/₁₀₀₀₀, ¹⁴²⁸⁵/₁₀₀₀₀₀</big>, &amp;c., or ·1, ·14, ·142, ·1428, ·14285, were
-shewn to be fractions which approach nearer and nearer to ¹/₇. To find
-either of these fractions, the rule is the same as that in the last
-<span class="pagenum" id="Page_79">[Pg 79]</span>
-article, with this exception, that, I. instead of stopping when there
-is no remainder, which never happens, stop at any part of the process,
-and make as many decimal places in the quotient as are equal in number
-to the number of ciphers which have been used, annexing ciphers to the
-beginning when this cannot be done, as before. II. Instead of obtaining
-a fraction which is exactly equal to the fraction from which we set
-out, we get a fraction which is very near to it, and may get one still
-nearer, by using more of the quotient. Thus, ·1428 is very near to <big>¹/₇</big>,
-but not so near as ·142857; nor is this last, in its turn, so near as
-·142857142857, &amp;c.</p>
-
-<p>147. If there should be ciphers in the numerator of a fraction, these
-must not be reckoned with the number of ciphers which are necessary in
-order to follow the rule for changing it into a decimal fraction. Take,
-for example, <big>¹⁰⁰/₁₂₅</big>; annex ciphers to the numerator, and divide by the
-denominator. It appears that 1000 is divisible by 125, and that the
-quotient is 8. One cipher only has been annexed to the numerator, and
-therefore 100 divided by 125 is ·8. Had the fraction been <big>¹/₁₂₅</big>, since
-1000 divided by 125 gives 8, and three ciphers would have been annexed
-to the numerator, the fraction would have been ·008.</p>
-
-<p>148. Suppose that the given fraction has ciphers at the right of its
-denominator; for example, <big>³¹/₂₅₀₀</big>. Then annexing a cipher to the
-numerator is the same thing as taking one away from the denominator;
-for, (108) ³¹⁰/₂₅₀₀ is the same thing as <big>³¹/₂₅₀</big>, and <big>³¹⁰/₂₅₀</big>
-as <big>³¹/₂₅</big>. The rule, therefore, is in this case: Take away the ciphers
-from the denominator.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Reduce the following fractions to decimal fractions:</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc">36</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc">297</td>
- <td class="tdc" rowspan="2">, and</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc over">800</td>
- <td class="tdc over">1250</td>
- <td class="tdc over">64</td>
- <td class="tdc over">128</td>
- </tr><tr>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdl" colspan="8"><i>Answer</i>, ·00125, ·0288, 4·640625,</td>
- </tr><tr>
- <td class="tdr" colspan="3">and</td>
- <td class="tdl" colspan="5">·0078125.</td>
- </tr>
- </tbody>
-</table>
-
-<p>Find decimals of 6 places very near to the following fractions:
-<span class="pagenum" id="Page_80">[Pg 80]</span></p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">27</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc u">156</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc">22</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc u">194</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc">2637</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">,</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">, and</td>
- <td class="tdc">3</td>
- <td class="tdc" rowspan="2">.</td>
- </tr><tr>
- <td class="tdr over">49</td>
- <td class="tdc">33</td>
- <td class="tdc over">37000</td>
- <td class="tdc">13</td>
- <td class="tdc over">9907</td>
- <td class="tdc over">2908</td>
- <td class="tdc over">466</td>
- <td class="tdc over">277</td>
- </tr><tr>
- <td class="tdc" colspan="16">&nbsp;</td>
- </tr><tr>
- <td class="tdl"><i>Answer</i>,</td>
- <td class="tdl" colspan="15">·551020, 4·727272, ·000594, 14·923076, ·266175,</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl" colspan="16">·000343,  ·002145,  and ·010830.</td>
- </tr>
- </tbody>
-</table>
-
-<p>149. From (121) it appears, that if two fractions have the same
-denominator, the first may be divided by the second by dividing the
-numerator of the first by the numerator of the second. Suppose it
-required to divide 17·762 by 6·25. These fractions (138), when reduced
-to a common denominator, are 17·762 and 6·250, or ¹⁷⁷⁶²/₁₀₀₀ and
-⁶²⁵⁰/₁₀₀₀. Their quotient is therefore ¹⁷⁷⁶²/₆₂₅₀, which must now be
-reduced to a decimal fraction by the last rule. The process at full
-length is as follows: Leave out the cipher in the denominator, and
-annex ciphers to the numerator, or, which will do as well, to the
-remainders, when it becomes necessary, and divide as in (145).</p>
-
-<ul class="index">
-<li class="isub3">625)17762(284192</li>
-<li class="isub5 u">1250</li>
-<li class="isub5-5">5262</li>
-<li class="isub5-5 u">5000</li>
-<li class="isub6">2620</li>
-<li class="isub6 u">2500</li>
-<li class="isub6-5">1200</li>
-<li class="isub6-5 u">&#8199;625</li>
-<li class="isub7">5750</li>
-<li class="isub7 u">5625</li>
-<li class="isub7-5">1250</li>
-<li class="isub7-5 u">1250</li>
-<li class="isub9">0</li>
-</ul>
-
-<p>Here four ciphers have been annexed to the numerator, and one has been
-taken from the denominator. Make five decimal places in the quotient,
-which then becomes 2·84192, and this is the quotient of 17·762 divided
-by 6·25.</p>
-
-<p>150. The rule for division of one decimal by another is as follows:
-Equalise the number of decimal places in the dividend and divisor,
-by annexing ciphers to that which has fewest places. Then, further,
-annex as many ciphers to the dividend<a id="FNanchor_18" href="#Footnote_18" class="fnanchor">[18]</a>
-as it is required to have decimal places, throw away the decimal point,
-and operate as in common division. Make the required number of decimal
-places in the quotient.</p>
-
-<p>Thus, to divide 6·7173 by ·014 to three decimal places, I first write
-6·7173 and ·0140, with four places in each. Having to provide for three
-decimal places, I should annex three ciphers to 6·7173; but, observing
-<span class="pagenum" id="Page_81">[Pg 81]</span>
-that the divisor ·0140 has one cipher, I strike that one out and annex
-two ciphers to 6·7173. Throwing away the decimal points, then divide
-6717300 by 014 or 14 in the usual way, which gives the quotient 479807
-and the remainder 2. Hence 479·807 is the answer.</p>
-
-<p>The common rule is: Let the quotient contain as many decimal places
-as there are decimal places in the dividend more than in the divisor.
-But this rule becomes inoperative except when there are more decimals
-in the dividend than in the divisor, and a number of ciphers must
-be annexed to the former. The rule in the text amounts to the same
-thing, and provides for an assigned number of decimal places. But the
-student is recommended to make himself familiar with the rule of the
-<i>characteristic</i> <a href="#APPENDIX_V">given in the Appendix</a>,
-and also to accustom himself to <i>reason out</i> the place of the
-decimal point. Thus, it should be visible, that 26·119 ÷ 7·2436 has
-one figure before the decimal point, and that 26·119 ÷ 724·36 has one
-cipher after it, preceding all significant figures.</p>
-
-<p>Or the following rule may be used: Expunge the decimal point of the
-divisor, and move that of the dividend as many places to the right
-as there were places in the divisor, using ciphers if necessary.
-Then proceed as in common division, making one decimal place in the
-quotient for every decimal place of the final dividend which is used.
-Thus 17·314 divided by 61·2 is 173·14 divided by 612, and the decimal
-point must precede the first figure of the quotient. But 17·314 divided
-by 6617·5 is 173·14 by 66175; and since three decimal places of
-173·14000 ... must be used before a quotient figure can be found, that
-quotient figure is the third decimal place, or the quotient is ·002.....</p>
-
-<p class="f120 space-above1">EXAMPLES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">3·1</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;1240,<span class="ws2">&nbsp;</span></td>
- <td class="tdc u">·00062</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;·00096875</td>
- </tr><tr>
- <td class="tdc over">·0025</td>
- <td class="tdc">·64</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Shew that</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">15·006 × 15·006 - ·004 × ·004</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;15·002,</td>
- </tr><tr>
- <td class="tdc">15·01</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and that</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">·01 × ·01 × ·01 + 2·9 × 2·9 × 2·9</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;2·9 × 2·9 - 2·9 × ·01 + ·01 × ·01</td>
- </tr><tr>
- <td class="tdc">2·91</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_82">[Pg 82]</span>What are</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">,&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">, and&nbsp;</td>
- <td class="tdc">365</td>
- <td class="tdc" rowspan="2">,</td>
- </tr><tr>
- <td class="tdc over">3·14159</td>
- <td class="tdc over">2·7182818</td>
- <td class="tdc over">·18349</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">as far as 6 places of decimals?&mdash;<i>Answer</i>,
-·318310, ·367879, and 1989·209221.</p>
-
-<p>Calculate 10 terms of each of the following series, as far as 5 places
-of decimals.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><big>1</big></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c. =</td>
- <td class="tdc" rowspan="2">&nbsp;·71824.</td>
- </tr><tr>
- <td class="tdc over">&nbsp;2&nbsp;</td>
- <td class="tdc over">2 × 3</td>
- <td class="tdc over">2 × 3 × 4</td>
- <td class="tdc over">2 × 3 × 4 × 5</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><span class="ws8">&nbsp;</span></td>
- <td class="tdc" rowspan="2"><big>1</big></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c. =</td>
- <td class="tdc" rowspan="2">&nbsp;2·92895.</td>
- </tr><tr>
- <td class="tdc over">&nbsp;2&nbsp;</td>
- <td class="tdc over">&nbsp;3&nbsp;</td>
- <td class="tdc over">&nbsp;4&nbsp;</td>
- <td class="tdc over">&nbsp;5&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2"><span class="ws4">&nbsp;</span></td>
- <td class="tdc">80</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">81</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">82</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">83</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">84</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c. =</td>
- <td class="tdc" rowspan="2">&nbsp;9·88286.</td>
- </tr><tr>
- <td class="tdc over">81</td>
- <td class="tdc over">82</td>
- <td class="tdc over">83</td>
- <td class="tdc over">84</td>
- <td class="tdc over">85</td>
- </tr>
- </tbody>
-</table>
-
-<p>151. We now enter upon methods by which unnecessary trouble is saved in
-the computation of decimal quantities. And first, suppose a number of
-miles has been measured, and found to be 17·846217 miles. If you were
-asked how many miles there are in this distance, and a rough answer
-were required which should give miles only, and not parts of miles,
-you would probably say 17. But this, though the number of whole miles
-contained in the distance, is not the nearest number of miles; for,
-since the distance is more than 17 miles and 8 tenths, and therefore
-more than 17 miles and a half, it is nearer the truth to say, it is 18
-miles. This, though too great, is not so much too great as the other
-was too little, and the error is not so great as half a mile. Again,
-if the same were required within a tenth of a mile, the correct answer
-is 17·8; for though this is too little by ·046217, yet it is not so
-much too little as 17·9 is too great; and the error is less than half
-a tenth, or ¹/₂₀. Again, the same distance, within a hundredth of a
-mile, is more correctly 17·85 than 17·84, since the last is too little
-by ·006217, which is greater than the half of ·01; and therefore 17·84
-+ ·01 is nearer the truth than 17·84. Hence this general rule: When a
-certain number of the decimals given is sufficiently accurate for the
-purpose, strike off the rest from the right hand, observing, if the
-first figure struck off be equal to or greater than 5, to increase the
-last remaining figure by 1.</p>
-
-<p>The following are examples of a decimal abbreviated by one place
-at a time.
-<span class="pagenum" id="Page_83">[Pg 83]</span></p>
-
-<p class="f120">
-3·14159, 3·1416, 3·142, 3·14, 3·1, 3·0<br />
-2·7182818, 2·718282, 2·71828, 2·7183, 2·718, 2·72, 2·7, 3·0<br />
-1·9919, 1·992, 1·99, 2·00, 2·0</p>
-
-<p>152. In multiplication and division it is useless to retain more
-places of decimals in the result than were certainly correct in
-the multiplier, &amp;c., which gave that result. Suppose, for example,
-that 9·98 and 8·96 are distances in inches which have been measured
-correctly to two places of decimals, that is, within half a hundredth
-of an inch each way. The real value of that which we call 9·98 may be
-any where between 9·975 and 9·985, and that of 8·96 may be any where
-between 8·955 and 8·965. The product, therefore, of the numbers which
-represent the correct distances will lie between 9·975 × 8·955 and
-9·985 × 8·965, that is, taking three decimal places in the products,
-between 89·326 and 89·516. The product of the actual numbers given
-is 89·4208. It appears, then, that in this case no more than the
-whole number 89 can be depended upon in the product, or, at most,
-the first place of decimals. The reason is, that the error made in
-measuring 8·96, though only in the third place of decimals, is in
-the multiplication increased at least 9·975, or nearly 10 times;
-and therefore affects the second place. The following simple rule
-will enable us to judge how far a product is to be depended upon.
-Let <i>a</i> be the multiplier, and <i>b</i> the multiplicand; if
-these be true only to the first decimal place, the product is within
-(<i>a</i> + <i>b</i>)/20<a id="FNanchor_19" href="#Footnote_19" class="fnanchor">[19]</a>
-of the truth; if to two decimal places, within (<i>a</i> +
-<i>b</i>)/200; if to three, within (<i>a</i> + <i>b</i>)/2000; and so
-on. Thus, in the above example, we have 9·98 and 8·96, which are true
-to two decimal places: their sum divided by 200 is ·0947, and their
-product is 89·4208, which is therefore within ·0947 of the truth. If,
-in fact, we increase and diminish 89·4208 by ·0947, we get 89·5155
-and 89·3261, which are very nearly the limits found within which the
-product must lie. We see, then, that we cannot in this case depend upon
-the first place of decimals, as (151) an error of ·05 cannot exist if
-this place be correct; and here is a possible error of ·09 and upwards.
-<span class="pagenum" id="Page_84">[Pg 84]</span>
-It is hardly necessary to say, that if the numbers given be exact,
-their product is exact also, and that this article applies where the
-numbers given are correct only to a certain number of decimal places.
-The rule is: Take half the sum of the multiplier and multiplicand,
-remove the decimal point as many places to the left as there are
-correct places of decimals in either the multiplier or multiplicand;
-the result is the quantity within which the product can be depended
-upon. In division, the rule is: Proceed as in the last rule, putting
-the dividend and divisor in place of the multiplier and multiplicand,
-and divide by the <i>square</i> of the divisor; the quotient will
-be the quantity within which the division of the first dividend and
-divisor may be depended upon. Thus, if 17·324 be divided by 53·809,
-both being correct to the third place, their half sum will be 35·566,
-which, by the last rule, is made ·035566, and is to be divided by the
-square of 53·809, or, which will do as well for our purpose, the square
-of 50, or 2500. The result is something less than ·00002, so that the
-quotient of 17·324 and 53·809 can be depended on to four places of decimals.</p>
-
-<p>153. It is required to multiply two decimal fractions together, so as
-to retain in the product only a given number of decimal places, and
-dispense with the trouble of finding the rest. First, it is evident
-that we may write the figures of any multiplier in a contrary order
-(for example, 4321 instead of 1234), provided that in the operation we
-move each line one place to the right instead of to the left, as in the
-following example:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">2221</td>
- <td class="tdl_ws2">2221</td>
- </tr><tr>
- <td class="tdr_ws1 u">1234</td>
- <td class="tdl_ws2 u">4321</td>
- </tr><tr>
- <td class="tdr_ws1">8884</td>
- <td class="tdl_ws2">2221</td>
- </tr><tr>
- <td class="tdr_ws1">6663&#8199;</td>
- <td class="tdl_ws2">&#8199;4442</td>
- </tr><tr>
- <td class="tdr_ws1">4442&#8199;&#8199;</td>
- <td class="tdl_ws2">&#8199;&#8199;6663</td>
- </tr><tr>
- <td class="tdr_ws1">2221&#8199;&#8199;&#8199;</td>
- <td class="tdl_ws2">&#8199;&#8199;&#8199;8884</td>
- </tr><tr>
- <td class="tdr_ws1 over">2740714</td>
- <td class="tdl_ws2 over">2740714</td>
- </tr>
- </tbody>
-</table>
-
-<p>Suppose now we wish to multiply 348·8414 by 51·30742, reserving only
-four decimal places in the product. If we reverse the multiplier, and
-proceed in the manner just pointed out, we have the following:
-<span class="pagenum" id="Page_85">[Pg 85]</span></p>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <tbody><tr>
- <td class="tdr">3488414&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">2470315&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr over">17442070&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">3488414</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1046524</td>
- <td class="tdl">2</td>
- </tr><tr>
- <td class="tdr">24418</td>
- <td class="tdl">898</td>
- </tr><tr>
- <td class="tdr">1395</td>
- <td class="tdl">3656</td>
- </tr><tr>
- <td class="tdr">69</td>
- <td class="tdl">76828</td>
- </tr><tr>
- <td class="tdr over">17898·1522</td>
- <td class="tdl over">23188</td>
- </tr>
- </tbody>
-</table>
-
-<p>Cut off, by a vertical line, the first four places of decimals, and
-the columns which produced them. It is plain that in forming our
-abbreviated rule, we have to consider only, I. all that is on the left
-of the vertical line; II. all that is carried from the first column on
-the right of the line. On looking at the first column to the left of
-the line, we see 4, 4, 8, 5, 9, of which the first 4 comes from 4 ×
-1′,<a id="FNanchor_20" href="#Footnote_20" class="fnanchor">[20]</a>
-the second 4 from 1 × 3′, the 8 from 8 × 7′, the 5 from 8 × 4′,
-and the 9 from 4 × 2′. If, then, we arrange the multiplicand and the
-reversed multiplier thus,</p>
-
-<ul class="index">
-<li class="isub4-5">3488414</li>
-<li class="isub5">2470315</li>
-</ul>
-
-<p class="no-indent">each figure of the multiplier is placed under
-the first figure of the multiplicand which is used with it in forming
-the first <i>four</i> places of decimals. And here observe, that the
-units’ figure in the multiplier 51·30742, viz. 1, comes under 4, the
-<i>fourth</i> decimal place in the multiplicand. If there had been no
-carrying from the right of the vertical line, the rule would have been:
-Reverse the multiplier, and place it under the multiplicand, so that
-the figure which was the units’ figure in the multiplier may stand
-under the last place of decimals in the multiplicand which is to be
-preserved; place ciphers over those figures of the multiplier which
-have none of the multiplicand above them, if there be any: proceed to
-multiply in the usual way, but begin each figure of the multiplier with
-the figure of the multiplicand which comes above it, taking no account
-of those on the right: place the first figures of all the lines under
-one another. To correct this rule, so as to allow for what is carried
-from the right of the vertical line, observe that this consists of two
-parts, 1st, what is carried directly in the formation of the different
-lines, and 2dly, what is carried from the addition of the first column
-on the right. The first of these may be taken into account by beginning
-<span class="pagenum" id="Page_86">[Pg 86]</span>
-each figure of the multiplier with the one which comes on its right in
-the multiplicand, and carrying the tens to the next figure as usual, but
-without writing down the units. But both may be allowed for at once,
-with sufficient correctness, on the principle of (151), by carrying
-1 from 5 up to 15, 2 from 15 up to 25, &amp;c.; that is, by carrying the
-nearest ten. Thus, for 37, 4 would be carried, 37 being nearer to 40
-than to 30. This will not always give the last place quite correctly,
-but the error may be avoided by setting out so as to keep one more
-place of decimals in the product than is absolutely required to be
-correct. The rule, then, is as follows:</p>
-
-<p>154. To multiply two decimals together, retaining only <i>n</i> decimal
-places.</p>
-
-<p>I. Reverse the multiplier, strike out the decimal points, and place the
-multiplier under the multiplicand, so that what was its units’ figure
-shall fall under the <i>n</i>ᵗʰ decimal place of the multiplicand,
-placing ciphers, if necessary, so that every place of the multiplier
-shall have a figure or cipher above it.</p>
-
-<p>II. Proceed to multiply as usual, beginning each figure of the
-multiplier with the one which is in the place to its right in the
-multiplicand: do not set down this first figure, but carry its
-<i>nearest</i> ten to the next, and proceed.</p>
-
-<p>III. Place the first figures of all the lines under one another; add as
-usual; and mark off <i>n</i> places from the right for decimals.</p>
-
-<p>It is required to multiply 136·4072 by 1·30609, retaining 7 decimal
-places.</p>
-
-<ul class="index">
-<li class="isub2">1364072000</li>
-<li class="isub4">906031</li>
-<li class="isub2 over">1364072000</li>
-<li class="isub2-5">409221600</li>
-<li class="isub3-5">8184432</li>
-<li class="isub4">122766</li>
-<li class="isub2 over">178·1600798</li>
-</ul>
-
-<p><span class="pagenum" id="Page_87">[Pg 87]</span>
-In the following examples the first two lines are the multiplicand
-and multiplier; and the number of decimals to be retained will be
-seen from the results.</p>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws2">·4471618</td>
- <td class="tdr_ws2">33·166248</td>
- <td class="tdr">3·4641016</td>
- </tr><tr>
- <td class="tdr_ws2 u">3·7719214</td>
- <td class="tdr_ws2 u">1·4142136</td>
- <td class="tdr u">1732·508</td>
- </tr><tr>
- <td class="tdr_ws2 over">37719214</td>
- <td class="tdr_ws2 over">033166248</td>
- <td class="tdr over">346410160</td>
- </tr><tr>
- <td class="tdr_ws2 u">8161744&#8199;</td>
- <td class="tdr_ws2 u">63124141</td>
- <td class="tdr">8052371&#8199;</td>
- </tr><tr>
- <td class="tdr_ws2">15087686</td>
- <td class="tdr_ws2">3316625</td>
- <td class="tdr over">346410160</td>
- </tr><tr>
- <td class="tdr_ws2">1508768</td>
- <td class="tdr_ws2">1326650</td>
- <td class="tdr">242487112</td>
- </tr><tr>
- <td class="tdr_ws2">264034</td>
- <td class="tdr_ws2">33166</td>
- <td class="tdr">10392305</td>
- </tr><tr>
- <td class="tdr_ws2">3772</td>
- <td class="tdr_ws2">13266</td>
- <td class="tdr">692820</td>
- </tr><tr>
- <td class="tdr_ws2">2263</td>
- <td class="tdr_ws2">663</td>
- <td class="tdr">173205</td>
- </tr><tr>
- <td class="tdr_ws2">38</td>
- <td class="tdr_ws2">33</td>
- <td class="tdr">2771</td>
- </tr><tr>
- <td class="tdr_ws2">30</td>
- <td class="tdr_ws2">10</td>
- <td class="tdr over">6001·58373</td>
- </tr><tr>
- <td class="tdr_ws2 over">1·6866591</td>
- <td class="tdr_ws2">2</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws2">&nbsp;</td>
- <td class="tdr_ws2 over">46·90415</td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="center space-below1">Exercises may be got from article (143).</p>
-
-<p>155. With regard to division, take any two numbers, for example,
-16·80437921 and 3·142, and divide the first by the second, as far as
-any required number of decimal places, for example, five. This gives
-the following:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">3·142)</td>
- <td class="tdr">16·804</td>
- <td class="tdl">379</td>
- <td class="tdl">21(5·34830</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">15·710</td>
- <td class="tdl" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl u">1·0943</td>
- <td class="tdl" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr u br">9426</td>
- <td class="tdl" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr br">15177</td>
- <td class="tdl" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc u">&nbsp;(A)&nbsp;</td>
- <td class="tdr u br">12568</td>
- <td class="tdl u" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc">2609</td>
- <td class="tdr br">2609</td>
- <td class="tdl" colspan="2">9</td>
- </tr><tr>
- <td class="tdc u">2514</td>
- <td class="tdr u br">2513</td>
- <td class="tdl u" colspan="2">6&nbsp;</td>
- </tr><tr>
- <td class="tdc">95</td>
- <td class="tdr br">96</td>
- <td class="tdl" colspan="2">32</td>
- </tr><tr>
- <td class="tdc u">94</td>
- <td class="tdr u br">94</td>
- <td class="tdl u" colspan="2">26</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdr br">2</td>
- <td class="tdl u" colspan="2">061</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_88">[Pg 88]</span>
-Now cut off by a vertical line, as in (153), all the figures which
-come on the right of the first figure 2, in the last remainder 2061.
-As in multiplication, we may obtain all that is on the left of the
-vertical line by an abbreviated method, as represented at (A). After
-what has been said on multiplication, it is useless to go further
-into the detail; the following rule will be sufficient: To divide one
-decimal by another, retaining only <i>n</i> places: Proceed one step in
-the ordinary division, and determine, by (150), in what place is the
-quotient so obtained; proceed in the ordinary way, until the number of
-figures remaining to be found in the quotient is less than the number
-of figures in the divisor: if this should be already the case, proceed
-no further in the ordinary way. Instead of annexing a figure or cipher
-to the remainder, cut off a figure from the divisor, and proceed one
-step with this curtailed divisor as usual, remembering, however, in
-multiplying this divisor, to carry the <i>nearest ten</i>, as in (154),
-from the figure which was struck off; repeat this, striking off another
-figure of the divisor, and so on, until no figures are left. Since we
-know from the beginning in what place the first figure of the quotient
-is, and also how many decimals are required, we can tell from the
-beginning how many figures there will be in the whole quotient. If the
-divisor contain more figures than the quotient, it will be unnecessary
-to use them: and they may be rejected, the rest being corrected as in
-(151): if there be ciphers at the beginning of the divisor, if it be,
-for example,</p>
-
-<table class="fontsize_120" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">·003178, since this is&nbsp;</td>
- <td class="tdc u">·3178</td>
- <td class="tdl" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">100</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">divide by ·3178 in the usual way, and afterwards
-multiply the quotient by 100, or remove the decimal point two places to
-the right. If, therefore, six decimals be required, eight places must
-be taken in dividing by ·3178, for an obvious reason. In finding the
-last figure of the quotient, the nearest should be taken, as in the
-second of the subjoined examples.
-<span class="pagenum" id="Page_89">[Pg 89]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="1" summary=" " cellpadding="1" >
- <tbody><tr>
- <td class="tdl">Places required,&emsp;&nbsp;</td>
- <td class="tdc">2</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">8</td>
- </tr><tr>
- <td class="tdl">Divisor,</td>
- <td class="tdl">·41432</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">3·1415927</td>
- </tr><tr>
- <td class="tdl">Dividend,</td>
- <td class="tdc">673·1489&nbsp;&nbsp;&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">2·71828180</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2 u">41432&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">2·51327416</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2">258828</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">20500764</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2 u">248592</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">18849556</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;10237</td>
- <td class="tdl"><a id="FNanchor_21" href="#Footnote_21" class="fnanchor">[21]</a></td>
- <td class="tdr">1651208</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2 u">8286</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">1570796</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2">1951</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">80412</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2 u">1657</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">62832</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2">294</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">17580</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2 u">290</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">15708</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2">4</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">1872</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2 u">&nbsp;4</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">1571</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr_ws2">0</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">301</td>
- </tr><tr>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdr u">283</td>
- </tr><tr>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdr">18</td>
- </tr><tr>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdr u">19</td>
- </tr><tr>
- <td class="tdl">Quotient,</td>
- <td class="tdr_ws2">1624·71</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">·86525596</td>
- </tr>
- </tbody>
-</table>
-
-<p class="center">Examples may be obtained from (143) and (150).</p>
-
-<hr class="chap x-ebookmaker-drop" />
-<div class="chapter">
-<h3 class="nobreak" id="SECTION_VII">SECTION VII.<br />
-<span class="h_subtitle">ON THE EXTRACTION OF<br />THE SQUARE ROOT.</span></h3>
-</div>
-
-<p>156. We have already remarked (66), that a number multiplied by itself
-produces what is called the <i>square</i> of that number. Thus, 169, or
-13 × 13, is the square of 13. Conversely, 13 is called the <i>square
-root</i> of 169, and 5 is the square root of 25; and any number is the
-square root of another, which when multiplied by itself will produce
-that other. The square root is signified by the sign</p>
-
-<p class="center">√ or √<span class="over">&nbsp;&nbsp;&nbsp;;</span>
-thus, √25 means the square root of 25, or 5; √<span class="over">16 + 9</span></p>
-
-<p class="no-indent">means the square root of 16 + 9, and is 5, and must not be confounded
-with √16 + √9, which is 4 + 3, or 7.</p>
-
-<p><span class="pagenum" id="Page_90">[Pg 90]</span>
-157. The following equations are evident from the definition:</p>
-
-<p class="f120">√<i>a</i> × √<i>a</i> = <i>a</i><br />
-√<span class="over"><i>aa</i></span> = <i>a</i><br />
-√<span class="over"><i>ab</i></span> × √<span class="over"><i>ab</i></span> = <i>ab</i><br />
-(√<i>a</i> × √<i>b</i>) × (√<i>a</i> × √<i>b</i>) =
- √<i>a</i> × √<i>a</i> × √<i>b</i> × √<i>b</i> = <i>ab</i></p>
-
-<p>whence</p>
-
-<p class="f120">√<i>a</i> × √<i>b</i> = √<span class="over"><i>ab</i></span></p>
-
-<p>158. It does not follow that a number has a square root because it
-has a square; thus, though 5 can be multiplied by itself, there is
-no number which multiplied by itself will produce 5. It is proved in
-algebra, that no fraction<a id="FNanchor_22" href="#Footnote_22" class="fnanchor">[22]</a>
-multiplied by itself can produce a whole number, which may be found
-true in any number of instances; therefore 5 has neither a whole nor
-a fractional square root; that is, it has no square root at all.
-Nevertheless, there are methods of finding fractions whose squares
-shall be as <i>near</i> to 5 as we please, though not exactly equal to
-it. One of these methods gives <big>¹⁵¹²⁷/₆₇₆₅</big>, whose square, viz.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">15127</td>
- <td class="tdc" rowspan="2">×&nbsp;</td>
- <td class="tdc u">15127</td>
- <td class="tdc" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc u">228826129</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">6765</td>
- <td class="tdc">6765</td>
- <td class="tdc">45765225</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">differs from 5 by only ⁴/₄₅₇₆₅₂₂₅, which is less
-than ·0000001: hence we are enabled to use √5 in arithmetical and
-algebraical reasoning: but when we come to the practice of any problem,
-we must substitute for √5 one of the fractions whose square is nearly
-5, and on the degree of accuracy we want, depends what fraction is
-to be used. For some purposes, <big>¹²³/₅₅</big> may be sufficient,
-as its square only differs from 5 by <big>⁴/₃₀₂₅</big>; for others,
-the fraction first given might be necessary, or one whose square is
-even nearer to 5. We proceed to shew how to find the square root of a
-number, when it has one, and from thence how to find fractions whose
-squares shall be as near as we please to the number, when it has not.
-We premise, what is sufficiently evident, that of two numbers, the
-greater has the greater square; and that if one number lie between two
-others, its square lies between the squares of those others.</p>
-
-<p>159. Let <i>x</i> be a number consisting of any number of parts, for
-example, four, viz. <i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>; that
-is, let
-<span class="pagenum" id="Page_91">[Pg 91]</span></p>
-
-<p class="f120"><i>x</i> = <i>a</i> + <i>b</i> + <i>c</i> + <i>d</i></p>
-
-<p>The square of this number, found as in (68), will be</p>
-
-<ul class="index fontsize_120">
-<li class="isub4"><i>aa</i> + 2<i>a</i>(<i>b</i> + <i>c</i> + <i>d</i>)</li>
-<li class="isub3">+ <i>bb</i> + 2<i>b</i>(<i>c</i> + <i>d</i>)</li>
-<li class="isub3">+ <i>cc</i> + 2<i>cd</i></li>
-<li class="isub3">+ <i>dd</i></li>
-</ul>
-
-<p>The rule there found for squaring a number consisting of parts was:
-Square each part, and multiply all that come after by twice that part,
-the sum of all the results so obtained will be the square of the whole
-number. In the expression above obtained, instead of multiplying
-2<i>a</i> by <i>each</i> of the succeeding parts, <i>b</i>, <i>c</i>,
-and <i>d</i>, and adding the results, we multiplied 2<i>a</i> by the
-<i>sum of all</i> the succeeding parts, which (52) is the same thing;
-and as the parts, however disposed, make up the number, we may reverse
-their order, putting the last first, &amp;c.; and the rule for squaring
-will be: Square each part, and multiply all that come before by twice
-that part. Hence a reverse rule for extracting the square root presents
-itself with more than usual simplicity. It is: To extract the square
-root of a number N, choose a number A, and see if N will bear the
-subtraction of the square of A; if so, take the remainder, choose a
-second number B, and see if the remainder will bear the subtraction of
-the square of B, and twice B multiplied by the preceding part A: if it
-will, there is a second remainder. Choose a third number C, and see if
-the second remainder will bear the subtraction of the square of C, and
-twice C multiplied by A + B: go on in this way either until there is no
-remainder, or else until the remainder will not bear the subtraction
-arising from any new part, even though that part were the least number,
-which is 1. In the first case, the square root is the sum of A, B, C,
-&amp;c.; in the second, there is no square root.</p>
-
-<p>160. For example, I wish to know if 2025 has a square root. I choose 20
-as the first part, and find that 400, the square of 20, subtracted from
-2025, gives 1625, the first remainder. I again choose 20, whose square,
-together with twice itself, multiplied by the preceding part, is
-<span class="pagenum" id="Page_92">[Pg 92]</span>
-20 × 20 + 2 × 20 × 20, or 1200; which subtracted from 1625, the first
-remainder, gives 425, the second remainder. I choose 7 for the third
-part, which appears to be too great, since 7 × 7, increased by 2 × 7
-multiplied by the sum of the preceding parts 20 + 20, gives 609, which
-is more than 425. I therefore choose 5, which closes the process, since
-5 × 5, together with 2 × 5 multiplied by 20 + 20, gives exactly 425.
-The square root of 2025 is therefore 20 + 20 + 5, or 45, which will be
-found, by trial, to be correct; since 45 × 45 = 2025. Again, I ask if
-13340 has, or has not, a square root. Let 100 be the first part, whose
-square is 10000, and the first remainder is 3340. Let 10 be the second
-part. Here 10 × 10 + 2 × 10 × 100 is 2100, and the second remainder,
-or 3340-2100, is 1240. Let 5 be the third part; then 5 × 5 + 2 × 5
-× (100 + 10) is 1125, which, subtracted from 1240, leaves 115. There
-is, then, no square root; for a single additional unit will give a
-subtraction of 1 × 1 + 2 × 1 × (100 + 10 + 5), or 231, which is greater
-than 115. But if the number proposed had been less by 115, each of the
-remainders would have been 115 less, and the last remainder would have
-been nothing. Therefore 13340-115, or 13225, has the square root 100
-+ 10 + 5, or 115; and the answer is, that 13340 has no square root, and
-that 13225 is the next number below it which has one, namely, 115.</p>
-
-<p>161. It only remains to put the rule in such a shape as will guide us
-to those parts which it is most convenient to choose. It is evident
-(57) that any number which terminates with ciphers, as 4000, has double
-the number of ciphers in its square. Thus, 4000 × 4000 = 16000000;
-therefore, any square number,<a id="FNanchor_23" href="#Footnote_23" class="fnanchor">[23]</a>
- as 49, with an even number of ciphers annexed, as 490000, is a square number.
-The root<a id="FNanchor_24" href="#Footnote_24" class="fnanchor">[24]</a>
-of 490000 is 700. This being premised, take any number, for example, 76176;
-setting out from the right hand towards the left, cut off two figures; then
-two more, and so on, until one or two figures only are left: thus, 7,61,76.
-This number is greater than 7,00,00, of which the first figure is not a
-square number, the nearest square below it being 4. Hence, 4,00,00 is
-<span class="pagenum" id="Page_93">[Pg 93]</span>
-the nearest square number below 7,00,00, which has four ciphers,
-and its square root is 200. Let this be the first part chosen: its
-square subtracted from 76176 leaves 36176, the first remainder; and
-it is evident that we have obtained the highest number of the highest
-denomination which is to be found in the square root of 76176; for
-300 is too great, its square, 9,00,00, being greater than 76176: and
-any denomination higher than hundreds has a square still greater. It
-remains, then, to choose a second part, as in the examples of (160),
-with the remainder 36176. This part cannot be as great as 100, by what
-has just been said; its highest denomination is therefore a number of
-tens. Let N stand for a number of tens, which is one of the simple
-numbers 1, 2, 3, &amp;c.; that is, let the new part be 10N, whose square
-is 10N × 10N, or 100NN, and whose double multiplied by the former part
-is 20N × 200, or 4000N; the two together are 4000N + 100NN. Now, N
-must be so taken that this may not be greater than 36176: still more
-4000N must not be greater than 36176. We may therefore try, for N, the
-number of times which 36176 contains 4000, or that which 36 contains
-4. The remark in (80) applies here. Let us try 9 tens or 90. Then, 2 ×
-90 × 200 + 90 × 90, or 44100, is to be subtracted, which is too great,
-since the whole remainder is 36176. We then try 8 tens or 80, which
-gives 2 × 80 × 200 + 80 × 80, or 38400, which is likewise too great. On
-trying 7 tens, or 70, we find 2 × 70 × 200 + 70 × 70, or 32900, which
-subtracted from 36176 gives 3276, the second remainder. The rest of
-the square root can only be units. As before, let N be this number of
-units. Then, the sum of the preceding parts being 200 + 70, or 270,
-the number to be subtracted is 270 × 2N + NN, or 540N + NN. Hence, as
-before, 540N must be less than 3276, or N must not be greater than the
-number of times which 3276 contains 540, or (80) which 327 contains
-54. We therefore try if 6 will do, which gives 2 × 6 × 270 + 6 × 6, or
-3276, to be subtracted. This being exactly the second remainder, the
-third remainder is nothing, and the process is finished. The square
-root required is therefore 200 + 70 + 6, or 276.</p>
-
-<p>The process of forming the numbers to be subtracted may be shortened
-thus. Let A be the sum of the parts already found, and N a new part:
-<span class="pagenum" id="Page_94">[Pg 94]</span>
-there must then be subtracted 2AN + NN, or (54) 2A + N multiplied by
-N. The rule, therefore, for forming it is: Double the sum of all the
-preceding parts, add the new part, and multiply the result by the new
-part.</p>
-
-<p>162. The process of the last article is as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">7,61,76</td>
- <td class="tdl">(200<span class="ws2">&nbsp;</span></td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">7,61,76(276</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">4 00 00</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;70</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">4</td>
- </tr><tr>
- <td class="tdr">400</td>
- <td class="tdc" rowspan="2"><span class="fontsize_200">)</span></td>
- <td class="tdl over">3,61,76</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;&nbsp;6</td>
- <td class="tdr">47)</td>
- <td class="tdl over">361</td>
- </tr><tr>
- <td class="tdr">70</td>
- <td class="tdl u">3 29 00</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">329</td>
- </tr><tr>
- <td class="tdr">400</td>
- <td class="tdc" rowspan="3"><span class="fontsize_300">)</span></td>
- <td class="tdr">32 76</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">546)</td>
- <td class="tdl">3276</td>
- </tr><tr>
- <td class="tdr">140</td>
- <td class="tdr u">32 76</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl u">3276</td>
- </tr><tr>
- <td class="tdr">6</td>
-
- <td class="tdr">0</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&emsp;0</td>
- </tr>
- </tbody>
-</table>
-
-<p>In the first of these, the numbers are written at length, as we found
-them; in the second, as in (79), unnecessary ciphers are struck off,
-and the periods 61, 76, are not brought down, until, by the continuance
-of the process, they cease to have ciphers under them. The following is
-another example, to which the reasoning of the last article may be applied.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">34,86,78,44,01</td>
- <td class="tdl">(50000<span class="ws2">&nbsp;</span></td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">34,86,78,44,01(59049</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl u">25 00 00 00 00</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;9000</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">25</td>
- </tr><tr>
- <td class="tdr">100000</td>
- <td class="tdc" rowspan="2"><span class="fontsize_200">)</span></td>
- <td class="tdl over">&nbsp;&nbsp;9 86 78 44 01</td>
- <td class="tdl">&nbsp;&nbsp;&emsp;&nbsp;40</td>
- <td class="tdr">109)</td>
- <td class="tdl over">986</td>
- </tr><tr>
- <td class="tdr">9000</td>
- <td class="tdl u">&nbsp;&nbsp;9 81 00 00 00</td>
- <td class="tdl">&emsp;&nbsp;&emsp;9</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl u">981&nbsp;&nbsp;</td>
- </tr><tr>
- <td class="tdr">100000</td>
- <td class="tdc" rowspan="3"><span class="fontsize_300">)</span></td>
- <td class="tdr">5 78 44 01</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">1180</td>
- <td class="tdl">4)57844</td>
- </tr><tr>
- <td class="tdr">18000</td>
- <td class="tdr">4 72 16 00</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&nbsp;&nbsp;47216</td>
- </tr><tr>
- <td class="tdr">40</td>
- <td class="tdl">&nbsp;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&mdash;&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdr">100000</td>
- <td class="tdc" rowspan="3"><span class="fontsize_300">)</span></td>
- <td class="tdr">5 78 44 01</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">18000</td>
- <td class="tdr">4 72 16 00</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">40</td>
- <td class="tdl">&nbsp;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr">100000</td>
- <td class="tdc" rowspan="4"><span class="fontsize_400">)</span></td>
- <td class="tdr">1 06 28 01</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">1180</td>
- <td class="tdl">89)1062801</td>
- </tr><tr>
- <td class="tdr">18000</td>
- <td class="tdr">1 06 28 01</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdc">1062801<span class="ws2">&nbsp;</span></td>
- </tr><tr>
- <td class="tdr">80</td>
- <td class="tdl">&nbsp;&mdash;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- </tr><tr>
- <td class="tdr">9</td>
- <td class="tdr">0</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl"><span class="ws4">&nbsp;</span>0</td>
- </tr>
- </tbody>
-</table>
-
-<p>163. The rule is as follows: To extract the square root of a number;&mdash;</p>
-
-<div class="blockquot">
-<p>I. Beginning from the right hand, cut off periods of two figures each,
-until not more than two are left.</p>
-
-<p>II. Find the root of the nearest square number next below the number in
-<span class="pagenum" id="Page_95">[Pg 95]</span>
-the first period. This root is the first figure of the required root;
-subtract its square from the first period, which gives the first remainder.</p>
-
-<p>III. Annex the second period to the right of the remainder, which gives
-the first dividend.</p>
-
-<p>IV. Double the first figure of the root; see how often this is
-contained in the number made by cutting one figure from the right of
-the first dividend, attending to IX., if necessary; use the quotient as
-the second figure of the root; annex it to the right of the double of
-the first figure, and call this the first divisor.</p>
-
-<p>V. Multiply the first divisor by the second figure of the root; if the
-product be greater than the first dividend, use a lower number for the
-second figure of the root, and for the last figure of the divisor,
-until the multiplication just mentioned gives the product less than the
-first dividend; subtract this from the first dividend, which gives the
-second remainder.</p>
-
-<p>VI. Annex the third period to the second remainder, which gives the
-second dividend.</p>
-
-<p>VII. Double the first two figures of the root;<a id="FNanchor_25" href="#Footnote_25" class="fnanchor">[25]</a>
-see how often the result is contained in the number made by cutting one
-figure from the right of the second dividend; use the quotient as the
-third figure of the root; annex it to the right of the double of the
-first two figures, and call this the second divisor.</p>
-
-<p>VIII. Get a new remainder, as in V., and repeat the process until all
-the periods are exhausted; if there be then no remainder, the square
-root is found; if there be a remainder, the proposed number has no
-square root, and the number found as its square root is the square root
-of the proposed number diminished by the remainder.</p>
-
-<p>IX. When it happens that the double of the figures of the root is not
-contained at all in all the dividend except the last figure, or when,
-being contained once, 1 is found to give more than the dividend, put a
-cipher in the square root and in the divisor, and bring down the next
-period; should the same thing still happen, put another cipher in the
-root and divisor, and bring down another period; and so on.</p>
-</div>
-
-<p><span class="pagenum" id="Page_96">[Pg 96]</span></p>
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <tbody><tr>
- <td class="tdc bb"><b>Numbers proposed.</b></td>
- <td class="tdc bb">&nbsp;<b>Square roots.</b></td>
- </tr><tr>
- <td class="tdc">73441</td>
- <td class="tdc">271</td>
- </tr><tr>
- <td class="tdc">2992900</td>
- <td class="tdc">1730</td>
- </tr><tr>
- <td class="tdc">6414247921</td>
- <td class="tdc">80089</td>
- </tr><tr>
- <td class="tdc">903687890625</td>
- <td class="tdc">950625</td>
- </tr><tr>
- <td class="tdc">42420747482776576&nbsp;&nbsp;</td>
- <td class="tdc">205962976</td>
- </tr><tr>
- <td class="tdc">13422659310152401</td>
- <td class="tdc">115856201</td>
- </tr>
- </tbody>
-</table>
-
-<p>164. Since the square of a fraction is obtained by squaring the
-numerator and the denominator, the square root of a fraction is found
-by taking the square root of both. Thus, the square root of ²⁵/₆₄ is ⅝,
-since 5 × 5 is 25, and 8 × 8 is 64. If the numerator or denominator,
-or both, be not square numbers, it does not therefore follow that the
-fraction has no square root; for it may happen that multiplication
-or division by the same number may convert both the numerator and
-denominator into square numbers (108). Thus, <big>²⁷/₄₈</big>, which appears
-at first to have no square root, has one in reality, since it is the same
-as <big>⁹/₁₆</big>, whose square root is ¾.</p>
-
-<p>165. We now proceed from (158), where it was stated that any number or
-fraction being given, a second may be found, whose square is as near to
-the first as we please. Thus, though we cannot solve the problem, “Find
-a fraction whose square is 2,” we can solve the following, “Find a
-fraction whose square shall not differ from 2 by so much as ·00000001.”
-Instead of this last, a still smaller fraction may be substituted;
-in fact, any one however small: and in this process we are said to
-approximate to the square root of 2. This can be done to any extent, as
-follows: Suppose we wish to find the square root of 2 within <big>¹/₅₇</big> of
-the truth; by which I mean, to find a fraction <i>a</i>/<i>b</i> whose
-square is less than 2, but such that the square of <i>a</i>/<i>b</i> +
-<big>¹/₅₇</big> is greater than 2. Multiply the numerator and denominator of <big>²/₁</big>
-by the square of 57, or 3249, which gives <big>⁶⁴⁹⁸/₃₂₄₉</big>. On attempting to
-extract the square root of the numerator, I find (163) that there is a
-remainder 98, and that the square number next below 6498 is 6400, whose
-root is 80. Hence, the square of 80 is less than 6498, while that of 81
-<span class="pagenum" id="Page_97">[Pg 97]</span>
-is greater. The square root of the denominator is of course 57. Hence,
-the square of <big>⁸⁰/⁵⁷</big> is less than <big>⁶⁴⁹⁸/₃₂₄₉</big>, or 2,
-while that of <big>⁸¹/₅₇</big> is greater, and these two fractions only
-differ by <big>¹/₅₇</big>; which was required to be done.</p>
-
-<p>166. In practice, it is usual to find the square root true to a certain
-number of places of decimals. Thus, 1·4142 is the square root of 2 true
-to four places of decimals, since the square of 1·4142, or 1·99996164,
-is less than 2, while an increase of only 1 in the fourth decimal
-place, giving 1·4143, gives the square 2·00024449, which is greater
-than 2. To take a more general case: Suppose it required to find the
-square root of 1·637 true to four places of decimals. The fraction is
-<big>¹⁶³⁷/₁₀₀₀</big>, whose square root is to be found within ·0001, or <big>¹/₁₀₀₀₀</big>.
-Annex ciphers to the numerator and denominator, until the denominator
-becomes the square of ¹/₁₀₀₀₀, which gives <big>¹⁶³⁷⁰⁰⁰⁰⁰/₁₀₀₀₀₀₀₀₀</big>, extract
-the square root of the numerator, as in (163), which shews that the
-square number nearest to it is 163700000-13564, whose root is
-12794. Hence, <big>¹²⁷⁹⁴/₁₀₀₀₀</big>, or 1·2794, gives a square less than 1·637,
-while 1·2795 gives a square greater. In fact, these two squares are
-1·63686436 and 1·63712025.</p>
-
-<p>167. The rule, then, for extracting the square root of a number or
-decimal to any number of places is: Annex ciphers until there are twice
-as many places following the units’ place as there are to be decimal
-places in the root; extract the nearest square root of this number,
-and mark off the given number of decimals. Or, more simply: Divide the
-number into periods, so that the units’ figure shall be the last of
-a period; proceed in the usual way; and if, when decimals follow the
-units’ place, there is one figure on the right, in a period by itself,
-annex a cipher in bringing down that period, and afterwards let each
-new period consist of two ciphers. Place the decimal point after that
-figure in forming which the period containing the units was used.</p>
-
-<p>168. For example, what is the square root of (1⅜) to five places of
-decimals? This is (145) 1·375, and the process is the first example
-over leaf. The second example is the extraction of the root of ·081
-to seven places, the first period being 08, from which the cipher is
-omitted as useless.
-<span class="pagenum" id="Page_98">[Pg 98]</span></p>
-
-<ul class="index">
-<li class="isub5">1,37,5(1·17260</li>
-<li class="isub5 u">1&nbsp;&nbsp;</li>
-<li class="isub3">21) &nbsp;37</li>
-<li class="isub4-5 u">&nbsp;21&nbsp;&nbsp;&nbsp;&nbsp;</li>
-<li class="isub3">227)&nbsp;1650</li>
-<li class="isub5 u">&nbsp;1589&nbsp;&nbsp;</li>
-<li class="isub3">2342) 6100</li>
-<li class="isub5-5 u">4684</li>
-<li class="isub3">23446) 141600</li>
-<li class="isub6 u">140676&nbsp;&nbsp;&nbsp;&nbsp;</li>
-<li class="isub3">23452)&nbsp;&emsp;&nbsp;&nbsp;92400</li>
-
-<li class="isub4-5 space-above2">8,1(·2846049</li>
-<li class="isub4-5 u">4&nbsp;&nbsp;&nbsp;</li>
-<li class="isub3">48)410</li>
-<li class="isub4-5 u">384</li>
-<li class="isub3">564) 2600</li>
-<li class="isub5 u">2256</li>
-<li class="isub2-5">5686) 34400</li>
-<li class="isub5 u">34116</li>
-<li class="isub2-5">569204) 2840000</li>
-<li class="isub6 u">2276816</li>
-<li class="isub2-5">569208) &nbsp;56318400</li>
-
-<li class="isub1-5 space-above2">·000002413672221(·001553599</li>
-<li class="isub4-5 u">1&nbsp;&nbsp;&nbsp;</li>
-<li class="isub3">25) 141</li>
-<li class="isub4-5 u">125&nbsp;&nbsp;</li>
-<li class="isub3">305) 1636</li>
-<li class="isub5 u">1525&nbsp;&nbsp;</li>
-<li class="isub3">3103) 11172</li>
-<li class="isub6 u">9309&nbsp;&nbsp;</li>
-<li class="isub3">31065) 186322</li>
-<li class="isub6 u">155325&nbsp;&nbsp;</li>
-<li class="isub3">310709) 3099710</li>
-<li class="isub6-5 u">2796381&nbsp;&nbsp;&nbsp;</li>
-<li class="isub7">30332900</li>
-</ul>
-
-<p>169. When more than half the decimals required have been found, the
-others may be simply found by dividing the dividend by the divisor, as
-in (155). The extraction of the square root of 12 to ten places, which
-will be found in the next page, is an example. It must, however, be
-observed in this process, as in all others where decimals are obtained
-by approximation, that the last place cannot always be depended upon:
-on which account it is advisable to carry the process so far, that
-one or even two more decimals shall be obtained than are absolutely
-required to be correct.
-<span class="pagenum" id="Page_99">[Pg 99]</span></p>
-
-<ul class="index no-wrap">
-<li class="isub10"><big><b>A</b></big></li>
-<li class="isub4-5">12(3·46410161513</li>
-<li class="isub5 u">9&nbsp;&nbsp;</li>
-<li class="isub3">64) 300</li>
-<li class="isub4-5 u">256&nbsp;&nbsp;</li>
-<li class="isub3">686) 4400</li>
-<li class="isub5 u">4116&nbsp;&nbsp;</li>
-<li class="isub3">6924) 28400</li>
-<li class="isub5-5 u">27696&nbsp;&nbsp;</li>
-<li class="isub3">69281)  70400</li>
-<li class="isub6-5 u">69281&nbsp;&nbsp;</li>
-<li class="isub3">6928201) 11190000</li>
-<li class="isub7-5 u">6928201&nbsp;&nbsp;</li>
-<li class="isub3">69282026) 4261799|00</li>
-<li class="isub7-5 u">4156921|56</li>
-<li class="isub3">692820321) 104877|4400</li>
-<li class="isub8-5 u">69282|0321</li>
-<li class="isub3">6928203225) 35595|407900</li>
-<li class="isub8-5 u">34641|016125</li>
-<li class="isub3">69282032301)  954|39177500</li>
-<li class="isub10 u">692|82032301</li>
-<li class="isub3">692820323023) 261|5714519900</li>
-<li class="isub11 u">207|8460969069</li>
-<li class="isub12">53|7253550831</li>
-<li class="isub3">&nbsp;</li>
-
-<li class="isub10"><big><b>B</b></big></li>
-<li class="isub1">692820323026)537253550831(77545870549</li>
-<li class="isub7-5 u">484974226118</li>
-<li class="isub8">52279324713</li>
-<li class="isub8 u">48497422611;</li>
-<li class="isub8-5">3781902102</li>
-<li class="isub8-5 u">3464101615</li>
-<li class="isub9">317800487</li>
-<li class="isub9 u">277128129</li>
-<li class="isub9-5">40672358</li>
-<li class="isub9-5 u">34641016</li>
-<li class="isub10">6031342</li>
-<li class="isub10 u">5542562</li>
-<li class="isub10-5">488780</li>
-<li class="isub10-5 u">484974</li>
-<li class="isub11-5">3806</li>
-<li class="isub11-5 u">3464</li>
-<li class="isub12">342</li>
-<li class="isub12 u">277</li>
-<li class="isub12-5">65</li>
-<li class="isub12-5 u">62</li>
-<li class="isub13">3</li>
-</ul>
-
-<p>If from any remainder we cut off the ciphers, and all figures which
-would come under or on the right of these ciphers, by a vertical line,
-we find on the left of that line a contracted division, such as those
-in (155). Thus, after having found the root as far as 3·464101, we
-have the remainder 4261799, and the divisor 6928202. The figures on
-the left of the line are nothing more than the contracted division of
-this remainder by the divisor, with this difference, however, that we
-have to begin by striking a figure off the divisor, instead of using
-the whole divisor once, and then striking off the first figure. By this
-alone we might have doubled our number of decimal places, and got the
-<span class="pagenum" id="Page_100">[Pg 100]</span>
-additional figures 615137, the last 7 being obtained by carrying the
-contracted division one step further with the remainder 53. We have,
-then, this rule: When half the number of decimal places have been
-obtained, instead of annexing two ciphers to the remainder, strike off
-a figure from what would be the divisor if the process were continued at
-length, and divide the remainder by this contracted divisor, as in (155).</p>
-
-<p>As an example, let us double the number of decimal places already
-obtained, which are contained in 3·46410161513. The remainder is
-537253550831, the divisor 692820323026, and the process is as in (B).
-Hence the square root of 12 is,</p>
-
-<p class="f120">3·4641016151377545870549;</p>
-
-<p class="no-indent">which is true to the last figure, and a little too
-great; but the substitution of 8 instead of 9 on the right hand would
-make it too small.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <tbody><tr>
- <td class="tdc bb"><b>Numbers.&nbsp;</b></td>
- <td class="tdc bb"><b>Square roots.</b></td>
- </tr><tr>
- <td class="tdc">·001728</td>
- <td class="tdc">·0415692194</td>
- </tr><tr>
- <td class="tdc">64·34</td>
- <td class="tdc">8·02122185</td>
- </tr><tr>
- <td class="tdc">8074</td>
- <td class="tdc">89·8554394</td>
- </tr><tr>
- <td class="tdc">10</td>
- <td class="tdc">3·16227766</td>
- </tr><tr>
- <td class="tdc">1·57</td>
- <td class="tdc">&nbsp;1·2529964086141667788495</td>
- </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-<div class="chapter">
-<h3 class="nobreak" id="SECTION_VIII">SECTION VIII.<br />
-<span class="h_subtitle">ON THE PROPORTION OF NUMBERS.</span></h3>
-</div>
-
-
-<p>170. When two numbers are named in any problem, it is usually
-necessary, in some way or other, to compare the two; that is, by
-considering the two together, to establish some connexion between
-them, which may be useful in future operations. The first method
-which suggests itself, and the most simple, is to observe which is
-the greater, and by how much it differs from the other. The connexion
-thus established between two numbers may also hold good of two other
-numbers; for example, 8 differs from 19 by 11, and 100 differs from 111
-<span class="pagenum" id="Page_101">[Pg 101]</span>
-by the same number. In this point of view, 8 stands to 19 in the
-same situation in which 100 stands to 111, the first of both couples
-differing in the same degree from the second. The four numbers thus
-noticed, viz.:</p>
-
-<p class="f120">8, 19, 100, 111,</p>
-
-<p class="no-indent">are said to be in <i>arithmetical</i><a id="FNanchor_26" href="#Footnote_26" class="fnanchor">[26]</a>
-<i>proportion</i>. When four numbers are thus placed, the first and
-last are called the <i>extremes</i>, and the second and third the
-<i>means</i>. It is obvious that 111 + 8 = 100 + 19, that is, the sum
-of the extremes is equal to the sum of the means. And this is not
-accidental, arising from the particular numbers we have taken, but must
-be the case in every arithmetical proportion; for in 111 + 8, by (35),
-any diminution of 111 will not affect the sum, provided a corresponding
-increase be given to 8; and, by the definition just given, one mean is
-as much less than 111 as the other is greater than 8.</p>
-
-<p>171. A set or series of numbers is said to be in <i>continued</i>
-arithmetical proportion, or in arithmetical <i>progression</i>, when
-the difference between every two succeeding terms of the series is the
-same. This is the case in the following series:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdr">1,</td>
- <td class="tdr">2,</td>
- <td class="tdr">3,</td>
- <td class="tdr">4,</td>
- <td class="tdr">5,</td>
- <td class="tdr">&amp;c.</td>
- </tr><tr>
- <td class="tdr">3,</td>
- <td class="tdr">6,</td>
- <td class="tdr">9,</td>
- <td class="tdr">12,</td>
- <td class="tdr">15,</td>
- <td class="tdr">&amp;c.</td>
- </tr><tr>
- <td class="tdr">1½,</td>
- <td class="tdr">2,</td>
- <td class="tdr">2½,</td>
- <td class="tdr">3,</td>
- <td class="tdr">3½,</td>
- <td class="tdr">&amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p>The difference between two succeeding terms is called the common
-difference. In the three series just given, the common differences are,
-1, 3, and ½.</p>
-
-<p>172. If a certain number of terms of any arithmetical series be taken,
-the sum of the first and last terms is the same as that of any other
-two terms, provided one is as distant from the beginning of the series
-as the other is from the end. For example, let there be 7 terms, and
-let them be,</p>
-
-<p class="f120"><i>a</i>  <i>b</i>  <i>c</i>  <i>d</i>  <i>e</i>  <i>f</i>  <i>g</i>.</p>
-
-<p class="no-indent"><span class="pagenum" id="Page_102">[Pg 102]</span>
-Then, since, by the nature of the series, <i>b</i> is as much above
-<i>a</i> as <i>f</i> is below <i>g</i> (170), <i>a</i> + <i>g</i> =
-<i>b</i> + <i>f</i>. Again, since <i>c</i> is as much above <i>b</i>
-as <i>e</i> is below <i>f</i> (170), <i>b</i> + <i>f</i> = <i>c</i>
-+ <i>e</i>. But <i>a</i> + <i>g</i> = <i>b</i> + <i>f</i>; therefore
-<i>a</i> + <i>g</i> = <i>c</i> + <i>e</i>, and so on. Again, twice
-the middle term, or the term equally distant from the beginning and
-the end (which exists only when the number of terms is odd), is equal
-to the sum of the first and last terms; for since <i>c</i> is as much
-below <i>d</i> as <i>e</i> is above it, we have <i>c</i> + <i>e</i> =
-<i>d</i> + <i>d</i> = 2<i>d</i>. But <i>c</i> + <i>e</i> = <i>a</i>
-+ <i>g</i>; therefore, <i>a</i> + <i>g</i> = 2<i>d</i>. This will
-give a short rule for finding the sum of any number of terms of an
-arithmetical series. Let there be 7, viz. those just given. Since
-<i>a</i> + <i>g</i>, <i>b</i> + <i>f</i>, and <i>c</i> + <i>e</i>, are
-the same, their sum is three times (<i>a</i> + <i>g</i>), which with
-<i>d</i>, the middle term, or half <i>a</i> + <i>g</i>, is three times
-and a half (<i>a</i> + <i>g</i>), or the sum of the first and last
-terms multiplied by (3½), or ⁷/₂, or half the number of terms. If there
-had been an even number of terms, for example, six, viz. <i>a</i>,
-<i>b</i>, <i>c</i>, <i>d</i>, <i>e</i>, and <i>f</i>, we know now that
-<i>a</i> + <i>f</i>, <i>b</i> + <i>e</i>, and <i>c</i> + <i>d</i>,
-are the same, whence the sum is three times (<i>a</i> + <i>f</i>), or
-the sum of the first and last terms multiplied by half the number of
-terms, as before. The rule, then, is: To sum any number of terms of an
-arithmetical progression, multiply the sum of the first and last terms
-by half the number of terms. For example, what are 99 terms of the
-series 1, 2, 3, &amp;c.? The 99th term is 99, and the sum is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">(99 + 1)&nbsp;</td>
- <td class="tdc u">99</td>
- <td class="tdc" rowspan="2">&nbsp;, or&nbsp;</td>
- <td class="tdc u">100 × 99</td>
- <td class="tdc" rowspan="2">&nbsp;, or 4950.</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">The sum of 50 terms of the series</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">,&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">,&nbsp;&nbsp;</td>
- <td class="tdc" rowspan="2"><big>1</big>,&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;4&nbsp;</td>
- <td class="tdc" rowspan="2">,&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;5&nbsp;</td>
- <td class="tdc" rowspan="2">,&nbsp;<big>2</big>,&nbsp;&nbsp;&amp;c. is&nbsp;</td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">(</span></td>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;50&nbsp;</td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">)</span></td>
- <td class="tdc u">&nbsp;50&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- <td class="tdc">2</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120">or 17 × 25, or 425.</p>
-
-<p>173. The first term being given, and also the common difference and
-number of terms, the last term may be found by adding to the first
-term the common difference multiplied by one less than the number of
-terms. For it is evident that the second term differs from the first
-by the common difference, the <i>third</i> term by <i>twice</i>, the
-<i>fourth</i> term by <i>three</i> times the common difference; and so
-on. Or, the passage from the first to the <i>n</i>th term is made by
-<i>n</i>-1 steps, at each of which the common difference is added.
-<span class="pagenum" id="Page_103">[Pg 103]</span></p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <thead><tr>
- <th class="tdc bb br" colspan="4"><big><i>Given.</i></big></th>
- <th class="tdc bb" colspan="2"><big><i>To find.</i></big></th>
- </tr><tr>
- <th class="tdc bb2 br" colspan="3">Series.</th>
- <th class="tdc bb2 br">&nbsp;No. of terms.&nbsp;</th>
- <th class="tdc bb2 br">&nbsp;Last term.&nbsp;</th>
- <th class="tdc bb2">Sum.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdr_ws1">4,</td>
- <td class="tdr_ws1">6½,</td>
- <td class="tdr_ws1 br">9, &amp;c.</td>
- <td class="tdc br2">33</td>
- <td class="tdc br">84</td>
- <td class="tdc">1452</td>
- </tr><tr>
- <td class="tdr_ws1">1,</td>
- <td class="tdr_ws1">3,</td>
- <td class="tdr_ws1 br">5, &amp;c.</td>
- <td class="tdc br2">28</td>
- <td class="tdc br">55</td>
- <td class="tdc">784</td>
- </tr><tr>
- <td class="tdr_ws1">2,</td>
- <td class="tdr_ws1">20,</td>
- <td class="tdr_ws1 br">38, &amp;c.</td>
- <td class="tdc br2">100,000</td>
- <td class="tdc br">1799984</td>
- <td class="tdc">&nbsp;89999300000</td>
- </tr>
- </tbody>
-</table>
-
-<p>174. The sum being given, the number of terms, and the first term,
-we can thence find the common difference. Suppose, for example, the
-first term of a series to be one, the number of terms 100, and the sum
-10,000. Since 10,000 was made by multiplying the sum of the first and
-last terms by <big>¹⁰⁰/₂</big>, if we divide by this, we shall recover the sum
-of the first and last terms. Now, <big>¹⁰,⁰⁰⁰/₁</big> divided by <big>¹⁰⁰/₂</big> is (122)
-200, and the first term being 1, the last term is 199. We have then to
-pass from 1 to 199, or through 198, by 99 equal steps. Each step is,
-therefore, <big>¹⁹⁸/⁹⁹</big>, or 2, which is the common difference; or the series
-is 1, 3, 5, &amp;c., up to 199.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <thead><tr>
- <th class="tdc bb br" colspan="3"><big><i>Given.</i></big></th>
- <th class="tdc bb" colspan="2"><big><i>To find.</i></big></th>
- </tr><tr>
- <th class="tdc bb2 br">Sum.</th>
- <th class="tdc bb2 br">&nbsp;No. of terms.&nbsp;</th>
- <th class="tdc bb2 br">&nbsp;First term.&nbsp;</th>
- <th class="tdc bb2 br">&nbsp;Last term.&nbsp;</th>
- <th class="tdc bb2">&nbsp;Common diff.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdc">1809025</td>
- <td class="tdc">1345</td>
- <td class="tdc">1</td>
- <td class="tdc">2689</td>
- <td class="tdc">2</td>
- </tr><tr>
- <td class="tdc" rowspan="2">44</td>
- <td class="tdc" rowspan="2">10</td>
- <td class="tdc" rowspan="2">3</td>
- <td class="tdc u">29</td>
- <td class="tdc u"> 14</td>
- </tr><tr>
- <td class="tdc">5</td>
- <td class="tdc">45</td>
- </tr><tr>
- <td class="tdc">7075600&nbsp;</td>
- <td class="tdc">1330</td>
- <td class="tdc">4</td>
- <td class="tdc">10636</td>
- <td class="tdc">8</td>
- </tr>
- </tbody>
-</table>
-
-<p>175. We now return to (170), in which we compared two numbers together
-by their difference. This, however, is not the method of comparison
-which we employ in common life, as any single familiar instance will
-shew. For example, we say of A, who has 10 thousand pounds, that he is
-much richer than B, who has only 3 thousand; but we do not say that
-C, who has 107 thousand pounds, is much richer than D, who has 100
-thousand, though the difference of fortune is the same in both cases,
-viz. 7 thousand pounds. In comparing numbers we take into our reckoning
-not only the differences, but the numbers themselves. Thus, if B and D
-both received 7 thousand pounds, B would receive 233 pounds and a third
-for every 100 pounds which he had before, while D for every 100 pounds
-<span class="pagenum" id="Page_104">[Pg 104]</span>
-would receive only 7 pounds. And though, in the view taken in (170), 3
-is as near to 10 as 100 is to 107, yet, in the light in which we now
-regard them, 3 is not so near to 10 as 100 is to 107, for 3 differs
-from 10 by more than twice itself, while 100 does not differ from 107
-by so much as one-fifth of itself. This is expressed in mathematical
-language by saying, that the <i>ratio</i> or <i>proportion</i> of 10 to
-3 is greater than the <i>ratio</i> or <i>proportion</i> of 107 to 100.
-We proceed to define these terms more accurately.</p>
-
-<p>176. When we use the term <i>part</i> of a number or fraction in
-the remainder of this section, we mean, one of the various sets of
-<i>equal</i> parts into which it may be divided, either the half, the
-third, the fourth, &amp;c.: the term multiple has been already explained
-(102). By the term <i>multiple-part</i> of a number we mean, the
-abbreviation of the words <i>multiple of a part</i>. Thus, 1, 2, 3,
-4, and 6, are parts of 12; ½ is also a part of 12, being contained in
-it 24 times; 12, 24, 36, &amp;c., are multiples of 12; and 8, 9, ⁵/₂,
-&amp;c. are multiple parts of 12, being multiples of some of its parts.
-And when multiple parts generally are spoken of, the parts themselves
-are supposed to be included, on the same principle that 12 is counted
-among the multiples of 12, the multiplier being 1. The multiples
-themselves are also included in this term; for 24 is also 48 halves,
-and is therefore among the multiple parts of 12. Each part is also
-in various ways a multiple-part; for one-fourth is two-eighths, and
-three-twelfths, &amp;c.</p>
-
-<p>177. Every number or fraction is a multiple-part of every other number
-or fraction. If, for example, we ask what part 12 is of 7, we see
-that on dividing 7 into 7 parts, and repeating one of these parts 12
-times, we obtain 12; or, on dividing 7 into 14 parts, each of which
-is one-half, and repeating one of these parts 24 times, we obtain
-24 halves, or 12. Hence, 12 is ¹²/₇, or ²⁴/₁₄, or ³⁶/₂₁ of 7; and
-so on. Generally, when <i>a</i> and <i>b</i> are two whole numbers,
-<i>a</i>/<i>b</i> expresses the multiple-part which <i>a</i> is of
-<i>b</i>, and <i>b</i>/<i>a</i> that which <i>b</i> is of <i>a</i>.
-Again, suppose it required to determine what multiple-part (2⅐)
-is of (3⅕), or ¹⁵/₇ of ¹⁶/₅. These fractions, reduced to a common
-denominator, are ⁷⁵/₃₅ and ¹¹²/₃₅, of which the second, divided into
-<span class="pagenum" id="Page_105">[Pg 105]</span>
-112 parts, gives ¹/₃₅, which repeated 75 times gives ⁷⁵/₃₅, the
-first. Hence, the multiple-part which the first is of the second is
-⁷⁵/₁₁₂, which being obtained by the rule given in (121), shews that
-<i>a</i>/<i>b</i>, or <i>a</i> divided by <i>b</i>, according to the
-notion of division there given, expresses the multiple-part which
-<i>a</i> is of <i>b</i> in every case.</p>
-
-<p>178. When the first of four numbers is the same multiple-part of the
-second which the third is of the fourth, the four are said to be
-<i>geometrically</i><a id="FNanchor_27" href="#Footnote_27" class="fnanchor">[27]</a>
-<i>proportional</i>, or simply <i>proportional</i>. This is a word in
-common use; and it remains to shew that our mathematical definition
-of it, just given, is, in fact, the common notion attached to it. For
-example, suppose a picture is copied on a smaller scale, so that a line
-of two inches long in the original is represented by a line of one inch
-and a half in the copy; we say that the copy is not correct unless all
-the parts of the original are reduced in the same proportion, namely,
-that of 2 to (1½). Since, on dividing two inches into 4 parts, and
-taking 3 of them, we get (1½), the same must be done with all the lines
-in the original, that is, the length of any line in the copy must be
-three parts out of four of its length in the original. Again, interest
-being at 5 per cent, that is, £5 being given for the use of £100, a
-similar proportion of every other sum would be given; the interest of
-£70, for example, would be just such a part of £70 as £5 is of £100.</p>
-
-<p>Since, then, the part which <i>a</i> is of <i>b</i> is expressed by the
-fraction <i>a</i>/<i>b</i>, or any other fraction which is equivalent
-to it, and that which <i>c</i> is of <i>d</i> by <i>c</i>/<i>d</i>,
-it follows, that when <i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>, are
-proportional, <i>a</i>/<i>b</i> = <i>c</i>/<i>d</i>. This equation will
-be the foundation of all our reasoning on proportional quantities; and
-in considering proportionals, it is necessary to observe not only the
-quantities themselves, but also the order in which they come. Thus,
-<i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>, being proportionals, that
-is, <i>a</i> being the same multiple-part of <i>b</i> which <i>c</i>
-is of <i>d</i>, it does not follow that <i>a</i>, <i>d</i>, <i>b</i>,
-and <i>c</i> are proportionals, that is, that <i>a</i> is the same
-<span class="pagenum" id="Page_106">[Pg 106]</span>
-multiple-part of <i>d</i> which <i>b</i> is of <i>c</i>. It is plain
-that <i>a</i> is greater than, equal to, or less than <i>b</i>,
-according as <i>c</i> is greater than, equal to, or less than <i>d</i>.</p>
-
-<p>179. Four numbers, <i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>, being
-proportional in the order written, <i>a</i> and <i>d</i> are called
-the <i>extremes</i>, and <i>b</i> and <i>c</i> the <i>means</i>,
-of the proportion. For convenience, we will call the two extremes,
-or the two means, <i>similar</i> terms, and an extreme and a mean,
-<i>dissimilar</i> terms. Thus, <i>a</i> and <i>d</i> are similar, and
-so are <i>b</i> and <i>c</i>; while <i>a</i> and <i>b</i>, <i>a</i> and
-<i>c</i>, <i>d</i> and <i>b</i>, <i>d</i> and <i>c</i>, are dissimilar.
-It is customary to express the proportion by placing dots between the
-numbers, thus:</p>
-
-<p class="f120"><i>a</i> : <i>b</i> ∷ <i>c</i> : <i>d</i></p>
-
-<p>180. Equal numbers will still remain equal when they have been
-increased, diminished, multiplied, or divided, by equal quantities.
-This amounts to saying that if</p>
-
-<ul class="index fontsize_120">
-<li class="isub3"><i>a</i> = <i>b</i> and <i>p</i> = <i>q</i>,</li>
-<li class="isub3"><i>a</i> + <i>p</i> = <i>b</i> + <i>q</i>,</li>
-<li class="isub3"><i>a</i> - <i>p</i> = <i>b</i> - <i>q</i>,</li>
-<li class="isub3"><i>ap</i> = <i>bq</i>,</li>
-<li class="isub1">&nbsp;</li>
-<li class="isub5"><i>a</i>&nbsp;&emsp;&nbsp;<i>b</i></li>
-<li class="isub3">and &mdash; = &mdash;.</li>
-<li class="isub5"><i>p</i>&nbsp;&emsp;&nbsp;<i>q</i></li>
-</ul>
-
-<p>It is also evident, that <span class="fontsize_120"><i>a</i> + <i>p</i>-<i>p</i>, <i>a</i>
--<i>p</i> + <i>p</i>, <i>ap</i>/<i>p</i>, and <i>a</i>/<i>p</i> ×
-<i>p</i></span>, are all equal to <big><i>a</i></big>.</p>
-
-<p>181. The product of the extremes is equal to the product of the means.
-Let <i>a</i>/<i>b</i> = <i>c</i>/<i>d</i>, and multiply these equal
-numbers by the product <i>bd</i>. Then,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;× <i>bd</i> =&nbsp;</td>
- <td class="tdc u"><i>abd</i></td>
- <td class="tdc" rowspan="2">&nbsp;&emsp;(116) = <i>ad</i>,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">and &nbsp;</td>
- <td class="tdc u"><i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;× <i>bd</i> =&nbsp;</td>
- <td class="tdc u"><i>cbd</i></td>
- <td class="tdc" rowspan="2">&nbsp;= <i>cb</i>:</td>
- </tr><tr>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdc" colspan="5" rowspan="2">hence (180), <i>ad</i> = <i>bc</i>.&nbsp;&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Thus, 6, 8, 21, and 28, are proportional, since</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;6&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;3&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">3 × 7</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">21</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;(180);</td>
- </tr><tr>
- <td class="tdc">8</td>
- <td class="tdc">4</td>
- <td class="tdc">4 × 7</td>
- <td class="tdc">28</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and it appears that 6 × 28 = 8 × 21, since both products are 168.</p>
-
-<p>182. If the product of two numbers be equal to the product of two
-others, these numbers are proportional in any order whatever, provided
-the numbers in the same product are so placed as to be similar terms;
-that is, if <i>ab</i> = <i>pq</i>, we have the following proportions:&mdash;</p>
-
-<ul class="index fontsize_150">
-<li class="isub3"><i>a</i> : <i>p</i> ∷ <i>q</i> : <i>b</i></li>
-<li class="isub3"><i>a</i> : <i>q</i> ∷ <i>p</i> : <i>b</i></li>
-<li class="isub3"><i>b</i> : <i>p</i> ∷ <i>q</i> : <i>a</i></li>
-<li class="isub3"><i>b</i> : <i>q</i> ∷ <i>p</i> : <i>a</i></li>
-<li class="isub3"><i>p</i> : <i>a</i> ∷ <i>b</i> : <i>q</i></li>
-<li class="isub3"><i>p</i> : <i>b</i> ∷ <i>a</i> : <i>q</i></li>
-<li class="isub3"><i>q</i> : <i>a</i> ∷ <i>b</i> : <i>p</i></li>
-<li class="isub3"><i>q</i> : <i>b</i> ∷ <i>a</i> : <i>p</i></li>
-</ul>
-
-<p class="no-indent">To prove any one of these, divide both <i>ab</i> and <i>pq</i> by the
-product of its second and fourth terms; for example, to shew the truth
-of <i>a</i>: <i>q</i> ∷ <i>p</i>: <i>b</i>, divide both <i>ab</i> and
-<i>pq</i> by <i>bq</i>. Then,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="1" summary="" cellpadding="1" >
- <tbody><tr>
- <td class="tdc u"><i>ab</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;, and&nbsp;</td>
- <td class="tdc u"><i>pq</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>p</i></td>
- <td class="tdc" rowspan="2">&nbsp;; hence (180),</td>
- </tr><tr>
- <td class="tdc"><i>bq</i></td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc"><i>bq</i></td>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdc u"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>p</i></td>
- <td class="tdl" colspan="5" rowspan="2">&nbsp;, or <i>a</i> : <i>q</i> ∷ <i>p</i> : <i>b</i> .</td>
- </tr><tr>
- <td class="tdc"><i>q</i></td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_107">[Pg 107]</span>
-The pupil should not fail to prove every one of the eight cases, and to
-verify them by some simple examples, such as 1 × 6 = 2 × 3, which gives
-1: 2 ∷ 3: 6, 3: 1 ∷ 6: 2, &amp;c.</p>
-
-<p>183. Hence, if four numbers be proportional, they are also proportional
-in any other order, provided it be such that similar terms still remain
-similar. For since, when</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="1" summary="" cellpadding="1" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">it follows (181) that <i>ad</i> = <i>bc</i>, all the proportions
-which follow from <i>ad</i> = <i>bc</i>, by the last article, follow also from</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="1" summary="" cellpadding="1" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>184. From (114) it follows that</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2"><big>1</big> +&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>b</i> + <i>a</i></td>
- <td class="tdl" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">and if&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;be</td>
- <td class="tdc" rowspan="2">&nbsp;less than</td>
- <td class="tdc" rowspan="2">&nbsp;<big>1</big>,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">&nbsp;<big>1</big> -&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>b</i> - <i>a</i></td>
- <td class="tdl" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">while if&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;be</td>
- <td class="tdc" colspan="3" rowspan="2">&nbsp;greater than&nbsp;</td>
- <td class="tdc" rowspan="2"><big>1</big>,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdr" rowspan="2">&nbsp;- <big>1</big></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>a</i> - <i>b</i></td>
- <td class="tdl" rowspan="2">.</td>
- </tr><tr>
- <td class="tdr"><i>b</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">Also (122), if&nbsp;&nbsp;</td>
- <td class="tdc u"><i>a</i> + <i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;be</td>
- <td class="tdc" rowspan="2">&nbsp;divided by&nbsp;&nbsp;</td>
- <td class="tdc u"><i>a</i> - <i>b</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdr" rowspan="2">the result is&nbsp;</td>
- <td class="tdc u"><i>a</i> + <i>b</i></td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>a</i> - <i>b</i></td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Hence, <i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>,
-being proportionals, we may obtain other proportions, thus:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">Let<span class="ws2">&nbsp;</span></td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- </tr><tr>
- <td class="tdr"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">Then (114)&nbsp;&emsp;<big>1</big> +&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>1</big> +&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- </tr><tr>
- <td class="tdr"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">or&nbsp;&emsp;&nbsp;</td>
- <td class="tdc u"><i>a</i> + <i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>c</i> + <i>d</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdr">or&nbsp;&emsp;&nbsp;</td>
- <td class="tdl" colspan="3"><i>a</i> + <i>b</i>: <i>b</i> ∷ <i>c</i> + <i>d</i>: <i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>That is, the sum of the first and second is to the second as the sum of
-the third and fourth is to the fourth. For brevity, we shall not state
-in words any more of these proportions, since the pupil will easily
-supply what is wanting.</p>
-
-<p class="f120">Resuming the proportion <i>a</i>: <i>b</i> ∷ <i>c</i>: <i>d</i></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">or&nbsp;&emsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2"><big>1</big> -&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdr" rowspan="2"><big>1</big> -&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdr" rowspan="2">&nbsp;, if&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdr" rowspan="2">&nbsp;be less than <big>1</big>,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">or&nbsp;&emsp;&nbsp;</td>
- <td class="tdc u"><i>b</i> - <i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>d</i> - <i>c</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 no-wrap">that is,&nbsp; &nbsp;<i>b</i>-<i>a</i>: <i>b</i> ∷ <i>d</i>-<i>c</i>: <i>d</i><br />
-&nbsp;&emsp;or,&nbsp;&emsp;<i>a</i>-<i>b</i>: <i>b</i> ∷ <i>c</i>-<i>d</i>: <i>d</i>,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">if&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;be greater than 1.</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_108">[Pg 108]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">Again, since&nbsp;&nbsp;</td>
- <td class="tdc u"><i>a</i> + <i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>c</i> + <i>d</i></td>
-
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">and&nbsp;&nbsp;</td>
- <td class="tdc u"><i>a</i> - <i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>c</i> - <i>d</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;<span class="fontsize_150">(</span></td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;being greater than <big>1</big><span class="fontsize_150">)</span></td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="fontsize_120">dividing the first by the second we have</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>a</i> + <i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdc u"><i>c</i> + <i>d</i></td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>a</i> - <i>b</i></td>
- <td class="tdc"><i>c</i> - <i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120">or &nbsp;<i>a</i> + <i>b</i> : <i>a</i> - <i>b</i> ∷ <i>c</i> + <i>d</i> : <i>c</i> - <i>d</i></p>
-
-<p class="f120">and also &nbsp;<i>a</i> + <i>b</i> : <i>b</i> - <i>a</i> ∷ <i>c</i> + <i>d</i> : <i>d</i> - <i>c</i>,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">if&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;be less than 1.</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- </tr><tr>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>185. Many other proportions might be obtained in the same manner. We
-will, however, content ourselves with writing down a few which can be
-obtained by combining the preceding articles.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>a</i> + <i>b</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>a</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i> + <i>d</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>c</i></td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>a</i> - <i>b</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>c</i> - <i>d</i></td>
- </tr><tr>
- <td class="tdc"><i>a</i> + <i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>a</i> - <i>c</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>b</i> + <i>d</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>b</i> - <i>d</i>.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">In these and all others it must be observed, that
-when such expressions as <i>a</i>-<i>b</i> and <i>c</i>-<i>d</i> occur,
-it is supposed that <i>a</i> is greater than <i>b</i>, and <i>c</i>
-greater than <i>d</i>.</p>
-
-<p>186. If four numbers be proportional, and any two dissimilar terms be
-both multiplied, or both divided by the same quantity, the results are
-proportional. Thus, if <i>a</i>: <i>b</i> ∷ <i>c</i>: <i>d</i>, and
-<i>m</i> and <i>n</i> be any two numbers, we have also the following:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>ma</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdr"><i>b</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>mc</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>d</i></td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>mb</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>md</i></td>
- </tr><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl" rowspan="2"><i>mb</i></td>
- <td class="tdc" rowspan="2">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl" rowspan="2"><i>md</i></td>
- </tr><tr>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>n</i></td>
- </tr><tr>
- <td class="tdc" colspan="7">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>ma</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>nb</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>mc</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdl"><i>nd</i></td>
- </tr><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- </tr><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>m</i></td>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and various others. To prove any one of these,
-recollect that nothing more is necessary to make four numbers
-proportional except that the product of the extremes should be equal to
-that of the means. Take the third of those just given; the product of
-its extremes is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;<i>md</i>, or&nbsp;&nbsp;</td>
- <td class="tdc u"><i>mbc</i></td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">while that of the means is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><i>mb</i>&nbsp;×&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;, or&nbsp;&nbsp;</td>
- <td class="tdc u"><i>mad</i></td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent fontsize_120">But since <i>a</i> : <i>b</i> ∷ <i>c</i> : <i>d</i>,
-by (181) <i>ad</i> = <i>bc</i>,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">whence, by (180), <i>mad</i> = <i>mbc</i>, and&nbsp;</td>
- <td class="tdc u"><i>mad</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u"><i>mbc</i></td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">Hence&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;, and <i>md</i>, are proportionals.&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>187. If the terms of one proportion be multiplied by the terms of a
-second, the products are proportional; that is, if <i>a</i>: <i>b</i> ∷ <i>c</i>: <i>d</i>,
-<span class="pagenum" id="Page_109">[Pg 109]</span>
-and <i>p</i>: <i>q</i> ∷ <i>r</i>: <i>s</i>, it follows that
-<i>ap</i>: <i>bq</i> ∷ <i>cr</i>: <i>ds</i>. For, since <i>ad</i>
-= <i>bc</i>, and <i>ps</i> = <i>qr</i>, by (180) <i>adps</i> =
-<i>bcqr</i>, or <i>ap</i> × <i>ds</i> = <i>bq</i> × <i>cr</i>, whence
-(182) <i>ap</i>: <i>bq</i> ∷ <i>cr</i>: <i>ds</i>.</p>
-
-<p>188. If four numbers be proportional, any similar powers of these
-numbers are also proportional; that is, if</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="3">Then&emsp;&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdc"><i>aa</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>bb</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>cc</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>dd</i></td>
- </tr><tr>
- <td class="tdc"><i>aaa</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>bbb</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>ccc</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>ddd</i></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;&amp;c.&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;&amp;c.&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">For, if we write the proportion twice, thus,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdr">by (187)&emsp;&nbsp;</td>
- <td class="tdc"><i>aa</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>bb</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>cc</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>dd</i></td>
- </tr><tr>
- <td class="tdr">But&emsp;&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdr">Whence (187)&emsp;&nbsp;</td>
- <td class="tdc"><i>aaa</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>bbb</i></td>
- <td class="tdc">&nbsp;<big>∷</big>&nbsp;</td>
- <td class="tdc"><i>ccc</i></td>
- <td class="tdc">&nbsp;<big>:</big>&nbsp;</td>
- <td class="tdc"><i>ddd</i>&emsp;and so on.</td>
- </tr>
- </tbody>
-</table>
-
-<p>189. An expression is said to be homogeneous with respect to any two
-or more letters, for instance, <i>a</i>, <i>b</i>, and <i>c</i>,
-when every term of it contains the same number of letters, counting
-<i>a</i>, <i>b</i>, and <i>c</i> only. Thus, <i>maab</i> + <i>nabc</i>
-+ <i>rccc</i> is homogeneous with respect to <i>a</i>, <i>b</i>, and
-<i>c</i>; and of the third degree, since in each term there is either
-<i>a</i>, <i>b</i>, and <i>c</i>, or one of these repeated alone,
-or with another, so as to make three in all. Thus, 8<i>aaabc</i>,
-12<i>abccc</i>, <i>maaaaa</i>, <i>naabbc</i>, are all homogeneous, and
-of the fifth degree, with respect to <i>a</i>, <i>b</i>, and <i>c</i>
-only; and any expression made by adding or subtracting these from one
-another, will be homogeneous and of the fifth degree. Again <i>ma</i>
-+ <i>mnb</i> is homogeneous with respect to <i>a</i> and <i>b</i>, and
-of the first degree; but it is not homogeneous with respect to <i>m</i>
-and <i>n</i>, though it is so with respect to <i>a</i> and <i>n</i>.
-This being premised, we proceed to a theorem,<a id="FNanchor_28" href="#Footnote_28" class="fnanchor">[28]</a>
-which will contain all the results of (184), (185), and (188).</p>
-
-<p><span class="pagenum" id="Page_110">[Pg 110]</span>
-190. If any four numbers be proportional, and if from the first two,
-<i>a</i> and <i>b</i>, any two homogeneous expressions of the same
-degree be formed; and if from the last two, two other expressions
-be formed, in precisely the same manner, the four results will be
-proportional. For example, if <i>a</i>: <i>b</i> ∷ <i>c</i>:
-<i>d</i>, and if 2<i>aaa</i> + 3<i>aab</i> and <i>bbb</i> + <i>abb</i>
-be chosen, which are both homogeneous with respect to <i>a</i> and
-<i>b</i>, and both of the third degree; and if the corresponding
-expressions 2<i>ccc</i> + 3<i>ccd</i> and <i>ddd</i> + <i>cdd</i> be
-formed, which are made from <i>c</i> and <i>d</i> precisely in the same
-manner as the two former ones from <i>a</i> and <i>b</i>, then will</p>
-
-<p class="f120 no-wrap">2<i>aaa</i> + 3<i>aab</i> : <i>bbb</i> + <i>abb</i> ∷ 2<i>ccc</i> + 3<i>ccd</i> : <i>ddd</i> + <i>cdd</i></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">To prove this, let&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;be called <i>x</i>.</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2">Then, since&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;= <i>x</i>, &nbsp;and</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">b</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdr" rowspan="2">it follows that&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;= <i>x</i>.</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>d</i></td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">But since <i>a</i> divided by <i>b</i> gives <i>x</i>, <i>x</i>
-multiplied by <i>b</i> will give <i>a</i>, or <i>a</i> = <i>bx</i>. For
-a similar reason, <i>c</i> = <i>dx</i>. Put <i>bx</i> and <i>dx</i>
-instead of <i>a</i> and <i>c</i> in the four expressions just given,
-recollecting that when quantities are multiplied together, the result
-is the same in whatever order the multiplications are made; that, for
-example, <i>bxbxbx</i> is the same as <i>bbbxxx</i>.</p>
-
-<p class="f120 no-wrap">Hence, 2<i>aaa</i> + 3<i>aab</i> = 2<i>bxbxbx</i> + 3<i>bxbxb</i><br />
-<span class="ws8">&nbsp;</span>= 2<i>bbbxxx</i> + 3<i>bbbxx</i></p>
-
-<p class="f120 no-wrap">which is <i>bbb</i> multiplied by 2<i>xxx</i> + 3<i>xx</i></p>
-<p class="f120 no-wrap">or<span class="ws3">&nbsp;</span><i>bbb</i> (2<i>xxx</i> + 3<i>xx</i>)<a id="FNanchor_29" href="#Footnote_29" class="fnanchor">[29]</a></p>
-
-<p class="f120 no-wrap">Similarly, 2<i>ccc</i> + 3<i>ccd</i> = <i>ddd</i> (2<i>xxx</i> + 3<i>xx</i>)</p>
-<p class="f120 no-wrap">Also,<span class="ws4">&nbsp;</span><i>bbb</i> + <i>abb</i> = <i>bbb</i> + <i>bxbb</i></p>
-<p class="f120 no-wrap"><span class="ws8">&nbsp;</span>= <i>bbb</i> multiplied by 1 + <i>x</i></p>
-<p class="f120 no-wrap">or<span class="ws6">&nbsp;</span><i>bbb</i>(1 + <i>x</i>)</p>
-
-<p class="f120 no-wrap">Similarly,<span class="ws4">&nbsp;</span><i>ddd</i> + <i>cdd</i> = <i>ddd</i> (1 + <i>x</i>)</p>
-<p class="f120 no-wrap">Now,<span class="ws4">&nbsp;</span><i>bbb</i> : <i>bbb</i> ∷ <i>ddd</i> : <i>ddd</i></p>
-
-<p class="fontsize_120 no-indent">Whence (186),
-<i>bbb</i>(2<i>xxx</i> + 3<i>xx</i>): <i>bbb</i>(1 + <i>x</i>) ∷
-<i>ddd</i>(2<i>xxx</i> + 3<i>xx</i>): <i>ddd</i>(1 + <i>x</i>),
-which, when instead of these expressions their equals just found are
-substituted, becomes 2<i>aaa</i> + 3<i>aab</i>: <i>bbb</i> + <i>abb</i>
-∷ 2<i>ccc</i> + 3<i>ccd</i>: <i>ddd</i> + <i>cdd</i>.</p>
-
-<p><span class="pagenum" id="Page_111">[Pg 111]</span>
-The same reasoning may be applied to any other case, and the pupil
-may in this way prove the following theorems:</p>
-
-<p class="fontsize_120"><span class="ws4">&nbsp;</span>If</p>
-
-<p class="f120 no-wrap"><i>a</i> : <i>b</i> ∷ <i>c</i> : <i>d</i></p>
-<p class="f120 no-wrap">2<i>a</i> + 3<i>b</i> : <i>b</i> ∷ 2<i>c</i> + 3<i>d</i> : <i>d</i></p>
-<p class="f120 no-wrap"><i>aa</i> + <i>bb</i> : <i>aa</i> - <i>bb</i>  ∷ <i>cc</i> + <i>dd</i> : <i>cc</i> - <i>dd</i></p>
-<p class="f120 no-wrap space-below1"><i>mab</i> : 2<i>aa</i> + <i>bb</i> ∷ <i>mcd</i> : 2<i>cc</i> + <i>dd</i></p>
-
-<p>191. If the two means of a proportion be the same, that is, if <i>a</i>
-: <i>b</i> ∷ <i>b</i>: <i>c</i>, the three numbers, <i>a</i>, <i>b</i>,
-and <i>c</i>, are said to be in <i>continued</i> proportion, or in
-<i>geometrical progression</i>. The same terms are applied to a series
-of numbers, of which any three that follow one another are in continued
-proportion, such as</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="3" summary=" " cellpadding="3" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">4</td>
- <td class="tdc">8</td>
- <td class="tdc">16</td>
- <td class="tdc">32</td>
- <td class="tdc">64</td>
- <td class="tdc">&amp;c.</td>
- </tr><tr>
- <td class="tdc" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2">2</td>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc" rowspan="2">&amp;c.</td>
- </tr><tr>
- <td class="tdc over">&nbsp;3&nbsp;</td>
- <td class="tdc over">&nbsp;9&nbsp;</td>
- <td class="tdc over">&nbsp;27&nbsp;</td>
- <td class="tdc over">&nbsp;81&nbsp;</td>
- <td class="tdc over">243</td>
- <td class="tdc over">729</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Which are in continued proportion, since</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">1</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc" rowspan="2">2</td>
- <td class="tdc" rowspan="2">&nbsp;∷&nbsp;</td>
- <td class="tdc" rowspan="2">2</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc" rowspan="2">4</td>
- <td class="tdc" rowspan="4"><span class="ws2">&nbsp;</span></td>
- <td class="tdc" rowspan="2">2</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;∷&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- </tr><tr>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- <td class="tdc">9</td>
- </tr><tr>
- <td class="tdc" rowspan="2">2</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc" rowspan="2">4</td>
- <td class="tdc" rowspan="2">&nbsp;∷&nbsp;</td>
- <td class="tdc" rowspan="2">4</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc" rowspan="2">8</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;∷&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;:&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- </tr><tr>
- <td class="tdc">3</td>
- <td class="tdc">9</td>
- <td class="tdc">9</td>
- <td class="tdc">27</td>
- </tr><tr>
- <td class="tdc" colspan="7">&amp;c.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" colspan="7">&amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p>192. Let <i>a</i>, <i>b</i>, <i>c</i>, <i>d</i>, <i>e</i> be in
-continued proportion; we have then</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><i>a</i> : <i>b</i> ∷ <i>b</i> : <i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;or&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;or&nbsp;&nbsp;</td>
- <td class="tdc" rowspan="2"><i>ac</i> = <i>bb</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>c</i></td>
- </tr><tr>
- <td class="tdc" rowspan="2"><i>b</i> : <i>c</i> ∷ <i>c</i> : <i>d</i></td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc" rowspan="2"><i>bd</i> = <i>cc</i></td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>d</i></td>
- </tr><tr>
- <td class="tdc" rowspan="2"><i>c</i> : <i>d</i> ∷ <i>d</i> : <i>e</i></td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc" rowspan="2"><i>ce</i> = <i>dd</i></td>
- </tr><tr>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>e</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Each term is formed from the preceding, by multiplying
-it by the same number. Thus,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;× <i>a</i> (180);&emsp;<i>c</i> =&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">× <i>b</i>;</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">and since&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,&emsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc"><i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">or&emsp;&nbsp;<i>c</i> =&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;× <i>b</i>.&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- </tr><tr>
- <td class="tdc" rowspan="2">Again,&emsp;&nbsp;<i>d</i> =&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;× <i>c</i>&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">but&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;, which is =&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;;&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>a</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr" rowspan="2">therefore, <i>d</i> =&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;× <i>c</i>, and so on</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">If, then,&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">(which is called the <i>common ratio</i> of the series)</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- </tr><tr>
- <td class="tdc" colspan="3">be denoted by <i>r</i>, we have</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 no-wrap"><i>b</i> = <i>ar</i>&emsp;<i>c</i> = <i>br</i> = <i>arr</i>&emsp;<i>d</i> = <i>cr</i> = <i>arrr</i></p>
-
-<p class="no-indent">and so on; whence the series
-<span class="pagenum" id="Page_112">[Pg 112]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <thead><tr>
- <th class="tdc">&nbsp;</th>
- <th class="tdc"><big><i>a</i></big></th>
- <th class="tdc">&nbsp;</th>
- <th class="tdc"><big><i>b</i></big></th>
- <th class="tdc">&nbsp;</th>
- <th class="tdc"><big><i>c</i></big></th>
- <th class="tdc">&nbsp;</th>
- <th class="tdc"><big><i>d</i></big></th>
- <th class="tdc">&amp;c.</th>
- </tr>
- </thead>
- <tbody><tr>
- <td class="tdr">is&emsp;&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>ar</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>arr</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>arrr</i></td>
- <td class="tdc">&amp;c.</td>
- </tr><tr>
- <td class="tdr">Hence&emsp;&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>arr</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">(186)&emsp;&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>aa</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>aarr</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>aa</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>bb</i></td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">because, <i>b</i> being <i>ar</i>, <i>bb</i> is <i>arar</i> or <i>aarr</i>. Again,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>arrr</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">(186)&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>aaa</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>aaarrr</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>aaa</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>bbb</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>e</i></td>
- <td class="tdc">&nbsp;∷&nbsp;</td>
- <td class="tdc"><i>aaaa</i></td>
- <td class="tdc">&nbsp;:&nbsp;</td>
- <td class="tdc"><i>bbbb</i></td>
- <td class="tdc">&nbsp;, and so on;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">that is, the first bears to the <i>n</i>ᵗʰ term
-from the first the same proportion as the <i>n</i>ᵗʰ power of the first
-to the <i>n</i>ᵗʰ power of the second.</p>
-
-<p>193. A short rule may be found for adding together any number of terms
-of a continued proportion. Let it be first required to add together the
-terms 1, <i>r</i>, <i>rr</i>, &amp;c. where <i>r</i> is greater than
-unity. It is evident that we do not alter any expression by adding or
-subtracting any numbers, provided we afterwards subtract or add the
-same. For example,</p>
-
-<p class="f120 no-wrap"><i>p</i> = <i>p</i> - <i>q</i> + <i>q</i> - <i>r</i>
- + <i>r</i> - <i>s</i> + <i>s</i></p>
-
-<p>Let us take four terms of the series, 1, <i>r</i>, <i>rr</i>, &amp;c. or,</p>
-
-<p class="f120 no-wrap">1 + <i>r</i> + <i>rr</i> + <i>rrr</i></p>
-
-<p>It is plain that</p>
-
-<p class="f120 no-wrap"><i>rrrr</i> - 1 = <i>rrrr</i> - <i>rrr</i> + <i>rrr</i> - <i>rr</i> +
-<i>rr</i> - <i>r</i> + <i>r</i> - 1</p>
-
-<p>Now (54), <span class="fontsize_120"><i>rr</i>-<i>r</i> = <i>r</i>(<i>r</i>-1), <i>rrr</i>
--<i>rr</i> = <i>rr</i>(<i>r</i>-1), <i>rrrr</i>-<i>rrr</i> =
-<i>rrr</i>(<i>r</i>-1)</span>, and the above equation becomes <span class="fontsize_120"><i>rrrr</i>
--1 = <i>rrr</i>(<i>r</i>-1) + <i>rr</i> (<i>r</i>-1) + <i>r</i>
-(<i>r</i>-1) + <i>r</i>-1</span>; which is (54) <span class="fontsize_120"><i>rrr</i> + <i>rr</i> +
-<i>r</i> + 1</span> taken <i>r</i>-1 times. Hence, <i>rrrr</i>-1 divided
-by <i>r</i>-1 will give <span class="fontsize_120">1 + <i>r</i> + <i>rr</i> + <i>rrr</i></span>,
-the sum of the terms required. In this way may be proved the following
-series of equations:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdr u"><i>rr</i> - 1</td>
- </tr><tr>
- <td class="tdc"><i>r</i> - 1</td>
- </tr><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i> + <i>rr</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdr u"><i>rrr</i> - 1</td>
- </tr><tr>
- <td class="tdc"><i>r</i> - 1</td>
- </tr><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i> + <i>rr</i> + <i>rrr</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdr u"><i>rrrr</i> - 1</td>
- </tr><tr>
- <td class="tdc"><i>r</i> - 1</td>
- </tr><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i> + <i>rr</i> + <i>rrr</i> + <i>rrrr</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdr u"><i>rrrrr</i> - 1</td>
- </tr><tr>
- <td class="tdc"><i>r</i> - 1</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_113">[Pg 113]</span>
-If <i>r</i> be less than unity, in order to find 1 + <i>r</i> +
-<i>rr</i> + <i>rrr</i>, observe that</p>
-
-<p class="f120">1 - <i>rrrr</i> = 1 - <i>r</i> + <i>r</i> - <i>rr</i> + <i>rr</i> - <i>rrr</i> + <i>rrr</i> - <i>rrrr</i><br />
-<span class="ws4">&nbsp;</span>= 1 - <i>r</i> + <i>r</i>(1 - <i>r</i>) + <i>rr</i>(1 - <i>r</i>) + <i>rrr</i>(1 - <i>r</i>);</p>
-
-<p class="no-indent">whence, by similar reasoning, 1 + <i>r</i> + <i>rr</i> + <i>rrr</i>
-is found by dividing 1-<i>rrrr</i> by 1-<i>r</i>; and equations
-similar to these just given may be found, which are,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i></td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdr u">1 - <i>rr</i></td>
- </tr><tr>
- <td class="tdc">1 - <i>r</i></td>
- </tr><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i> + <i>rr</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdr u">1 - <i>rrr</i></td>
- </tr><tr>
- <td class="tdc">1 - <i>r</i></td>
- </tr><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i> + <i>rr</i> + <i>rrr</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdr u">1 - <i>rrrr</i></td>
- </tr><tr>
- <td class="tdc">1 - <i>r</i></td>
- </tr><tr>
- <td class="tdl" rowspan="2">1 + <i>r</i> + <i>rr</i> + <i>rrr</i> + <i>rrrr</i></td>
- <td class="tdc" rowspan="2">=</td>
- <td class="tdr u">1 - <i>rrrrr</i></td>
- </tr><tr>
- <td class="tdc">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>The rule is: To find the sum of n terms of the series, 1 + <i>r</i> +
-<i>rr</i> + &amp;c., divide the difference between 1 and the (<i>n</i> +
-1)ᵗʰ term by the difference between 1 and <i>r</i>.</p>
-
-<p>194. This may be applied to finding the sum of any number of terms of
-a continued proportion. Let <i>a</i>, <i>b</i>, <i>c</i>, &amp;c. be the
-terms of which it is required to sum four, that is, to find <i>a</i>
-+ <i>b</i> + <i>c</i> + <i>d</i>, or (192) <i>a</i> + <i>ar</i>
-+ <i>arr</i> + <i>arrr</i>, or (54) a(1 + <i>r</i> + <i>rr</i> +
-<i>rrr</i>), which (193) is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>rrrr</i> - 1</td>
- <td class="tdc" rowspan="2">&nbsp;× &nbsp;<i>a</i>, or&nbsp;</td>
- <td class="tdc u">1 - <i>rrrr</i></td>
- <td class="tdc" rowspan="2">&nbsp;× <i>a</i>,</td>
- </tr><tr>
- <td class="tdc"><i>r</i> - 1</td>
- <td class="tdc">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">according as <i>r</i> is greater or less than unity.
-The first fraction is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>arrrr</i> - <i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;, or (192)&nbsp;</td>
- <td class="tdc u"><i>e</i> - <i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc"><i>r</i> - 1</td>
- <td class="tdc"><i>r</i> - 1</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Similarly, the second is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>a</i> - <i>e</i></td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>The rule, therefore, is: To sum <i>n</i> terms of a continued
-proportion, divide the difference of the (<i>n</i> + 1)ᵗʰ and first
-terms by the difference between unity and the common measure. For
-example, the sum of 10 terms of the series 1 + 3 + 9 + 27 + &amp;c. is
-required. The eleventh term is 59049, and <big>⁽⁵⁹⁰⁴⁹ ⁻ ¹⁾/₍₃₋₁₎</big> is 29524.
-Again, the sum of 18 terms of the series 2 + 1 + ½ + ½ + &amp;c. of
-which the nineteenth term is <big>¹/₁₃₁₀₇₂</big>, is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" rowspan="2"><span class="fontsize_150">2</span> -&nbsp;</td>
- <td class="tdc">&mdash;&mdash;&mdash;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">131072</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">131070</td>
- </tr><tr>
- <td class="tdc" colspan="2">&mdash;&mdash;&mdash;&mdash;&mdash;</td>
- <td class="tdc" rowspan="2">&nbsp;&emsp;=&emsp;&nbsp;<span class="fontsize_150">3</span></td>
- <td class="tdc">&mdash;&mdash;&mdash; .</td>
- </tr><tr>
- <td class="tdc" colspan="2">1 - ½</td>
- <td class="tdc">131072</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_114">[Pg 114]</span></p>
-
-<p class="f120 space-above1">EXAMPLES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">9 terms of</td>
- <td class="tdc">&nbsp;1&nbsp;</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">&nbsp;4&nbsp;</td>
- <td class="tdc">&nbsp;+&nbsp;</td>
- <td class="tdc">&nbsp;16&nbsp;</td>
- <td class="tdc">&nbsp;+ &amp;c.&nbsp;are&nbsp;&nbsp;</td>
- <td class="tdl">87381</td>
- </tr><tr>
- <td class="tdr" rowspan="2">10 &nbsp;&nbsp;......&emsp;&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<big>3</big>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;6&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;12&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+ &amp;c. ...&nbsp;</td>
- <td class="tdc u">847422675</td>
- </tr><tr>
- <td class="tdc">7</td>
- <td class="tdc">49</td>
- <td class="tdc">201768035</td>
- </tr><tr>
- <td class="tdr" rowspan="2">20 &nbsp;&nbsp;......&emsp;&nbsp;</td>
- <td class="tdc">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+ &amp;c. ...&nbsp;</td>
- <td class="tdl u">1048575</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdc">4</td>
- <td class="tdc">8</td>
- <td class="tdl">1048576</td>
- </tr>
- </tbody>
-</table>
-
-<p>195. The powers of a number or fraction greater than unity increase;
-for since 2½ is greater than 1, 2½ × 2½ is 2½ taken more than once,
-that is, is greater than 2½, and so on. This increase goes on without
-limit; that is, there is no quantity so great but that some power of
-2½ is greater. To prove this, observe that every power of 2½ is made
-by multiplying the preceding power by 2½, or by 1 + 1½, that is, by
-adding to the former power that power itself and its half. There will,
-therefore, be more added to the 10th power to form the 11th, than was
-added to the 9th power to form the 10th. But it is evident that if
-any given quantity, however small, be continually added to 2½, the
-result will come in time to exceed any other quantity that was also
-given, however great; much more, then, will it do so if the quantity
-added to 2½ be increased at each step, which is the case when the
-successive powers of 2½ are formed. It is evident, also, that the
-powers of 1 never increase, being always 1; thus, 1 × 1 = 1, &amp;c.
-Also, if <i>a</i> be greater than <i>m</i> times <i>b</i>, the square
-of <i>a</i> is greater than <i>mm</i> times the square of <i>b</i>.
-Thus, if <i>a</i> = 2<i>b</i> + <i>c</i>, where <i>a</i> is greater
-than 2<i>b</i>, the square of <i>a</i>, or <i>aa</i>, which is (68)
-4<i>bb</i> + 4<i>bc</i> + <i>cc</i> is greater than 4<i>bb</i>, and so
-on.</p>
-
-<p>196. The powers of a fraction less than unity continually decrease;
-thus, the square of ⅖, or ⅖ × ⅖, is less than ⅖, being only two-fifths of it.
-This decrease continues without limit; that is, there is no quantity so
-small but that some power of ⅖ is less. For if</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;5&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;<i>x</i>,</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc">2</td>
- </tr><tr>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">,</td>
- </tr><tr>
- <td class="tdc">5</td>
- <td class="tdc"><i>x</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">and the powers of ⅖ are&nbsp;&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;,&nbsp;&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc over"><i>xx</i></td>
- <td class="tdc over"><i>xxx</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on. Since <i>x</i> is greater than 1 (195),
-some power of <i>x</i> may be found which shall be greater than a
-given quantity. Let this be called <i>m</i>; then 1/<i>m</i> is the
-corresponding power of ⅖; and a fraction whose denominator can be
-made as great as we please, can itself be made as small as we please (112).</p>
-
-<p>197. We have, then, in the series</p>
-
-<p class="f120 no-wrap">1&nbsp; <i>r</i>&nbsp; <i>rr</i>&nbsp; <i>rrr</i>&nbsp; <i>rrrr</i>&nbsp; &amp;c.</p>
-
-<p><span class="pagenum" id="Page_115">[Pg 115]</span>
-I. A series of increasing terms, if <i>r</i> be greater than 1. II. Of
-terms having the same value, if <i>r</i> be equal to 1. III. A series
-of decreasing terms, if <i>r</i> be less than 1. In the first two
-cases, the sum</p>
-
-<p class="f120 no-wrap">1 + <i>r</i> + <i>rr</i> + <i>rrr</i> + &amp;c.</p>
-
-<p class="no-indent">may evidently be made as great as we please, by
-sufficiently increasing the number of terms. But in the third this
-may or may not be the case; for though something is added at each
-step, yet, as that augmentation diminishes at every step, we may not
-certainly say that we can, by any number of such augmentations, make
-the result as great as we please. To shew the contrary in a simple
-instance, consider the series,</p>
-
-<p class="f120 no-wrap">1 + ½ + ¼ + ⅛ + ¹/₁₆ + &amp;c.</p>
-
-<p class="no-indent">Carry this series to what extent we may, it will always
-be necessary to add the last term in order to make as much as 2. Thus,</p>
-
-<p class="f120 no-wrap">(1 + ½ + ¼) + ¼ = 1 + ½ + ½ = 1 + 1 = 2<br />
-(1 + ½ + ¼ + ⅛) + ⅛ = 2.<br />
-(1 + ½ + ¼ + ⅛ + ¹/₁₆) + ¹/₁₆ = 2, &amp;c.</p>
-
-<p class="no-indent">But in the series, every term is only the half
-of the preceding; consequently no number of terms, however great, can
-be made as great as 2 by adding one more. The sum, therefore, of 1,
-½, ¼, ⅛ &amp;c. continually approaches to 2, diminishing its distance
-from 2 at every step, but never reaching it. Hence, 2 is celled the
-<i>limit</i> of 1 + ½ + ¼ + &amp;c. We are not, therefore, to conclude
-that <i>every</i> series of decreasing terms has a limit. The contrary
-may be shewn in the very simple series, 1 + ½ + ⅓ + ¼ + &amp;c. which
-may be written thus:</p>
-
-<p class="f120 no-wrap">1 + ½ + (⅓ + ¼) + (⅕ + ... up to ⅛) + (⅑ + ... up to ¹/₁₆)<br />
- + (¹/₁₇ + ... up to ¹/₃₂) + &amp;c.</p>
-
-<p>We have thus divided all the series, except the first two terms, into
-lots, each containing half as many terms as there are units in the
-denominator of its last term. Thus, the fourth lot contains 16 or ³²/₂2
-terms. Each of these lots may be shewn to be greater than ½. Take the
-<span class="pagenum" id="Page_116">[Pg 116]</span>
-third, for example, consisting of ⅑, ¹/₁₀, ¹/₁₁, ¹/₁₂, ¹/₁₃, ¹/₁₄,
-¹/₁₅, and ¹/₁₆. All except ¹/₁₆, the last, are greater than ¹/₁₆;
-consequently, by substituting ¹/₁₆ for each of them, the amount of the
-whole lot would be lessened; and as it would then become ⁸/₁₆, or ½,
-the lot itself is greater than ½. Now, if to 1 + ½, ½ be continually
-added, the result will in time exceed any given number. Still more will
-this be the case if, instead of ½, the several lots written above be
-added one after the other. But it is thus that the series 1 + ½ + ⅓,
-&amp;c. is composed, which proves what was said, that this series has
-no limit.</p>
-
-<p>198. The series 1 + <i>r</i> + <i>rr</i> + <i>rrr</i> + &amp;c. always
-has a limit when <i>r</i> is less than 1. To prove this, let the term
-succeeding that at which we stop be <i>a</i>, whence (194) the sum is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1 - <i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;, or (112)&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc over">1 - <i>r</i></td>
- <td class="tdc over">1 - <i>r</i></td>
- <td class="tdc over">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">The terms decrease without limit (196), whence we may take a term so
-far distant from the beginning, that <i>a</i>, and therefore</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1 - <i>a</i></td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc over">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">shall be as small as we please. But it is evident that in this case</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;-&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- </tr><tr>
- <td class="tdc over">1 - <i>r</i></td>
- <td class="tdc over">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">though always less than</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- </tr><tr>
- <td class="tdc over">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">may be brought as near to</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- </tr><tr>
- <td class="tdc over">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">as we please; that is, the series 1 + <i>r</i> + <i>rr</i> + &amp;c.
-continually approaches to the limit</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc over">1 - <i>r</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Thus 1 + ½ + ¼ + ⅛ + &amp;c. where <i>r</i> = ½, continually
-approaches to</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">or <big>2</big>,</td>
- </tr><tr>
- <td class="tdc over">1 - ½</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">as was shewn in the last article.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr" rowspan="2">The limit of&emsp;&nbsp;</td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">2</span></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c.</td>
- </tr><tr>
- <td class="tdc">3</td>
- <td class="tdc">9</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr" rowspan="2">or&emsp;&nbsp;</td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">2</span></td>
- <td class="tdc" rowspan="2"><span class="fontsize_200">(</span></td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">1</span></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c.</td>
- <td class="tdc" rowspan="2"><span class="fontsize_200">)</span></td>
- <td class="tdc" rowspan="2">is&nbsp;&nbsp;<span class="fontsize_150">3</span></td>
- </tr><tr>
- <td class="tdc">3</td>
- <td class="tdc">9</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr" rowspan="2">...&nbsp;</td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">1</span></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">9</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc">81</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c.</td>
- <td class="tdc" rowspan="2">&nbsp;&emsp;...&nbsp;&emsp;<span class="fontsize_150">10</span></td>
- </tr><tr>
- <td class="tdc over">&nbsp;10&nbsp;</td>
- <td class="tdc over">&nbsp;100&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2">...&nbsp;</td>
- <td class="tdc" rowspan="2"><span class="fontsize_150">5</span></td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;15&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;</td>
- <td class="tdc u">&nbsp;45&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+&nbsp;&amp;c.</td>
- <td class="tdc" rowspan="2">&nbsp;&emsp;...&nbsp;&emsp;<span class="fontsize_150">8¾</span></td>
- </tr><tr>
- <td class="tdc">7</td>
- <td class="tdc">49</td>
- </tr>
- </tbody>
-</table>
-
-<p>199. When the fraction <i>a</i>/<i>b</i> is not equal to
-<i>c</i>/<i>d</i>, but greater, <i>a</i> is said to have to <i>b</i> a
-greater ratio than <i>c</i> has to <i>d</i>; and when <i>a</i>/<i>b</i>
-is less than <i>c</i>/<i>d</i>, <i>a</i> is said to have to <i>b</i>
-a less ratio than <i>c</i> has to <i>d</i>. We propose the following
-questions as exercises, since they follow very simply from this definition.
-<span class="pagenum" id="Page_117">[Pg 117]</span></p>
-
-<p>I. If <i>a</i> be greater than <i>b</i>, and <i>c</i> less than or
-equal to <i>d</i>, <i>a</i> will have a greater ratio to <i>b</i> than
-<i>c</i> has to <i>d</i>.</p>
-
-<p>II. If <i>a</i> be less than <i>b</i>, and <i>c</i> greater than or
-equal to <i>d</i>, <i>a</i> has a less ratio to <i>b</i> than <i>c</i>
-has to <i>d</i>.</p>
-
-<p>III. If <i>a</i> be to <i>b</i> as <i>c</i> is to <i>d</i>, and
-if <i>a</i> have a greater ratio to <i>b</i> than <i>c</i> has to
-<i>x</i>, <i>d</i> is less than <i>x</i>; and if <i>a</i> have a less
-ratio to <i>b</i> than <i>c</i> to <i>x</i>, <i>d</i> is greater than
-<i>x</i>.</p>
-
-<p>IV. <i>a</i> has to <i>b</i> a greater ratio than <i>ax</i> to
-<i>bx</i> + <i>y</i>, and a less ratio than <i>ax</i> to <i>bx</i>-
-<i>y</i>.</p>
-
-<p>200. If <i>a</i> have to <i>b</i> a greater ratio than <i>c</i> has to
-<i>d</i>, <i>a</i> + <i>c</i> has to <i>b</i> + <i>d</i> a less ratio
-than <i>a</i> has to <i>b</i>, but a greater ratio than <i>c</i> has to
-<i>d</i>; or, in other words, if <i>a</i>/<i>b</i> be the greater of
-the two fractions <i>a</i>/<i>b</i> and <i>c</i>/<i>d</i>,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>a</i> + <i>c</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i> + <i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">will be greater than <i>c</i>/<i>d</i>, but less than
-<i>a</i>/<i>b</i>. To shew this, observe that (<i>mx</i> +
-<i>ny</i>)/(<i>m</i> + <i>n</i>) must lie between <i>x</i> and
-<i>y</i>, if <i>x</i> and <i>y</i> be unequal: for if <i>x</i> be the
-less of the two, it is certainly greater than</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>mx</i> + <i>nx</i></td>
- </tr><tr>
- <td class="tdc"><i>m</i> + <i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">or than <i>x</i>; and if <i>y</i> be the greater of the two,
-it is certainly less than</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>my</i> + <i>ny</i></td>
- </tr><tr>
- <td class="tdc"><i>m</i> + <i>n</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">or than <i>y</i>. It therefore lies between <i>x</i> and <i>y</i>.
-Now let <i>a</i>/<i>b</i> be <i>x</i>, and let <i>c</i>/<i>d</i> be <i>y</i>:
-then <i>a</i> = <i>bx</i>, <i>c</i> = <i>dy</i>. Now</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>bx</i> + <i>dy</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i> + <i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">is something between <i>x</i> and <i>y</i>,
-as was just proved; therefore</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>a</i> + <i>c</i></td>
- </tr><tr>
- <td class="tdc"><i>b</i> + <i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">is something between <i>a</i>/<i>b</i> and
-<i>c</i>/<i>d</i>. Again, since <i>a</i>/<i>b</i> and <i>c</i>/<i>d</i>
-are respectively equal to <i>ap</i>/<i>bp</i> and <i>cq</i>/<i>dq</i>,
-and since, as has just been proved,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>ap</i> + <i>cq</i></td>
- </tr><tr>
- <td class="tdc"><i>bp</i> + <i>dq</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">lies between the two last, it also lies between the two first;
-that is, if <i>p</i> and <i>q</i> be any numbers or fractions whatsoever,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>ap</i> + <i>cq</i></td>
- </tr><tr>
- <td class="tdc"><i>bp</i> + <i>dq</i></td>
- </tr>
- </tbody>
-</table>
-<p class="no-indent">lies between <i>a</i>/<i>b</i> and <i>c</i>/<i>d</i>.</p>
-
-<p>201. By the last article we may often form some notion of the value
-of an expression too complicated to be easily calculated. Thus,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="Ordinal Names" cellpadding="2" >
- <tbody><tr>
- <td class="tdr_ws1">1 + <i>x</i></td>
- <td class="tdc" rowspan="2">&nbsp;lies between&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc"><i>x</i></td>
- <td class="tdl" rowspan="2">,&nbsp; or 1 and&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdr_ws1 over">1 + <i>xx</i></td>
- <td class="tdc over">&nbsp;1&nbsp;</td>
- <td class="tdc over"><i>xx</i></td>
- <td class="tdc over">&nbsp;<i>x</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>ax</i> + <i>by</i></td>
- <td class="tdc" rowspan="2">&nbsp;lies between&nbsp;</td>
- <td class="tdc"><i>ax</i></td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc"><i>by</i></td>
- <td class="tdl" rowspan="2">,</td>
- <td class="tdc" colspan="2" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc over"><i>axx</i> + <i>bbyy</i></td>
- <td class="tdc over"><i>axx</i></td>
- <td class="tdc over"><i>bbyy</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">that is, between 1/<i>x</i> and 1/<i>by</i>. And it has been shewn
-that (<i>a</i> + <i>b</i>)/2 lies between <i>a</i> and <i>b</i>, the
-denominator being considered as 1 + 1.</p>
-
-<p>202. It may also be proved that a fraction such as</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc u"><i>a</i> + <i>b</i> + <i>c</i> + <i>d</i> </td>
- </tr><tr>
- <td class="tdc"><i>p</i> + <i>q</i> + <i>r</i> + <i>s</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">always lies among</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;,&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;,&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;, and&nbsp;&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdl" rowspan="2">&nbsp;,&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc"><i>s</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">that is, is less than the greatest of them, and
-greater than the least. <span class="pagenum" id="Page_118">[Pg
-118]</span> Let these fractions be arranged in order of magnitude;
-that is, let <i>a</i>/<i>p</i> be greater than <i>b</i>/<i>q</i>,
-<i>b</i>/<i>q</i> be greater than <i>c</i>/<i>r</i>, and
-<i>c</i>/<i>r</i> greater than <i>d</i>/<i>s</i>. Then by (200)</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc bl br">is<br />less<br />&nbsp;than&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- <td class="tdc bl br">and<br />&nbsp;greater&nbsp;<br />than</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr u"><i>a</i> + <i>b</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdr u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc br bl">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- </tr><tr>
- <td class="tdr"><i>p</i> + <i>q</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdr">&nbsp;<i>p</i>&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- </tr><tr class="greyish">
- <td class="tdr u"><i>a</i> + <i>b</i> + <i>c</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdr u"><i>a</i> + <i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- </tr><tr class="greyish">
- <td class="tdr"><i>p</i> + <i>q</i> + <i>r</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdr"><i>p</i> + <i>q</i></td>
- <td class="tdc"><i>p</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc"><i>s</i></td>
- </tr><tr>
- <td class="tdr u"><i>a</i> + <i>b</i> + <i>c</i> + <i>d</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdr u"><i>a</i> + <i>b</i> + <i>c</i></td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr"><i>p</i> + <i>q</i> + <i>r</i> + <i>s</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdr"><i>p</i> + <i>q</i> + <i>r</i></td>
- <td class="tdc"><i>p</i></td>
- <td class="tdc bl br">&nbsp;</td>
- <td class="tdc"><i>s</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">whence the proposition is evident.</p>
-
-<p>203. It is usual to signify “<i>a</i> is greater than <i>b</i>” by
-<i>a</i> &gt; <i>b</i> and “<i>a</i> is less than <i>b</i>” by <i>a</i> &lt;
-<i>b</i>; the opening of V being turned towards the greater quantity.
-The pupil is recommended to make himself familiar with these signs.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="SECTION_IX">SECTION IX.<br />
-<span class="h_subtitle">ON PERMUTATIONS AND<br /> COMBINATIONS.</span></h3>
-</div>
-
-<p>204. If a number of counters, distinguished by different letters, be
-placed on the table, and any number of them, say four, be taken away,
-the question is, to determine in how many different ways this can be
-done. Each way of doing it gives what is called a <i>combination</i> of
-four, but which might with more propriety be called a <i>selection</i>
-of four. Two combinations or selections are called different, which
-differ in any way whatever; thus, <i>abcd</i> and <i>abce</i> are
-different, <i>d</i> being in one and <i>e</i> in the other, the
-remaining parts being the same. Let there be six counters, <i>a</i>,
-<i>b</i>, <i>c</i>, <i>d</i>, <i>e</i>, and <i>f</i>; the combinations
-of three which can be made out of them are twenty in number, as follow:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="3" summary=" " cellpadding="3" >
- <tbody><tr>
- <td class="tdc"><i>abc</i></td>
- <td class="tdc"><i>ace</i></td>
- <td class="tdc"><i>bcd</i></td>
- <td class="tdc"><i>bef</i></td>
- </tr><tr>
- <td class="tdc"><i>abd</i></td>
- <td class="tdc"><i>acf</i></td>
- <td class="tdc"><i>bce</i></td>
- <td class="tdc"><i>cde</i></td>
- </tr><tr>
- <td class="tdc"><i>abe</i></td>
- <td class="tdc"><i>ade</i></td>
- <td class="tdc"><i>bcf</i></td>
- <td class="tdc"><i>cdf</i></td>
- </tr><tr>
- <td class="tdc"><i>abf</i></td>
- <td class="tdc"><i>adf</i></td>
- <td class="tdc"><i>bde</i></td>
- <td class="tdc"><i>cef</i></td>
- </tr><tr>
- <td class="tdc"><i>acd</i></td>
- <td class="tdc"><i>aef</i></td>
- <td class="tdc"><i>bdf</i></td>
- <td class="tdc"><i>def</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>The combinations of four are fifteen in number, namely,
-<span class="pagenum" id="Page_119">[Pg 119]</span></p>
-
-<table class=" fontsize_120 no-wrap" border="0" cellspacing="3" summary=" " cellpadding="3" >
- <tbody><tr>
- <td class="tdc"><i>abcd</i></td>
- <td class="tdc"><i>abde</i></td>
- <td class="tdc"><i>acde</i></td>
- <td class="tdc"><i>adef</i></td>
- <td class="tdc"><i>bcef</i></td>
- </tr><tr>
- <td class="tdc"><i>abce</i></td>
- <td class="tdc"><i>abdf</i></td>
- <td class="tdc"><i>acdf</i></td>
- <td class="tdc"><i>bcde</i></td>
- <td class="tdc"><i>bdcf</i></td>
- </tr><tr>
- <td class="tdc"><i>abcf</i></td>
- <td class="tdc"><i>abef</i></td>
- <td class="tdc"><i>acef</i></td>
- <td class="tdc"><i>bcdf</i></td>
- <td class="tdc"><i>cdef</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on.</p>
-
-<p>205. Each of these combinations may be written in several different
-orders; thus, <i>abcd</i> may be disposed in any of the following ways:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="3" summary=" " cellpadding="3" >
- <tbody><tr>
- <td class="tdc"><i>abcd</i></td>
- <td class="tdc"><i>acbd</i></td>
- <td class="tdc"><i>acdb</i></td>
- <td class="tdc"><i>abdc</i></td>
- <td class="tdc"><i>adbc</i></td>
- <td class="tdc"><i>adcb</i></td>
- </tr><tr>
- <td class="tdc"><i>bacd</i></td>
- <td class="tdc"><i>cabd</i></td>
- <td class="tdc"><i>cadb</i></td>
- <td class="tdc"><i>badc</i></td>
- <td class="tdc"><i>dabc</i></td>
- <td class="tdc"><i>dacb</i></td>
- </tr><tr>
- <td class="tdc"><i>bcad</i></td>
- <td class="tdc"><i>cbad</i></td>
- <td class="tdc"><i>cdab</i></td>
- <td class="tdc"><i>bdac</i></td>
- <td class="tdc"><i>dbac</i></td>
- <td class="tdc"><i>dcab</i></td>
- </tr><tr>
- <td class="tdc"><i>bcda</i></td>
- <td class="tdc"><i>cbda</i></td>
- <td class="tdc"><i>cdba</i></td>
- <td class="tdc"><i>bdca</i></td>
- <td class="tdc"><i>dbca</i></td>
- <td class="tdc"><i>dcba</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">of which no two are entirely in the same
-order. Each of these is said to be a distinct <i>permutation</i> of
-<i>abcd</i>. Considered as a <i>combination</i>, they are all the same,
-as each contains <i>a</i>, <i>b</i>, <i>c</i>, and <i>d</i>.</p>
-
-<p>206. We now proceed to find how many <i>permutations</i>, each
-containing one given number, can be made from the counters in another
-given number, six, for example. If we knew how to find all the
-permutations containing four counters, we might make those which
-contain five thus: Take any one which contains four, for example,
-<i>abcf</i> in which <i>d</i> and <i>e</i> are omitted; write <i>d</i>
-and <i>e</i> successively at the end, which gives <i>abcfd</i>,
-<i>abcfe</i>, and repeat the same process with every other permutation
-of four; thus, <i>dabc</i> gives <i>dabce</i> and <i>dabcf</i>. No
-permutation of five can escape us if we proceed in this manner,
-provided only we know those of four; for any given permutation of
-five, as <i>dbfea</i>, will arise in the course of the process from
-<i>dbfe</i>, which, according to our rule, furnishes <i>dbfea</i>.
-Neither will any permutation be repeated twice, for <i>dbfea</i>, if
-the rule be followed, can only arise from the permutation <i>dbfe</i>.
-If we begin in this way to find the permutations of two out of the six,</p>
-
-<p class="f120"><i>a</i>  <i>b</i>  <i>c</i>  <i>d</i>  <i>e</i>  <i>f</i></p>
-
-<p class="no-indent">each of these gives five; thus,</p>
-
-<p class="f120"><i>a</i> gives <i>ab</i> <i>ac</i> <i>ad</i> <i>ae</i> <i>af</i></p>
-<p class="f120"><i>b</i>    ...    <i>ba</i> <i>bc</i> <i>bd</i> <i>be</i> <i>bf</i></p>
-
-<p class="no-indent">and the whole number is 6 × 5, or 30.
-<span class="pagenum" id="Page_120">[Pg 120]</span></p>
-
-<p class="no-indent">Again,</p>
-
-<p class="f120"><i>ab</i> gives <i>abc</i> <i>abd</i> <i>abe</i> <i>abf</i></p>
-<p class="f120"><i>ac</i>    ...    &nbsp; <i>acb</i> <i>acd</i> <i>ace</i> <i>acf</i></p>
-
-<p class="no-indent">and here are 30, or 6 × 5 permutations of 2, each of which gives 4
-permutations of 3; the whole number of the last is therefore 6 × 5 × 4,
-or 120.</p>
-
-<p class="no-indent">Again,</p>
-
-<p class="f120"><i>abc</i> gives <i>abcd</i> <i>abce</i> <i>abcf</i></p>
-<p class="f120"><i>abd</i>    ...    <i>abdc</i> <i>abde</i> <i>abdf</i></p>
-
-<p class="no-indent">and here are 120, or 6 × 5 × 4, permutations of
-three, each of which gives 3 permutations of four; the whole number of
-the last is therefore 6 × 5 × 4 × 3, or 360.</p>
-
-<p>In the same way, the number of permutations of 5 is 6 × 5 × 4 × 3 × 2,
-and the number of permutations of six, or the number of different ways
-in which the whole six can be arranged, is 6 × 5 × 4 × 3 × 2 × 1. The
-last two results are the same, which must be; for since a permutation
-of five only omits one, it can only furnish one permutation of six.
-If instead of six we choose any other number, <i>x</i>, the number of
-permutations of two will be <i>x</i>(<i>x</i>-1), that of three will
-be <i>x</i>(<i>x</i>-1)(<i>x</i>-2), that of four <i>x</i>(<i>x</i>
--1)(<i>x</i>-2)(<i>x</i>-3), the rule being: Multiply the whole
-number of counters by the next less number, and the result by the next
-less, and so on, until as many numbers have been multiplied together
-as there are to be counters in each permutation: the product will be
-the whole number of permutations of the sort required. Thus, out of 12
-counters, permutations of four may be made to the number of 12 × 11 ×
-10 × 9, or 11880.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>207. In how many different ways can eight persons be arranged
-on eight seats?</p>
-
-<p class="author"><i>Answer</i>, 40320.</p>
-
-<p>In how many ways can eight persons be seated at a round table, so that
-all shall not have the same neighbours in any two arrangements?<a id="FNanchor_30" href="#Footnote_30" class="fnanchor">[30]</a></p>
-
-<p class="author"><i>Answer</i>, 5040.</p>
-
-<p><span class="pagenum" id="Page_121">[Pg 121]</span>
-If the hundredth part of a farthing be given for every different
-arrangement which can be made of fifteen persons, to how much will
-the whole amount?</p>
-
-<p class="author"><i>Answer</i>, £13621608.</p>
-
-<p>Out of seventeen consonants and five vowels, how many words can
-be made, having two consonants and one vowel in each?</p>
-
-<p class="author"><i>Answer</i>, 4080.</p>
-
-<p>208. If two or more of the counters have the same letter upon them,
-the number of distinct permutations is less than that given by the
-last rule. Let there be <i>a</i>, <i>a</i>, <i>a</i>, <i>b</i>,
-<i>c</i>, <i>d</i>, and, for a moment, let us distinguish between the
-three as thus, <i>a</i>, <i>a′</i>, <i>a″</i>. Then, <i>abca′a″d</i>,
-and <i>a″bcaa′d</i> are reckoned as distinct permutations in the
-rule, whereas they would not have been so, had it not been for the
-accents. To compute the number of distinct permutations, let us make
-one with <i>b</i>, <i>c</i>, and <i>d</i>, leaving places for the
-<i>a</i>s, thus, ( ) <i>bc</i> ( ) ( ) <i>d</i>. If the <i>a</i>s
-had been distinguished as <i>a</i>, <i>a′</i>, <i>a″</i>, we might
-have made 3 × 2 × 1 distinct permutations, by filling up the vacant
-places in the above, all which six are the same when the <i>a</i>s
-are not distinguished. Hence, to deduce the number of permutations of
-<i>a</i>, <i>a</i>, <i>a</i>, <i>b</i>, <i>c</i>, <i>d</i>, from that of
-<i>aa′a″bcd</i>, we must divide the latter by 3 × 2 × 1, or 6, which gives</p>
-
-<ul class="index fontsize_120">
-<li class="isub3 u">6 × 5 × 4 × 3 × 2 × 1</li>
-<li class="isub6">3 × 2 × 1</li>
-</ul>
-
-<p class="no-indent">or 120. Similarly, the number of permutations of <i>aaaabbbcc</i> is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">9 × 8 × 7 × 6 × 5 × 4 × 3 × 2 × 1</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc">4 × 3 × 2 × 1 × 3 × 2 × 1 × 2 × 1</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-above1">EXERCISE.</p>
-
-<p>How many variations can be made of the order of the letters in the
-word antitrinitarian?</p>
-
-<p class="author"><i>Answer</i>, 126126000.</p>
-
-<p>209. From the number of permutations we can easily deduce the number of
-combinations. But, in order to form these combinations independently,
-we will shew a method similar to that in (206). If we know the
-combinations of two which can be made out of <i>a</i>, <i>b</i>,
-<i>c</i>, <i>d</i>, <i>e</i>, we can find the combinations of three,
-by writing successively at the end of each combination of two, the
-letters which come after the last contained in it. Thus, <i>ab</i>
-gives <i>abc</i>, <i>abd</i>, <i>abe</i>; <i>ad</i> gives <i>ade</i>
-only. No combination of three can escape us if we proceed in this
-manner, provided only we know the combinations of two; for any given
-combination of three, as <i>acd</i>, will arise in the course of
-the process from <i>ac</i>, which, according to our rule, furnishes
-<span class="pagenum" id="Page_122">[Pg 122]</span>
-<i>acd</i>. Neither will any combination be repeated
-twice, for <i>acd</i>, if the rule be followed, can only arise from <i>ac</i>, since
-neither <i>ad</i> nor <i>cd</i> furnishes it. If we begin in this way to find the
-combinations of the five,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary="" cellpadding="4" >
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><big><b><i>a</i></b></big></td>
- <td class="tdc"><big><b><i>b</i></b></big></td>
- <td class="tdc"><big><b><i>c</i></b></big></td>
- <td class="tdc"><big><b><i>d</i></b></big></td>
- <td class="tdc"><big><b><i>e</i></b></big></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>a</i></td>
- <td class="tdc">gives</td>
- <td class="tdc"><i>ab</i></td>
- <td class="tdc"><i>ac</i></td>
- <td class="tdc"><i>ad</i></td>
- <td class="tdc"><i>ae</i></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bc</i></td>
- <td class="tdc"><i>bd</i></td>
- <td class="tdc"><i>be</i></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>cd</i></td>
- <td class="tdc"><i>ce</i></td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>de</i></td>
- </tr><tr>
- <td class="tdl">Of these,&nbsp;&nbsp;</td>
- <td class="tdc"><i>ab</i></td>
- <td class="tdc">gives</td>
- <td class="tdc"><i>abc</i></td>
- <td class="tdc"><i>abd</i></td>
- <td class="tdc"><i>abe</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>ac</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>acd</i></td>
- <td class="tdc"><i>ace</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>ad</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>ade</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bc</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bcd</i></td>
- <td class="tdc"><i>bce</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bd</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bde</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>cd</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>cde</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="7"><span class="ws3">&nbsp;</span><b><i>ae</i>&emsp;<i>be</i>&emsp;<i>ce</i></b>&emsp;and&emsp;<b><i>de</i></b>&emsp;give none.</td>
- </tr><tr>
- <td class="tdl">Of these,&nbsp;&nbsp;</td>
- <td class="tdc"><i>abc</i></td>
- <td class="tdc">gives</td>
- <td class="tdc"><i>abcd</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>abce</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>abd</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>abde</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>acd</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>acde</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bcd</i></td>
- <td class="tdc">····</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>bcde</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="7">Those which contain <b><i>e</i></b> give none, as before.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Of the last, <i>abcd</i> gives <i>abcde</i>, and
-the others none, which is evidently true, since only one selection of
-five can be made out of five things.</p>
-
-<p>210. The rule for calculating the number of combinations is derived
-directly from that for the number of permutations. Take 7 counters;
-then, since the number of permutations of two is 7 × 6, and since
-two permutations, <i>ba</i> and <i>ab</i>, are in any combination
-<i>ab</i>, the number of combinations is half that of the permutations,
-or (7 × 6)/2. Since the number of permutations of three is 7 × 6 × 5,
-and as each combination <i>abc</i> has 3 × 2 × 1 permutations, the
-number of combinations of three is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">7 × 6 × 5</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Also, since any combination of four, <i>abcd</i>, contains
-4 × 3 × 2 × 1 permutations, the number of combinations of four is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">7 × 6 × 5 × 4</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3 × 4</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on. The rule is: To find the number of combinations,
-each containing <i>n</i> counters, divide the corresponding number of
-<span class="pagenum" id="Page_123">[Pg 123]</span>
-permutations by the product of 1, 2, 3, &amp;c. up to <i>n</i>. If
-<i>x</i> be the whole number, the number of combinations of two is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>x</i>(<i>x</i> - 1)</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc">1 × 2</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">that of three is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>x</i>(<i>x</i> - 1)(<i>x</i> - 2)</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">that of four is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>x</i>(<i>x</i> - 1)(<i>x</i> - 2)(<i>x</i> - 3)</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3 × 4</td>
- </tr>
- </tbody>
-</table>
-
-<p>211. The rule may in half the cases be simplified, as follows. Out of
-ten counters, for every distinct selection of seven which is taken, a
-distinct combination of 3 is left. Hence, the number of combinations
-of seven is as many as that of three. We may, therefore, find the
-combinations of three instead of those of seven; and we must moreover
-expect, and may even assert, that the two formulæ for finding these two
-numbers of combinations are the same in result, though different in
-form. And so it proves; for the number of combinations of seven out of
-ten is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">10 × 9 × 8 × 7 × 6 × 5 × 4</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3 × 4 × 5 × 6 × 7</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">in which the product 7 × 6 × 5 × 4 occurs in both terms, and therefore
-may be removed from both (108), leaving</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">10 × 9 × 8</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which is the number of combinations of three out of ten. The same may
-be shewn in other cases.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>How many combinations of four can be made out of twelve things?</p>
-
-<p class="author"><i>Answer</i>, 495.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="Ordinal Names" cellpadding="0" >
- <tbody><tr>
- <td class="tdc">What number of</td>
- <td class="tdc" rowspan="4"><img src="images/cbl-4.jpg" alt="" width="23" height="82" />&nbsp;</td>
- <td class="tdr">6</td>
- <td class="tdc" rowspan="4">&nbsp;<img src="images/cbr-4.jpg" alt="" width="23" height="82" />&nbsp;</td>
- <td class="tdc" rowspan="4">&nbsp;out of&nbsp;</td>
- <td class="tdc" rowspan="4">&nbsp;<img src="images/cbl-4.jpg" alt="" width="23" height="82" />&nbsp;</td>
- <td class="tdr">8</td>
- <td class="tdc" rowspan="4">&nbsp;<img src="images/cbr-4.jpg" alt="" width="23" height="82" />&nbsp;</td>
- <td class="tdc" rowspan="4">&nbsp;<i>Answer</i>,&nbsp;</td>
- <td class="tdc" rowspan="4">&nbsp;<img src="images/cbl-4.jpg" alt="" width="23" height="82" />&nbsp;</td>
- <td class="tdr">28</td>
- </tr><tr>
- <td class="tdc">combinations</td>
- <td class="tdr">4</td>
- <td class="tdr">11</td>
- <td class="tdr">330</td>
- </tr><tr>
- <td class="tdc">can be made of&nbsp;&nbsp;</td>
- <td class="tdr">26</td>
- <td class="tdr">28</td>
- <td class="tdr">378</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">6</td>
- <td class="tdr">15</td>
- <td class="tdr">5005</td>
- </tr>
- </tbody>
-</table>
-
-<p>How many combinations can be made of 13 out of 52; or how many
-different hands may a person hold at the game of whist?</p>
-
-<p class="author"><i>Answer</i>, 635013559600.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-<p><span class="pagenum" id="Page_124">[Pg 124]</span></p>
-
-<div class="chapter">
-<h2 class="nobreak">BOOK II.</h2>
-</div>
-
-<p class="f120"><b>COMMERCIAL ARITHMETIC.</b></p>
-
-<h3 id="SECTION_2_I">SECTION I.<br /><span class="h_subtitle">WEIGHTS, MEASURES, &amp;C.</span></h3>
-
-<p>212. In making the calculations which are necessary in commercial
-affairs, no more processes are required than those which have been
-explained in the preceding book. But there is still one thing
-wanted&mdash;not to insure the accuracy of our calculations, but to enable
-us to compare and judge of their results. We have hitherto made use of
-a single unit (15), and have treated of other quantities which are made
-up of a number of units, in Sections II., III., and IV., and of those
-which contain parts of that unit in Sections V. and VI. Thus, if we are
-talking of distances, and take a mile as the unit, any other length may
-be represented,<a id="FNanchor_31" href="#Footnote_31" class="fnanchor">[31]</a>
-either by a certain number of miles, or a certain
-number of parts of a mile, and (1 meaning one mile) may be expressed
-<span class="pagenum" id="Page_125">[Pg 125]</span>
-either by a whole number or a fraction. But we can easily see that in
-many cases inconveniences would arise. Suppose, for example, I say,
-that the length of one room is ¹/₁₈₀ of a mile, and of another ¹/₁₇₄
-of a mile, what idea can we form as to how much the second is longer
-than the first? It is necessary to have some smaller measure; and if
-we divide a mile into 1760 equal parts, and call each of these parts a
-yard, we shall find that the length of the first room is 9 yards and
-⁷/₉ of a yard, and that of the second 10 yards and ¹⁰/₈₇ of a yard.
-From this we form a much better notion of these different lengths,
-but still not a very perfect one, on account of the fractions ⁷/₉ and
-¹⁰/₈₇. To get a clearer idea of these, suppose the yard to be divided
-into three equal parts, and each of these parts to be called a foot;
-then ⁷/₉ of a yard contains 2⅓ feet, and ¹⁰/₈₇ of a yard contains ³⁰/₈₇
-of a foot, or a little more than ⅓ of a foot. Therefore the length
-of the first room is now 9 yards, 2 feet, and ⅓ of a foot; that of
-the second is 10 yards and a little more than ⅓ of a foot. We see,
-then, the convenience of having large measures for large quantities,
-and smaller measures for small ones; but this is done for convenience
-only, for it is <i>possible</i> to perform calculations upon any sort
-of quantity, with one measure alone, as certainly as with more than
-one; and not only possible, but more convenient, as far as the mere
-calculation is concerned.</p>
-
-<p>The measures which are used in this country are not those which would
-have been chosen had they been made all at one time, and by a people
-well acquainted with arithmetic and natural philosophy. We proceed
-to shew how the results of the latter science are made useful in
-our system of measures. Whether the circumstances introduced are
-sufficiently well known to render the following methods exact enough
-for the recovery of <i>astronomical</i> standards, may be matter of
-opinion; but no doubt can be entertained of their being amply correct
-for commercial purposes.</p>
-
-<p><span class="pagenum" id="Page_126">[Pg 126]</span>
-It is evidently desirable that weights and measures should always
-continue the same, and that posterity should be able to replace any
-one of them when the original measure is lost. It is true that a yard,
-which is now exact, is kept by the public authorities; but if this were
-burnt by accident,<a id="FNanchor_32" href="#Footnote_32" class="fnanchor">[32]</a>
-how are those who shall live 500 years hence to know what was the
-length which their ancestors called a yard? To ensure them this
-knowledge, the measure must be derived from something which cannot
-be altered by man, either from design or accident. We find such a
-quantity in the time of the daily revolution of the earth, and also
-in the length of the year, both of which, as is shewn in astronomy,
-will remain the same, at least for an enormous number of centuries,
-unless some great and totally unknown change take place in the solar
-system. So long as astronomy is cultivated, it is impossible to suppose
-that either of these will be lost, and it is known that the latter is
-365·24224 mean solar days, or about 365¼ of the average interval which
-elapses between noon and noon, that is, between the times when the sun
-is highest in the heavens. Our year is made to consist of 365 days,
-and the odd quarter is allowed for by adding one day to every fourth
-year, which gives what we call leap-year. This is the same as adding ¼
-of a day to each year, and is rather too much, since the excess of the
-year above 365 days is not ·25 but ·24224 of a day. The difference is
-·00776 of a day, which is the quantity by which our average year is too
-long. This amounts to a day in about 128 years, or to about 3 days in
-4 centuries. The error is corrected by allowing only one out of four
-of the years which close the centuries to be leap-years. Thus,
-<span class="smcap">a.d.</span> 1800 and 1900 are not leap-years,
-but 2000 is so.</p>
-
-<p>213. The day is therefore the first measure obtained, and is divided
-into 24 parts or hours, each of which is divided into 60 parts or
-minutes, and each of these again into 60 parts or seconds. One second,
-marked thus, 1″,<a id="FNanchor_33" href="#Footnote_33" class="fnanchor">[33]</a>
-is therefore the 86400ᵗʰ part of a day, and the following is the
-<span class="pagenum" id="Page_127">[Pg 127]</span></p>
-
-<p class="f120 space-above1">MEASURE OF TIME.<a id="FNanchor_34" href="#Footnote_34" class="fnanchor">[34]</a></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">60</td>
- <td class="tdl">&nbsp;&nbsp;<i>seconds</i></td>
- <td class="tdc">&nbsp;are&nbsp;</td>
- <td class="tdl_ws1">1 <i>minute</i></td>
- <td class="tdc" rowspan="5"><span class="ws2">&nbsp;</span></td>
- <td class="tdl">1 m.</td>
- </tr><tr>
- <td class="tdr">60</td>
- <td class="tdl">&nbsp;&nbsp;<i>minutes</i></td>
- <td class="tdc">&nbsp;”&nbsp;</td>
- <td class="tdl_ws1">1 <i>hour</i></td>
- <td class="tdl">1 h.</td>
- </tr><tr>
- <td class="tdr">24</td>
- <td class="tdl">&nbsp;&nbsp;<i>hours</i></td>
- <td class="tdc">&nbsp;”&nbsp;</td>
- <td class="tdl_ws1">1 <i>day</i></td>
- <td class="tdl">1 d.</td>
- </tr><tr>
- <td class="tdr">7</td>
- <td class="tdl">&nbsp;&nbsp;<i>days</i></td>
- <td class="tdc">&nbsp;”&nbsp;</td>
- <td class="tdl_ws1">1 <i>week</i></td>
- <td class="tdl">1 wk.</td>
- </tr><tr>
- <td class="tdr">365</td>
- <td class="tdl">&nbsp;&nbsp;<i>days</i></td>
- <td class="tdc">&nbsp;”&nbsp;</td>
- <td class="tdl_ws1">1 <i>year</i></td>
- <td class="tdl">1 yr.</td>
- </tr>
- </tbody>
-</table>
-
-<p>214. The <i>second</i> having been obtained, a pendulum can be
-constructed which shall, when put in motion, perform one vibration
-in exactly one second, in the latitude of Greenwich.<a id="FNanchor_35" href="#Footnote_35" class="fnanchor">[35]</a>
-If we were inventing measures, it would be convenient to call the length of
-this pendulum a yard, and make it the standard of all our measures of
-length. But as there is a yard already established, it will do equally
-well to tell the length of the pendulum in yards. It was found by
-commissioners appointed for the purpose, that this pendulum in London
-was 39·1393 inches, or about one yard, three inches, and ⁵/₃₆ of an
-inch. The following is the division of the yard.</p>
-
-<p class="f120 space-above1">MEASURES OF LENGTH.</p>
-
-<p class="center">The lowest measure is a barleycorn.<a id="FNanchor_36" href="#Footnote_36" class="fnanchor">[36]</a></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">3</td>
- <td class="tdl">&nbsp;&nbsp;<i>barleycorns</i><span class="ws3">are</span></td>
- <td class="tdl_ws1">1 <i>inch</i></td>
- <td class="tdl_ws1">1 in.</td>
- </tr><tr>
- <td class="tdr">12</td>
- <td class="tdl">&nbsp;&nbsp;<i>inches</i></td>
- <td class="tdl_ws1">1 <i>foot</i></td>
- <td class="tdl_ws1">1 ft.</td>
- </tr><tr>
- <td class="tdr">3</td>
- <td class="tdl">&nbsp;&nbsp;<i>feet</i></td>
- <td class="tdl_ws1">1 <i>yard</i></td>
- <td class="tdl_ws1">1 yd.</td>
- </tr><tr>
- <td class="tdr">5½</td>
- <td class="tdl">&nbsp;&nbsp;<i>yards</i></td>
- <td class="tdl_ws1">1 <i>pole</i></td>
- <td class="tdl_ws1">1 po.</td>
- </tr><tr>
- <td class="tdr">40</td>
- <td class="tdl">&nbsp;&nbsp;<i>poles</i> or 220 <i>yards</i></td>
- <td class="tdl_ws1">1 <i>furlong</i></td>
- <td class="tdl_ws1">1 fur.</td>
- </tr><tr>
- <td class="tdr">8</td>
- <td class="tdl">&nbsp;&nbsp;<i>furlongs</i> or 1760 <i>yards</i></td>
- <td class="tdl_ws1">1 <i>mile</i></td>
- <td class="tdl_ws1">1 mi.</td>
- </tr><tr>
- <td class="tdl">Also&emsp;&nbsp;</td>
- <td class="tdl" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr">6</td>
- <td class="tdl">&nbsp;&nbsp;<i>feet</i></td>
- <td class="tdl_ws1">1 <i>fathom</i></td>
- <td class="tdl_ws1">1 fth.</td>
- </tr><tr>
- <td class="tdr">69⅓</td>
- <td class="tdl">&nbsp;&nbsp;<i>miles</i></td>
- <td class="tdl_ws1">1 <i>degree</i></td>
- <td class="tdl_ws1">1 deg. or 1°.</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_128">[Pg 128]</span>
-A geographical mile is <big>¹/₆₀</big>th of a degree, and three such miles are one
-nautical league.</p>
-
-<p>In the measurement of cloth or linen the following are also used:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">2¼</td>
- <td class="tdl_ws1">inches <span class="ws2">are</span></td>
- <td class="tdl_ws1">1 nail</td>
- <td class="tdl_ws1">1 nl.</td>
- </tr><tr>
- <td class="tdr">4</td>
- <td class="tdl_ws1">nails</td>
- <td class="tdl_ws1">1 quarter (of a yard)</td>
- <td class="tdl_ws1">1 qr.</td>
- </tr><tr>
- <td class="tdr">3</td>
- <td class="tdl_ws1">quarters</td>
- <td class="tdl_ws1">1 Flemish ell</td>
- <td class="tdl_ws1">1 Fl. e.</td>
- </tr><tr>
- <td class="tdr">5</td>
- <td class="tdl_ws1">quarters</td>
- <td class="tdl_ws1">1 English ell</td>
- <td class="tdl_ws1">1 E. e.</td>
- </tr><tr>
- <td class="tdr">6</td>
- <td class="tdl_ws1">quarters</td>
- <td class="tdl_ws1">1 French ell</td>
- <td class="tdl_ws1">1 Fr. e.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-above1">215. MEASURES OF SURFACE, OR SUPERFICIES.</p>
-
-<p>All surfaces are measured by square inches, square feet, &amp;c.; the
-square inch being a square whose side is an inch in length, and so on.
-The following measures may be deduced from the last, as will afterwards
-appear.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">144</td>
- <td class="tdl_ws1">square inches&emsp;are</td>
- <td class="tdl_ws1">1 square foot</td>
- <td class="tdl_ws1">1 sq. ft.</td>
- </tr><tr>
- <td class="tdr">9</td>
- <td class="tdl_ws1">square feet</td>
- <td class="tdl_ws1">1 square yard</td>
- <td class="tdl_ws1">1 sq. yd.</td>
- </tr><tr>
- <td class="tdr">30¼</td>
- <td class="tdl_ws1">square yards</td>
- <td class="tdl_ws1">1 square pole</td>
- <td class="tdl_ws1">1 sq. p.</td>
- </tr><tr>
- <td class="tdr">40</td>
- <td class="tdl_ws1">square poles</td>
- <td class="tdl_ws1">1 rood</td>
- <td class="tdl_ws1">1 rd.</td>
- </tr><tr>
- <td class="tdr">4</td>
- <td class="tdl_ws1">roods</td>
- <td class="tdl_ws1">1 acre</td>
- <td class="tdl_ws1">1 ac.</td>
- </tr>
- </tbody>
-</table>
-
-<p>Thus, the acre contains 4840 square yards, which is ten times a square
-of 22 yards in length and breadth. This 22 yards is the length which
-land-surveyors’ chains are made to have, and the chain is divided into
-100 links, each ·22 of a yard or 7·92 inches. An acre is then 10 square
-chains. It may also be noticed that a square whose side is 69⁴/₇ yards
-is nearly an acre, not exceeding it by ⅕ of a square foot.</p>
-
-<p class="f120 space-above1">216. MEASURES OF SOLIDITY OR CAPACITY.<a id="FNanchor_37" href="#Footnote_37" class="fnanchor">[37]</a></p>
-
-<p>Cubes are solids having the figure of dice. A cubic inch is a cube each
-of whose sides is an inch, and so on.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">1728</td>
- <td class="tdl_ws1">cubic inches&emsp;are</td>
- <td class="tdl_ws1">1 cubic foot</td>
- <td class="tdl_ws1">1 c. ft.</td>
- </tr><tr>
- <td class="tdr">27</td>
- <td class="tdl_ws1">cubic feet</td>
- <td class="tdl_ws1">1 cubic yard</td>
- <td class="tdl_ws1">1 c. yd.</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_129">[Pg 129]</span>
-This measure is not much used, except in purely mathematical
-questions. In the measurements of different commodities various measures
-were used, which are now reduced, by act of parliament, to one.
-This is commonly called the imperial measure, and is as follows:</p>
-
-<p class="f120 space-above1">MEASURE OF LIQUIDS AND<br />OF ALL DRY GOODS.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">4</td>
- <td class="tdl_ws1"><i>gills</i>&nbsp;&emsp;are</td>
- <td class="tdl_ws1">1 <i>pint</i></td>
- <td class="tdl_ws1">1 pt.</td>
- </tr><tr>
- <td class="tdr">2</td>
- <td class="tdl_ws1"><i>pints</i></td>
- <td class="tdl_ws1">1 <i>quart</i></td>
- <td class="tdl_ws1">1 qt.</td>
- </tr><tr>
- <td class="tdr">4</td>
- <td class="tdl_ws1"><i>quarts</i></td>
- <td class="tdl_ws1">1 <i>gallon</i></td>
- <td class="tdl_ws1">1 gall.</td>
- </tr><tr>
- <td class="tdr">2</td>
- <td class="tdl_ws1"><i>gallons</i></td>
- <td class="tdl_ws1">1 <i>peck</i><a id="FNanchor_38" href="#Footnote_38" class="fnanchor">[38]</a></td>
- <td class="tdl_ws1">1 pk.</td>
- </tr><tr>
- <td class="tdr">4</td>
- <td class="tdl_ws1"><i>pecks</i></td>
- <td class="tdl_ws1">1 <i>bushel</i></td>
- <td class="tdl_ws1">1 bu.</td>
- </tr><tr>
- <td class="tdr">8</td>
- <td class="tdl_ws1"><i>bushels</i></td>
- <td class="tdl_ws1">1 <i>quarter</i></td>
- <td class="tdl_ws1">1 qr.</td>
- </tr><tr>
- <td class="tdr">5</td>
- <td class="tdl_ws1"><i>quarters</i></td>
- <td class="tdl_ws1">1 <i>load</i></td>
- <td class="tdl_ws1">1 ld.</td>
- </tr>
- </tbody>
-</table>
-
-<p>The gallon in this measure is about 277·274 cubic inches; that is, very
-nearly 277¼ cubic inches.<a id="FNanchor_39" href="#Footnote_39" class="fnanchor">[39]</a></p>
-
-<p>217. The smallest weight in use is the grain, which is thus determined.
-A vessel whose interior is a cubic inch, when filled with
-water,<a id="FNanchor_40" href="#Footnote_40" class="fnanchor">[40]</a>
-has its weight increased by 252·458 grains. Of the grains so determined,
-7000 are a pound <i>averdupois</i>, and 5760 a pound <i>troy</i>. The
-first pound is always used, except in weighing precious metals and
-stones, and also medicines. It is divided as follows:
-<span class="pagenum" id="Page_130">[Pg 130]</span></p>
-
-<p class="f120 space-above1">AVERDUPOIS WEIGHT.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">27</td>
- <td class="tdc">¹¹/₃₂</td>
- <td class="tdl_ws1"><i>grains</i><span class="ws5">are</span></td>
- <td class="tdl_ws1">1 <i>dram</i></td>
- <td class="tdl_ws1">1 dr.</td>
- </tr><tr>
- <td class="tdr">6</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1"><i>drams</i>, or <i>drachms</i></td>
- <td class="tdl_ws1">1 <i>ounce</i><a id="FNanchor_41" href="#Footnote_41" class="fnanchor">[41]</a></td>
- <td class="tdl_ws1">1 oz.</td>
- </tr><tr>
- <td class="tdr">16</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1"><i>ounces</i></td>
- <td class="tdl_ws1">1 <i>pound</i></td>
- <td class="tdl_ws1">1 lb.</td>
- </tr><tr>
- <td class="tdr">28</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1"><i>pounds</i></td>
- <td class="tdl_ws1">1 <i>quarter</i></td>
- <td class="tdl_ws1">1 qr.</td>
- </tr><tr>
- <td class="tdr">4</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1"><i>quarters</i></td>
- <td class="tdl_ws1">1 <i>hundred-weight</i></td>
- <td class="tdl_ws1">1 cwt.</td>
- </tr><tr>
- <td class="tdr">20</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl_ws1"><i>hundred-weight</i></td>
- <td class="tdl_ws1">1 <i>ton</i></td>
- <td class="tdl_ws1">1 ton.</td>
- </tr>
- </tbody>
-</table>
-
-<p>The pound averdupois contains 7000 grains. A cubic foot of water weighs
-62·3210606 pounds averdupois, or 997·1369691 ounces.</p>
-
-<p>For the precious metals and for medicines, the pound troy, containing
-5760 grains, is used, but is differently divided in the two cases. The
-measures are as follow:</p>
-
-<p class="f120 space-above1">TROY WEIGHT.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">24</td>
- <td class="tdl_ws1"><i>grains</i><span class="ws3">are</span></td>
- <td class="tdl_ws1">1 <i>pennyweight</i></td>
- <td class="tdl_ws1">1 dwt.</td>
- </tr><tr>
- <td class="tdr">20</td>
- <td class="tdl_ws1"><i>pennyweights</i></td>
- <td class="tdl_ws1">1 <i>ounce</i></td>
- <td class="tdl_ws1">1 oz.</td>
- </tr><tr>
- <td class="tdr">12</td>
- <td class="tdl_ws1"><i>ounces</i></td>
- <td class="tdl_ws1">1 <i>pound</i></td>
- <td class="tdl_ws1">1 lb.</td>
- </tr>
- </tbody>
-</table>
-
-<p>The pound troy contains 5760 grains. A cubic foot of water weighs
-75·7374 pounds troy, or 908·8488 ounces.</p>
-
-<p class="f120 space-above1">APOTHECARIES’ WEIGHT.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">20</td>
- <td class="tdl_ws1"><i>grains</i><span class="ws2">are</span></td>
- <td class="tdl_ws1">1 <i>scruple</i></td>
- <td class="tdl_ws1"><big>℈</big></td>
- </tr><tr>
- <td class="tdr">3</td>
- <td class="tdl_ws1"><i>scruples</i></td>
- <td class="tdl_ws1">1 <i>dram</i></td>
- <td class="tdl_ws1"><big>ʒ</big></td>
- </tr><tr>
- <td class="tdr">8</td>
- <td class="tdl_ws1"><i>drams</i></td>
- <td class="tdl_ws1">1 <i>ounce</i></td>
- <td class="tdl_ws1"><big>℥</big></td>
- </tr><tr>
- <td class="tdr">12</td>
- <td class="tdl_ws1"><i>ounces</i></td>
- <td class="tdl_ws1">1 <i>pound</i></td>
- <td class="tdl_ws1">lb</td>
- </tr>
- </tbody>
-</table>
-
-<p>218. The standard coins of copper, silver, and gold, are,&mdash;the penny,
-which is 10⅔ drams of copper; the shilling, which weighs 3 pennyweights
-15 grains, of which 3 parts out of 40 are alloy, and the rest pure
-silver; and the sovereign, weighing 5 pennyweights and 3¼ grains, of
-which 1 part out of 12 is copper, and the rest pure gold.
-<span class="pagenum" id="Page_131">[Pg 131]</span></p>
-
-<p class="f120 space-above1">MEASURES OF MONEY.</p>
-
-<p>The lowest coin is a farthing, which is marked thus, ¼, being one
-fourth of a penny.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">2</td>
- <td class="tdl_ws1"><i>farthings</i>&emsp;are</td>
- <td class="tdl_ws1">1 <i>halfpenny</i></td>
- <td class="tdl_ws1"> <big>½</big><i>d</i>.</td>
- </tr><tr>
- <td class="tdr">2</td>
- <td class="tdl_ws1"><i>halfpence</i></td>
- <td class="tdl_ws1">1 <i>penny</i></td>
- <td class="tdl_ws1">1<i>d</i>.</td>
- </tr><tr>
- <td class="tdr">12</td>
- <td class="tdl_ws1"><i>pence</i></td>
- <td class="tdl_ws1">1 <i>shilling</i></td>
- <td class="tdl_ws1">1<i>s</i>.</td>
- </tr><tr>
- <td class="tdr">20</td>
- <td class="tdl_ws1"><i>shillings</i></td>
- <td class="tdl_ws1">1 <i>pound</i><a id="FNanchor_42" href="#Footnote_42" class="fnanchor">[42]</a> or <i>sovereign</i></td>
- <td class="tdl_ws1">£1</td>
- </tr><tr>
- <td class="tdr">21</td>
- <td class="tdl_ws1"><i>shillings</i></td>
- <td class="tdl_ws1">1 <i>guinea</i>.<a id="FNanchor_43" href="#Footnote_43" class="fnanchor">[43]</a></td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>219. When any quantity is made up of several others, expressed in
-different units, such as £1. 14. 6, or 2cwt. 1qr. 3lbs., it is called
-a <i>compound quantity</i>. From these tables it is evident that any
-compound quantity of any substance can be measured in several different
-ways. For example, the sum of money which we call five pounds four
-shillings is also 104 shillings, or 1248 pence, or 4992 farthings.
-It is easy to reduce any quantity from one of these measurements to
-another; and the following examples will be sufficient to shew how to
-apply the same process, usually called <span class="smcap">Reduction</span>,
-to all sorts of quantities.</p>
-
-<p>I. How many farthings are there in £18. 12. 6¾?<a id="FNanchor_44" href="#Footnote_44" class="fnanchor">[44]</a></p>
-
-<p>Since there are 20 shillings in a pound, there are, in £18, 18 × 20, or
-360 shillings; therefore, £18. 12 is 360 + 12, or 372 shillings. Since
-there are 12 pence in a shilling, in 372 shillings there are 372 × 12,
-or 4464 pence; and, therefore, in £18. 12. 6 there are 4464 + 6, or
-4470 pence.
-<span class="pagenum" id="Page_132">[Pg 132]</span></p>
-
-<p>Since there are 4 farthings in a penny, in 4470 pence there are 4470 ×
-4, or 17880 farthings; and, therefore, in £18. 12. 6¾ there are 17880
-+ 3, or 17883 farthings. The whole of this process may be written as
-follows:</p>
-
-<ul class="index fontsize_110">
-<li class="isub1">£18 . 12 . 6¾</li>
-<li class="isub1 u"> 20&emsp; &emsp; </li>
-<li class="isub1">360 + 12 =  372</li>
-<li class="isub5-5 u">    12 &emsp; </li>
-<li class="isub5-5">4464 + 6 = 4470</li>
-<li class="isub10 u">      4 &emsp; </li>
-<li class="isub10">17880 + 3 = 17883</li>
-</ul>
-
-<p>II. In 17883 farthings, how many pounds, shillings, pence, and
-farthings are there?</p>
-
-<p>Since 17883, divided by 4, gives the quotient 4470, and the remainder
-3, 17883 farthings are 4470 pence and 3 farthings (218).</p>
-
-<p>Since 4470, divided by 12, gives the quotient 372, and the remainder 6,
-4470 pence is 372 shillings and 6 pence.</p>
-
-<p>Since 372, divided by 20, gives the quotient 18, and the remainder 12,
-372 shillings is 18 pounds and 12 shillings.</p>
-
-<p>Therefore, 17883 farthings is 4470¾<i>d</i>., which is 372s.
-6¾<i>d</i>., which is £18. 12. 6¾.</p>
-
-<p>The process may be written as follows:</p>
-
-<ul class="index fontsize_120">
-<li class="isub1">4)17883</li>
-<li class="isub2">&mdash;&mdash;</li>
-<li class="isub1">12)4470 ... 3</li>
-<li class="isub2-5">&mdash;&mdash;</li>
-<li class="isub1">20)372 ... 6</li>
-<li class="isub2-5">£18 . 12 . 6¾</li>
-</ul>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>A has £100. 4. 11½, and B has 64392 farthings. If A receive 1492
-farthings, and B £1. 2. 3½, which will then have the most, and by how
-much?&mdash;<i>Answer</i>, A will have £33. 12. 3 more than B.</p>
-
-<p>In the following table the quantities written opposite to each other
-are the same: each line furnishes two exercises.
-<span class="pagenum" id="Page_133">[Pg 133]</span></p>
-
-<table class="fontsize_150 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <tbody><tr>
- <td class="tdr_ws1">£15 . 18 . 9½</td>
- <td class="tdl_ws1">15302 farthings.</td>
- </tr><tr>
- <td class="tdr_ws1">115ˡᵇˢ 1ᵒᶻ 8ᵈᵚᵗ</td>
- <td class="tdl_ws1">663072 grains.</td>
- </tr><tr>
- <td class="tdr_ws1">3ˡᵇˢ 14ᵒᶻ 9ᵈʳ</td>
- <td class="tdl_ws1">1001 drams.</td>
- </tr><tr>
- <td class="tdr_ws1">3ᵐ 149 <small>yds</small> 2ᶠᵗ 9 <small>in</small></td>
- <td class="tdl_ws1">195477 inches.</td>
- </tr><tr>
- <td class="tdr_ws1">19ᵇᵘ  2ᵖᵏˢ  1 <small>gall</small> 2 qᵗˢ</td>
- <td class="tdl_ws1">1260 pints.</td>
- </tr><tr>
- <td class="tdr_ws1">16 ʰ 23ᵐ 47ˢ</td>
- <td class="tdl_ws1">59027 seconds.</td>
- </tr>
- </tbody>
-</table>
-
-<p>220. The same may be done where the number first expressed is
-fractional. For example, how many shillings and pence are there in <big>⁴/₁₅</big>
-of a pound? Now, <big>⁴/₁₅</big> of a pound is <big>⁴/₁₅</big> of 20 shillings;
-<big>⁴/₁₅</big> of 20 is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">4 × 20</td>
- <td class="tdc" rowspan="2">, or&nbsp;&nbsp;</td>
- <td class="tdc u">4 × 4</td>
- <td class="tdc" rowspan="2">&nbsp;&nbsp;(110), or&nbsp;&nbsp;</td>
- <td class="tdc u">16</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc">15</td>
- <td class="tdc">3</td>
- <td class="tdc">3</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">or (105) 5⅓ of a shilling. Again, ⅓ of a shilling is ⅓ of
-12 pence, or 4 pence. Therefore, £⁴/₁₅ = 5<i>s.</i> 4<i>d.</i></p>
-
-<p>Also, ·23 of a day is ·23 × 24 in hours, or 5ʰ·52; and ·52 of an hour
-is ·52 × 60 in minutes, or 3ᵐ·2; and ·2 of a minute is ·2 × 60 in
-seconds, or 12ˢ; whence ·23 of a day is 5ʰ 31ᵐ 12ˢ.</p>
-
-<p>Again, suppose it required to find what part of a pound 6<i>s</i>.
-8<i>d</i>. is. Since 6<i>s.</i> 8<i>d.</i> is 80 pence, and since the
-whole pound contains 20 × 12 or 240 pence, 6<i>s.</i> 8<i>d.</i> is
-made by dividing the pound into 240 parts, and taking 80 of them. It is
-therefore <big>£⁸⁰/₂₄₀</big> (107), but <big>⁸⁰/₂₄₀ = ⅓</big> (108);
-therefore, 6<i>s.</i> 8<i>d.</i> = <big>£⅓</big>.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_150 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl">⅖ of a day <span class="ws3">is</span></td>
- <td class="tdl_ws1">9ʰ 36ᵐ</td>
- </tr><tr>
- <td class="tdl">&#8199;·12841 of a day</td>
- <td class="tdl_ws1">3ʰ 4ᵐ 54ᔆ·624<a id="FNanchor_45" href="#Footnote_45" class="fnanchor"><small>[45]</small></a></td>
- </tr><tr>
- <td class="tdl">&#8199;·257 of a cwt.</td>
- <td class="tdl_ws1">28ˡᵇˢ 12ᵒᶻ 8ᵈʳ·704</td>
- </tr><tr>
- <td class="tdl">£·14936</td>
- <td class="tdl_ws1">2ˢ 11ᵈ 3ᶠ·3856</td>
- </tr>
- </tbody>
-</table>
-
-<p>221, 222. I have thought it best to refer the mode of converting
-shillings, pence, and farthings into decimals of a pound to the
-Appendix (<a href="#APPENDIX_VI">See Appendix <i>On Decimal Money</i></a>).
-I should strongly recommend the reader to make himself perfectly familiar with the modes
-<span class="pagenum" id="Page_134">[Pg 134]</span>
-given in that Appendix. To prevent the subsequent sections from being
-altered in their numbering, I have numbered this paragraph as above.</p>
-
-<p>223. The rule of addition<a id="FNanchor_46" href="#Footnote_46" class="fnanchor">[46]</a>
-of two compound quantities of the same sort will be evident from the
-following example. Suppose it required to add £192. 14. 2½ to £64. 13.
-11¾. The sum of these two is the whole of that which arises from adding
-their several parts. Now</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">¾<i>d.</i> +  ½<i>d.</i></td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">⁵/₄<i>d.</i></td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdr">£0 . 0 . 1¼</td>
- <td class="tdl_ws1">(219)</td>
- </tr><tr>
- <td class="tdr">11<i>d.</i> +  2<i>d.</i></td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">13<i>d.</i></td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdr">0 . 1 . 1</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">13<i>s.</i> + 14<i>s.</i></td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">27<i>s.</i></td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdr">1 . 7 . 0</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">£64 + £192</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdr u">256 . 0 . 0</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1" colspan="4">The sum of all of which is</td>
- <td class="tdr">£257. 8 . 2¼</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>This may be done at once, and written as follows:</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">£192.14. &nbsp;2½</li>
-<li class="isub3 u">&#8199;&#8199;64.13.11¾</li>
-<li class="isub3">£257. &nbsp;8. &nbsp;2¼</li>
-</ul>
-
-<p>Begin by adding together the farthings, and reduce the result to pence
-and farthings. Set down the last only, carry the first to the line
-of pence, and add the pence in both lines to it. Reduce the sum to
-shillings and pence; set down the last only, and carry the first to the
-line of shillings, and so on. The same method must be followed when the
-quantities are of any other sort; and if the tables be kept in memory,
-the process will be easy.</p>
-
-<p>224. <span class="smcap">Subtraction</span> is performed on the same principle
-as in (40), namely, that the difference of two quantities is not altered by
-adding the same quantity to both. Suppose it required to subtract
-£19 . 13. 10¾ from £24. 5. 7½. Write these quantities under one another thus:
-<span class="pagenum" id="Page_135">[Pg 135]</span></p>
-
-<ul class="index fontsize_120">
-<li class="isub3">£24. &#8199;5. &#8199;7½</li>
-<li class="isub3-5">19. 13. 10¾</li>
-</ul>
-
-<p>Since ¾ cannot be taken from ½ or ²/₄, add 1<i>d.</i> to both
-quantities, which will not alter their difference; or, which is the
-same thing, add 4 farthings to the first, and 1<i>d.</i> to the second.
-The pence and farthings in the two lines then stand thus: 7⁶/₄<i>d.</i>
-and 11¾<i>d.</i> Now subtract ¾ from ⁶/₄, and the difference is ¾ which
-must be written under the farthings. Again, since 11<i>d.</i> cannot be
-subtracted from 7<i>d.</i>, add 1<i>s.</i> to both quantities by adding
-12<i>d.</i> to the first, and 1<i>s.</i> to the second. The pence in
-the first line are then 19, and in the second 11, and the difference
-is 8, which write under the pence. Since the shillings in the lower
-line were increased by 1, there are now 14<i>s.</i> in the lower, and
-5<i>s.</i> in the upper one. Add 20<i>s.</i> to the upper and £1 to
-the lower line, and the subtraction of the shillings in the second
-from those in the first leaves 11<i>s.</i> Again, there are now £20 in
-the lower, and £24 in the upper line, the difference of which is £4;
-therefore the whole difference of the two sums is £4. 11. 8¾. If we
-write down the two sums with all the additions which have been made,
-the process will stand thus:</p>
-
-<ul class="index fontsize_120">
-<li class="isub5-5">£24 . 25 . 19⁶/₄</li>
-<li class="isub6 u">20 . 14 . 11¾</li>
-<li class="isub1">Difference &nbsp;£4 .&#8199;11 .&#8199;&#8199;8¾</li>
-</ul>
-
-<p>225. The same method may be applied to any of the quantities in the
-tables. The following is another example:</p>
-
-<p>From&nbsp; &nbsp; 7 cwt. 2 qrs. 21 lbs. 14 oz.
-Subtract 2 cwt. 3 qrs. 27 lbs. 12 oz.</p>
-
-<p>After alterations have been made similar to those in the last article,
-the question becomes:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">From</td>
- <td class="tdl_ws1">7 cwt. 6 qrs. 49 lbs. 14 oz.</td>
- </tr><tr>
- <td class="tdr">Subtract</td>
- <td class="tdl_ws1 u">3 cwt. 4 qrs. 27 lbs. 12 oz.</td>
- </tr><tr>
- <td class="tdr">The difference is</td>
- <td class="tdl_ws1">4 cwt. 2 qrs. 22 lbs. &#8199;2 oz.</td>
- </tr>
- </tbody>
-</table>
-
-<p>In this example, and almost every other, the process may be a little
-<span class="pagenum" id="Page_136">[Pg 136]</span>
-shortened in the following way. Here we do not subtract 27 lbs. from 21
-lbs., which is impossible, but we increase 21 lbs. by 1 qr. or 28 lbs.
-and then subtract 27 lbs. from the sum. It would be shorter, and lead
-to the same result, first to subtract 27 lbs. from 1 qr. or 28 lbs. and
-add the difference to 21 lbs.</p>
-
-<p class="f120 space-above1">226. EXERCISES.</p>
-
-<p>A man has the following sums to receive: £193. 14. 11¼, £22. 0. 6¾,
-£6473. 0. 0, and £49. 14. 4½; and the following debts to pay: £200
-. 19. 6¼, £305. 16. 11, £22, and £19. 6. 0½. How much will remain
-after paying the debts?</p>
-
-<p class="author"><i>Answer</i>, £6190. 7. 4¾.</p>
-
-<p>There are four towns, in the order A, B, C, and D. If a man can go from
-A to B in 5ʰ 20ᵐ 33ˢ, from B to C in 6ʰ 49ᵐ 2ˢ and from A to D in 19ʰ
-0ᵐ 17ˢ, how long will he be in going from B to D, and from C to D?</p>
-
-<p class="author"><i>Answer</i>, 13ʰ 39ᵐ 44ˢ, and 6ʰ 50ᵐ 42ˢ.</p>
-
-<p>227. In order to perform the process of <span class="smcap">Multiplication</span>, it
-must be recollected that, as in (52), if a quantity be divided into
-several parts, and each of these parts be multiplied by a number, and
-the products be added, the result is the same as would arise from
-multiplying the whole quantity by that number.</p>
-
-<p>It is required to multiply £7. 13. 6¼ by 13. The first quantity is
-made up of 7 pounds, 13 shillings, 6 pence, and 1 farthing. And</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">1 farth. × 13 is &nbsp;</td>
- <td class="tdr_ws1">13 farth.  or</td>
- <td class="tdl_ws1">£0 .  0 . 3¼</td>
- <td class="tdl_ws1">(219)</td>
- </tr><tr>
- <td class="tdr">6 pence  × 13 is &nbsp;</td>
- <td class="tdr_ws1">78 pence,  or</td>
- <td class="tdl_ws1">&#8199;0 .  6 . 6</td>
- <td class="tdl_ws1" rowspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr">13 shill. × 13 is &nbsp;</td>
- <td class="tdr_ws1">169 shill.  or</td>
- <td class="tdl_ws1">&#8199;8 .  9 . 0</td>
- </tr><tr>
- <td class="tdr">7 pounds × 13 is &nbsp;</td>
- <td class="tdr_ws1">91 pounds, or</td>
- <td class="tdl_ws1">91 .  0 . 0</td>
- </tr><tr>
- <td class="tdr" colspan="2">The sum of all these is</td>
- <td class="tdl over">&#8199;£99 . 15 . 9¼</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which is therefore £7. 13. 6¼ × 13.</p>
-
-<p>This process is usually written as follows:</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">£&#8199;7 . 13 . 6¼</li>
-<li class="isub7">13</li>
-<li class="isub3 over">£99 . 15 . 9¼</li>
-</ul>
-
-<p><span class="pagenum" id="Page_137">[Pg 137]</span>
-228. <span class="smcap">Division</span> is performed upon the same principle as in (74),
-viz. that if a quantity be divided into any number of parts, and each
-part be divided by any number, the different quotients added together
-will make up the quotient of the whole quantity divided by that number.
-Suppose it required to divide £99. 15. 9¼ by 13. Since 99 divided
-by 13 gives the quotient 7, and the remainder 8, the quantity is made
-up of £13 × 7, or £91, and £8. 15. 9¼. The quotient of the first,
-13 being the divisor, is £7: it remains to find that of the second.
-Since £8 is 160<i>s.</i>, £8. 15. 9¼ is 175<i>s.</i> 9¼<i>d.</i>,
-and 175 divided by 13 gives the quotient 13, and the remainder 6; that
-is, 175<i>s.</i> 9¼<i>d.</i> is made up of 169<i>s.</i> and 6<i>s.</i>
-9¼<i>d.</i>, the quotient of the first of which is 13<i>s.</i>, and it
-remains to find that of the second. Since 6<i>s.</i> is 72<i>d.</i>,
-6<i>s.</i> 9¼<i>d.</i> is 81¼<i>d.</i>, and 81 divided by 13 gives the
-quotient 6 and remainder 3; that is, 81¼<i>d.</i> is 78<i>d.</i> and
-3¼<i>d.</i>, of the first of which the quotient is 6<i>d.</i> Again,
-since 3<i>d.</i> is ¹²/₄, or 12 farthings, 3¼<i>d.</i> is 13 farthings,
-the quotient of which is 1 farthing, or ¼, without remainder. We have
-then divided £99. 15. 9¼ into four parts, each of which is divisible
-by 13, viz. £91, 169<i>s.</i>, 78<i>d.</i>, and 13 farthings; so that
-the thirteenth part of this quantity is £7. 13. 6¼. The whole process
-may be written down as follows; and the same sort of process may be
-applied to the exercises which follow:</p>
-
-<ul class="index fontsize_120">
-<li class="isub3"><b>£    <i>s.</i>    <i>d.</i>  £    <i>s.</i>     <i>d.</i></b></li>
-<li class="isub1-5">13)99 15   9¼(7  13    6¼</li>
-<li class="isub3 u">91</li>
-<li class="isub3">&#8199;8</li>
-<li class="isub3 u">&nbsp;&nbsp;20</li>
-<li class="isub3">160 + 15 = 175</li>
-<li class="isub8 u">&nbsp;13</li>
-<li class="isub8-5">45</li>
-<li class="isub8-5 u">39</li>
-<li class="isub9">6</li>
-<li class="isub8-5 u">12</li>
-<li class="isub8-5">72 + 9 = 81</li>
-<li class="isub12 u">78</li>
-<li class="isub12-5">3</li>
-<li class="isub12 u">&nbsp; 4</li>
-
-<li class="isub12">12 + 1 = 13</li>
-<li class="isub15-5 u">13</li>
-
-<li class="isub16">0</li>
-</ul>
-
-<p><span class="pagenum" id="Page_138">[Pg 138]</span>
-Here, each of the numbers 99, 175, 81, and 13, is divided by 13 in the
-usual way, though the divisor is only written before the first of them.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">2 cwt. 1 qr. 21 lbs. 7 oz. × 53</td>
- <td class="tdc">&nbsp;&nbsp;=&nbsp;&nbsp;</td>
- <td class="tdl">129 cwt. 1 qr. 16 lbs. 3 oz.</td>
- </tr><tr>
- <td class="tdr">2ᵈ 4ʰ 3ᵐ 27ˢ × 109</td>
- <td class="tdc">=</td>
- <td class="tdl">236ᵈ 10ʰ 16ᵐ 3ˢ</td>
- </tr><tr>
- <td class="tdr">£27 . 10 . 8 × 569</td>
- <td class="tdc">=</td>
- <td class="tdl">£15666 . 9 . 4</td>
- </tr><tr>
- <td class="tdr">£7 . 4 . 8 × 123</td>
- <td class="tdc">=</td>
- <td class="tdl">£889 . 14</td>
- </tr><tr>
- <td class="tdr">£166 ×&nbsp; ₈/₃₃</td>
- <td class="tdc">=</td>
- <td class="tdl">£40 . 4 . 10⁶/₃₃</td>
- </tr><tr>
- <td class="tdr">£187 . 6 . 7 × ³/₁₀₀</td>
- <td class="tdc">=</td>
- <td class="tdl">£5 . 12 . 4¾ ²/₂₅</td>
- </tr><tr>
- <td class="tdr">4<i>s.</i> 6½<i>d.</i> × 1121</td>
- <td class="tdc">=</td>
- <td class="tdl">£254 . 11 . 2½</td>
- </tr><tr>
- <td class="tdr">4<i>s.</i> 4<i>d.</i> × 4260</td>
- <td class="tdc">=</td>
- <td class="tdl">6<i>s.</i> 6<i>d.</i> × 2840</td>
- </tr>
- </tbody>
-</table>
-
-<p>229. Suppose it required to find how many times 1s. 4¼<i>d.</i> is
-contained in £3. 19. 10¾. The way to do this is to find the number
-of farthings in each. By 219, in the first there are 65, and in the
-second 3835 farthings. Now, 3835 contains 65 59 times; and therefore
-the second quantity is 59 times as great as the first. In the case,
-however, of pounds, shillings, and pence, it would be best to use
-decimals of a pound, which will give a sufficiently exact answer.
-Thus 1s. 4¼<i>d.</i> is £·067, and £3. 19. 10¾ is £3·994, and 3·994
-divided by ·067 is 3994 by 67, or 59⁴¹/₆₇. This is an extreme case, for
-the smaller the divisor, the greater the effect of an error in a given
-place of decimals.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>How many times does 6 cwt. 2 qrs. contain 1 qr. 14 lbs. 1 oz.? and 1ᵈ
-2ʰ 0ᵐ 47ˢ contain 3ᵐ 46ˢ?</p>
-
-<p class="author"><i>Answer</i>, 17·30758 and 414·367257.</p>
-
-<p>If 2 cwt. 3 qrs. 1 lb. cost £150. 13. 10, how much does 1 lb. cost?</p>
-
-<p class="author"><i>Answer</i>, 9<i>s.</i> 9<i>d.</i> ¹³/₃₀₉.</p>
-
-<p>A grocer mixes 2 cwt. 15 lbs. of sugar at 11<i>d.</i> per pound with 14
-cwt. 3 lbs. at 5<i>d.</i> per pound. At how much per pound must he sell
-the mixture so as not to lose by mixing them?</p>
-
-<p class="author"><i>Answer</i>, 5<i>d.</i> ¾ ¹⁵³/₉₀₅.</p>
-
-<p>230. There is a convenient method of multiplication called
-<span class="smcap">Practice</span>. Suppose I ask, How much do 153 tons cost
-if each ton cost £2. 15. 7½? It is plain that if this sum be multiplied by 153,
-<span class="pagenum" id="Page_139">[Pg 139]</span>
-the product is the price of the whole. But this is also evident,
-that, if I buy 153 tons at £2. 15. 7½ each ton, payment may be
-made by first putting down £2 for each ton, then 10s. for each, then
-5<i>s.</i>, then 6<i>d.</i>, and then 1½<i>d.</i> These sums together
-make up £2. 15. 7½, and the reason for this separation of £2. 15
-. 7½ into different parts will be soon apparent. The process may be
-carried on as follows:</p>
-
-<div class="blockquot">
-<p class="neg-indent">1. 153 tons, at £2 each ton, will cost</p>
-<p class="author">£306  0 0</p>
-
-<p class="neg-indent">2. Since 10s. is £½, 153 tons, at 10<i>s.</i>
-each, will cost £15³/₂, which is</p>
-<p class="author">76 10 0</p>
-
-<p class="neg-indent">3. Since 5<i>s.</i> is ½ of 10<i>s.</i>, 153 tons,
-at 5<i>s.</i>, will cost half as much as the same number at 10<i>s.</i>
-each, that is, ½ of £76 . 10, which is</p>
-<p class="author">38  5 0</p>
-
-<p class="neg-indent">4. Since 6<i>d.</i> is ⅒ of 5<i>s.</i>, 153 tons,
-at 6<i>d.</i> each, will cost ⅒ of what the same number costs at 5<i>s.</i>
-each, that is, ⅒ of £38 . 5, which is</p>
-<p class="author">3 16 6</p>
-
-<p class="neg-indent">5. Since 1½ or 3 halfpence is ¼ of 6<i>d.</i>
-or 12 halfpence, 153 tons, at 1½<i>d.</i> each, will cost ¼ of what
-the same number costs at 6<i>d.</i> each, that is, ¼ of £3 . 16 . 6, which is</p>
-
-<p class="author u">&nbsp;&emsp;0 19 1½</p>
-
-<p class="author">The sum of all these quantities is<span class="ws6">&nbsp;</span>425 10 7½</p>
-</div>
-
-<p class="no-indent">which is, therefore, £2 . 15 . 7½ × 153.</p>
-
-<p>The whole process may be written down as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">or what<br />153 tons<br />would<br />cost at</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1 br">&nbsp;</td>
- <td class="tdr_ws1 u">£153  0  0</td>
- <td class="tdc" rowspan="8">&nbsp;</td>
- <td class="tdr u">£1 per ton.</td>
- </tr><tr>
- <td class="tdr_ws1 br">£2 is 2 × £1</td>
- <td class="tdr_ws1">306  0  0</td>
- <td class="tdr">2  0  0&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1 br">10<i>s.</i> is ½ of £1</td>
- <td class="tdr_ws1">76 10  0</td>
- <td class="tdr">0 10&nbsp;  0</td>
- </tr><tr>
- <td class="tdr_ws1 br">10<i>s.</i> is ½ of £1</td>
- <td class="tdr_ws1">76 10  0</td>
- <td class="tdr">0 10&nbsp;  0</td>
- </tr><tr>
- <td class="tdr_ws1 br">5<i>s.</i> is ½ of 10<i>s.</i></td>
- <td class="tdr_ws1">38  5  0</td>
- <td class="tdr">0  5  0&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1 br">6<i>d.</i> is ⅒ of 5<i>s.</i></td>
- <td class="tdr_ws1">3 16  6</td>
- <td class="tdr">0  0  6&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1 br">1½<i>d.</i> is ¼ of 6<i>d.</i></td>
- <td class="tdr">0 19  1½</td>
- <td class="tdr">0  0  1½</td>
- </tr><tr>
- <td class="tdc br">Sum</td>
- <td class="tdr over">£425 10  7½</td>
- <td class="tdr over">0  0  1½</td>
- </tr>
- </tbody>
-</table>
-<p><span class="pagenum" id="Page_140">[Pg 140]</span></p>
-
-<p class="f120 space-above1">ANOTHER EXAMPLE.</p>
-
-<p>What do 1735 lbs. cost at 9<i>s.</i> 10¾<i>d.</i> per lb.? The
-price 9<i>s.</i> 10¾<i>d</i>. is made up of 5<i>s.</i>, 4<i>s.</i>,
-10<i>d.</i>, ½<i>d.</i>, and ¼<i>d.</i>; of which 5<i>s.</i> is ¼ of
-£1, 4<i>s.</i> is ⅕ of £1, 10<i>d.</i> is ⅙ of 5<i>s.</i>, ½<i>d.</i>
-is ¹/₂₀ of 10<i>d.</i>, and ¼<i>d.</i> is ½ of ½<i>d.</i> Follow the
-same method as in the last example, which gives the following:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdc">or what<br />1735 tons<br />would<br />cost at</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1 br">&nbsp;</td>
- <td class="tdr_ws1 u">£1735  0  0</td>
- <td class="tdc" rowspan="8">&nbsp;</td>
- <td class="tdr u">£1 per ton.</td>
- </tr><tr>
- <td class="tdr_ws1 br">5<i>s.</i> is ¼ of £1</td>
- <td class="tdr_ws1">433 15  0</td>
- <td class="tdr">0  5  0&#8199;&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1 br">4<i>s.</i> is ⅕ of £1</td>
- <td class="tdr_ws1">347 0  0</td>
- <td class="tdr">0  4  0&#8199;&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1 br">10<i>d.</i> is ⅙ of 5<i>s.</i></td>
- <td class="tdr_ws1">72  5 10</td>
- <td class="tdr">0  0  10&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1 br">½<i>d.</i> is ¹/₂₀ of 10<i>d.</i></td>
- <td class="tdr_ws1">3 12  3½</td>
- <td class="tdr">0  0  0½</td>
- </tr><tr>
- <td class="tdr_ws1 br">¼<i>d.</i> is ½ of ½<i>d.</i></td>
- <td class="tdr_ws1">1 16  1¾</td>
- <td class="tdr">0  0  0¼</td>
- </tr><tr>
- <td class="tdc br">by addition ...</td>
- <td class="tdr over">£858 9 3¼</td>
- <td class="tdr over">£0  9 10¾</td>
- </tr>
- </tbody>
-</table>
-
-
-<p>In all cases, the price must first be divided into a number of parts,
-each of which is a simple fraction<a id="FNanchor_47" href="#Footnote_47" class="fnanchor">[47]</a>
-of some one which goes before. No rule can be given for doing this,
-but practice will enable the student immediately to find out the best
-method for each case. When that is done, he must find how much the
-whole quantity would cost if each of these parts were the price, and
-then add the results together.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>What is the cost of</p>
-
-<p>243 cwt. at £14 . 18 . 8¼ per cwt.?&mdash;<i>Answer</i>, £3629 . 1 . 0¾.</p>
-
-<p>169 bushels at £2 . 1 . 3¼ per bushel?&mdash;<i>Answer</i>, £348 . 14 . 9¼.</p>
-
-<p>273 qrs. at 19<i>s.</i> 2<i>d.</i> per quarter?&mdash;<i>Answer</i>, £261 . 12. 6.</p>
-
-<p>2627 sacks at 7<i>s.</i> 8½<i>d.</i> per sack?&mdash;<i>Answer</i>, £1012 . 9 . 9½.</p>
-
-<p class="space-above2"><span class="pagenum" id="Page_141">[Pg 141]</span>
-231. Throughout this section it must be observed, that the rules can be
-applied to cases where the quantities given are expressed in common or
-decimal fractions, instead of the measures in the tables. The following
-are examples:</p>
-
-<p>What is the price of 272·3479 cwt. at £2. 1. 3½ per cwt.?</p>
-
-<p class="author"><i>Answer</i>, £562·2849, or<br />
-£562. 5. 8¼. 66½lbs. at 1<i>s.</i> 4½<i>d.</i> per lb. cost £4. 11. 5¼.</p>
-
-<p>How many pounds, shillings, and pence, will 279·301 acres let for if
-each acre lets for £3·1076?&mdash;<i>Answer</i>, £867·9558, or £867. 19. 1¼.</p>
-
-<p>What does ¼ of ³/₁₃ of 17 bush. cost at ⅙ of ⅔ of £17. 14 per bushel?</p>
-
-<p class="author"><i>Answer</i>, £2·3146, or £2. 6. 3½.</p>
-
-<p>What is the cost of 19lbs. 8oz. 12dwt. 8gr. at £4. 4. 6 per
-ounce?&mdash;<i>Answer</i>, £999. 14. 1¼ ⅙.</p>
-
-<p>232. It is often required to find to how much a certain sum per day
-will amount in a year. This may be shortly done, since it happens that
-the number of days in a year is 240 + 120 + 5; so that a penny per day
-is a pound, half a pound, and 5 pence per year. Hence the following
-rule: To find how much any sum per day amounts to in a year, turn it
-into pence and fractions of a penny; to this add the half of itself,
-and let the pence be pounds, and each farthing five shillings; then
-add five times the daily sum, and the total is the yearly amount.
-For example, what does 12<i>s.</i> 3¾<i>d.</i> amount to in a year?
-This is 147¾<i>d.</i>, and its half is 73⅞<i>d.</i>, which added to
-147¾<i>d.</i> gives 221⅝<i>d.</i>, which turned into pounds is £221.
-12. 6. Also, 12<i>s.</i> 3¾<i>d.</i> × 5 is £3. 1. 6¾, which added
-to the former sum gives £224. 14. 0¾ for the yearly amount. In the
-same way the yearly amount of 2<i>s.</i> 3½<i>d.</i> is £41. 16. 5½;
-that of 6¾<i>d.</i> is £10. 5. 3¾; and that of 11<i>d.</i> is £16. 14. 7.</p>
-
-<p>233. An inverse rule may be formed, sufficiently correct for every
-purpose, in the following way: If the year consisted of 360 days, or
-³/₂ of 240, the subtraction of one-third from any sum per year would
-give the proportion which belongs to 240 days; and every pound so
-obtained would be one penny per day. But as the year is not 360, but
-365 days, if we divide each day’s share into 365 parts, and take 5
-away, the whole of the subtracted sum, or 360 × 5 such parts, will give
-<span class="pagenum" id="Page_142">[Pg 142]</span>
-360 parts for each of the 5 days which we neglected at first. But 360
-such parts are left behind for each of the 360 first days; therefore,
-this additional process divides the whole annual amount equally among
-the 365 days. Now, 5 parts out of 365 is one out of 73, or the 73d
-part of the first result must be subtracted from it to produce the
-true result. Unless the daily sum be very large, the 72d part will
-do equally well, which, as 72 farthings are 18 pence, is equivalent
-to subtracting at the rate of one farthing for 18<i>d.</i>, or
-½<i>d.</i> for 3<i>s.</i>, or 10<i>d.</i> for £3. The rule, then, is
-as follows: To find how much per day will produce a given sum per
-year, turn the shillings, &amp;c. in the given sum into decimals of a
-pound (221); subtract one-third; consider the result as pence; and
-diminish it by one farthing for every eighteen pence, or ten pence
-for every £3. For example, how much per day will give £224. 14. 0¾
-per year? This is 224·703, and its third is 74·901, which subtracted
-from 224·703, gives 149·802, which, if they be pence, amounts to
-12<i>s.</i> 5·802<i>d.</i>, in which 1<i>s.</i> 6<i>d.</i> is contained
-8 times. Subtract 8 farthings, or 2<i>d.</i>, and we have 12<i>s.</i>
-3·802<i>d.</i>, which differs from the truth only about ¹/₂₀ of a
-farthing. In the same way, £100 per year is 5<i>s.</i> 5¾<i>d.</i> per day.</p>
-
-<p>234. The following connexion between the measures of length and the
-measures of surface is the foundation of the application of arithmetic
-to geometry.</p>
-
-<div class="figcenter">
- <img src="images/i_142.jpg" alt="" width="600" height="437" />
-</div>
-
-<p>Suppose an oblong figure, <span class="smcap">a, b, c, d</span>, as here drawn (which is
-called a <i>rectangle</i> in geometry), with the side <span class="smcap">a b</span> 6
-inches, and the side <span class="smcap">a c</span> 4 inches. Divide <span class="smcap">a b</span>
-and <span class="smcap">c d</span> (which are equal) each into 6 inches by the points <i>a,
-b, c, l, m</i>, &amp;c.; and <span class="smcap">a c</span> and <span class="smcap">b d</span>
-(which are also equal) into 4 inches by the points <i>f, g, h, x, y</i>, and
-<span class="pagenum" id="Page_143">[Pg 143]</span>
-<i>z</i>. Join <i>a</i> and l, <i>b</i> and <i>m</i>, &amp;c., and
-<i>f</i> and <i>x</i>, &amp;c. Then, the figure <span class="smcap">a b c d</span> is
-divided into a number of squares; for a square is a rectangle whose
-sides are equal, and therefore <span class="allsmcap">a</span> <i>a f</i>
-<span class="allsmcap">e</span> is square, since <span
-class="allsmcap">a</span> <i>a</i> is of the same length as
-<span class="allsmcap">a</span> <i>f</i>, both being 1 inch. There are
-also four rows of these squares, with six squares in each row; that
-is, there are 6 × 4, or 24 squares altogether. Each of these squares
-has its sides 1 inch in length, and is what was called in (215)
-<i>a square inch</i>. By the same reasoning, if one side had contained
-6 <i>yards</i>, and the other 4 <i>yards</i>, the surface would have
-contained 6 × 4 <i>square yards</i>; and so on.</p>
-
-<div class="figleft">
- <img src="images/i_143.jpg" alt="" width="300" height="554" />
-</div>
-
-<p>235. Let us now suppose that the sides of <span class="smcap">a b c d</span>, instead of
-being a whole number of inches, contain some inches and a fraction.
-For example, let <span class="smcap">a b</span> be 3½ inches, or (114) ⁷/₂ of an inch,
-and let <span class="smcap">a c</span> contain 2½ inches, or ⁹/₄ of an inch. Draw <span class="smcap">a e</span>
-twice as long as <span class="smcap">a b</span>, and <span class="smcap">a f</span> four times as
-long as <span class="smcap">a c</span>, and complete the rectangle <span class="smcap">a e f g</span>.
-The rest of the figure needs no description. Then, since <span class="smcap">a e</span>
-is twice <span class="smcap">a b</span>, or twice ⁷/₂ inches, it is 7 inches. And since
-<span class="smcap">a f</span> is four times <span class="smcap">a c</span>, or four times ⁹/₄ inches,
-it is 9 inches. Therefore, the whole rectangle <span class="smcap">a e f g</span> contains,
-by (234), 7 × 9 or 63 square inches. But the rectangle <span class="smcap">a e f g</span>
-contains 8 rectangles, all of the same figure as <span class="smcap">a b c d</span>; and
-therefore <span class="smcap">a b c d</span> is one-eighth part of <span class="smcap">a e f g</span>,
-and contains ⁶³/₈ square inches. But ⁶³/₈ is made by multiplying ⁹/₄ and
-⁷/₂ together (118). From this and the last article it appears, that,
-whether the sides of a rectangle be a whole or a fractional number of
-inches, the number of square inches in its surface is the product of
-the numbers of inches in its sides. The square itself is a rectangle
-whose sides are all equal, and therefore the number of square inches
-which a square contains is found by multiplying the number of inches in
-its side by itself. For example, a square whose side is 13 inches in
-length contains 13 × 13 or 169 square inches.</p>
-
-<p class="f120 space-above1">236. EXERCISES.</p>
-
-<p>What is the content, in square feet and inches, of a room whose sides
-are 42 ft. 5 inch. and 31 ft. 9 inch.? and supposing the piece from
-<span class="pagenum" id="Page_144">[Pg 144]</span>
-which its carpet is taken to be three quarters of a yard in breadth,
-what length of it must be cut off?&mdash;<i>Answer</i>, The content is 1346
-square feet 105 square inches, and the length of carpet required is 598
-feet 6⁵/₉ inches.</p>
-
-<p>The sides of a rectangular field are 253 yards and a quarter of a mile;
-how many acres does it contain?&mdash;<i>Answer</i>, 23.</p>
-
-<p>What is the difference between 18 <i>square miles</i>, and a square of
-18 miles long, or 18 <i>miles square</i>?&mdash;<i>Answer</i>, 306 square miles.</p>
-
-<p>237. It is by this rule that the measure in (215) is deduced from
-that in (214); for it is evident that twelve inches being a foot, the
-square foot is 12 × 12 or 144 square inches, and so on. In a similar
-way it may be shewn that the content in cubic inches of a cube, or
-parallelepiped,<a id="FNanchor_48" href="#Footnote_48" class="fnanchor">[48]</a>
-may be found by multiplying together the number of inches in those
-three sides which meet in a point. Thus, a cube of 6 inches contains 6
-× 6 × 6, or 216 cubic inches; a chest whose sides are 6, 8, and 5 feet,
-contains 6 × 8 × 5, or 240 cubic feet. By this rule the measure in
-(216) was deduced from that in (214).</p>
-
-<h3 id="SECTION_2_II">SECTION II.<br /><span class="h_subtitle">RULE OF THREE</span>.</h3>
-
-<p>238. Suppose it required to find what 156 yards will cost, if 22
-yards cost 17<i>s.</i> 4<i>d.</i> This quantity, reduced to pence,
-is 208<i>d.</i>; and if 22 yards cost 208<i>d.</i>, each yard costs
-²⁰⁸/₂₂<i>d</i>. But 156 yards cost 156 times the price of one yard, and
-therefore cost</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">208</td>
- <td class="tdc" rowspan="2">&nbsp;× 156 pence, or &nbsp;</td>
- <td class="tdc u">208 × 156</td>
- <td class="tdc" rowspan="2">&nbsp;pence (117).</td>
- </tr><tr>
- <td class="tdc">22</td>
- <td class="tdc">22</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Again, if 25½ French francs be 20 shillings sterling, how many
-francs are in £20. 15? Since 25½ francs are 20 shillings, twice the number of
-francs must be twice the number of shillings; that is, 51 francs are 40
-<span class="pagenum" id="Page_145">[Pg 145]</span>
-shillings, and one shilling is the fortieth part of 51 francs, or ⁵¹/₄₀
-francs. But £20 15<i>s.</i> contain 415 shillings (219); and since 1
-shilling is ⁵¹/₄₀ francs, 415 shillings is</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">⁵¹/₄₀ × 415 francs, or (117) &nbsp;</td>
- <td class="tdc u">51 × 415</td>
- <td class="tdc" rowspan="2">&nbsp;francs.</td>
- </tr><tr>
- <td class="tdc">40</td>
- </tr>
- </tbody>
-</table>
-
-<p>239. Such questions as the last two belong to the most extensive rule
-in Commercial Arithmetic, which is called the <span class="smcap">Rule of Three</span>,
-because in it three quantities are given, and a fourth is required to
-be found. From both the preceding examples the following rule may be
-deduced, which the same reasoning will shew to apply to all similar cases.</p>
-
-<p>It must be observed, that in these questions there are two quantities
-which are of the same sort, and a third of another sort, of which last
-the answer must be. Thus, in the first question there are 22 and 156
-yards and 208 pence, and the thing required to be found is a number
-of pence. In the second question there are 20 and 415 shillings and
-25½ francs, and what is to be found is a number of francs. Write the
-three quantities in a line, putting that one last which is the only
-one of its kind, and that one first which is connected with the last
-in the question.<a id="FNanchor_49" href="#Footnote_49" class="fnanchor">[49]</a>
-Put the third quantity in the middle. In the first question the
-quantities will be placed thus:</p>
-
-<p class="f120">22 yds.&nbsp; 156 yds.&nbsp; 17<i>s.</i> 4<i>d.</i></p>
-
-<p class="no-indent">In the second question they will be placed thus:</p>
-
-<p class="f120">20<i>s.</i>&nbsp; £20 15<i>s.</i>&nbsp; 25½ francs.</p>
-
-<p>Reduce the first and second quantities, if necessary, to quantities of
-the same denomination. Thus, in the second question, £20 15<i>s.</i>
-must be reduced to shillings (219). The third quantity may also be
-reduced to any other denomination, if convenient; or the first and
-third may be multiplied by any quantity we please, as was done in the
-<span class="pagenum" id="Page_146">[Pg 146]</span>
-second question; and, on looking at the answer in (238), and at (108),
-it will be seen that no change is made by that multiplication. Multiply
-the second and third quantities together, and divide by the first. The
-result is a quantity of the same sort as the third in the line, and is
-the answer required. Thus, to the first question the answer is (238)</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">208 × 156</td>
- <td class="tdc" rowspan="2">&nbsp;pence, or, which is the same thing, &nbsp;</td>
- <td class="tdc u">17<i>s.</i> 4<i>d</i>. × 156</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc">22</td>
- <td class="tdc">22</td>
- </tr>
- </tbody>
-</table>
-
-<p>240. The whole process in the first question is as follows:<a id="FNanchor_50" href="#Footnote_50" class="fnanchor">[50]</a></p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub1">yds.     yds.<span class="ws2">&nbsp;</span><i>s.</i>   <i>d.</i></li>
-<li class="isub1">22   :   156   ∷   17 . 4</li>
-<li class="isub7 u">&nbsp;12</li>
-<li class="isub7">208 &nbsp;pence.</li>
-<li class="isub7 u">156</li>
-<li class="isub6-5">1248</li>
-<li class="isub6">1040</li>
-<li class="isub6 u">208&nbsp;&nbsp;</li>
-<li class="isub4-5">22)32448(1474¾<i>d.</i> and ¹⁴/₂₂, or ⁷/₁₁ of a farthing,</li>
-<li class="isub6"><span class="u">22&nbsp;&nbsp;</span><span class="ws5">&nbsp;</span>or (219) £6 . 2 . 10¾-⁷/₁₁.</li>
-<li class="isub6">104</li>
-<li class="isub6 u">&nbsp;&nbsp;88</li>
-<li class="isub6">&nbsp;164</li>
-<li class="isub6 u">&nbsp;154&nbsp;&nbsp;</li>
-<li class="isub7">108</li>
-<li class="isub7 u">&nbsp;&nbsp;88</li>
-<li class="isub7">&nbsp;&nbsp;20</li>
-<li class="isub3">(228)<span class="ws2 u">&nbsp;&nbsp;&nbsp;4</span></li>
-<li class="isub7">&nbsp;&nbsp;80</li>
-<li class="isub7 u">&nbsp;&nbsp;66</li>
-<li class="isub7">&nbsp;&nbsp;14</li>
-</ul>
-
-<p>The question might have been solved without reducing
-17<i>s.</i> 4<i>d.</i> to pence, thus:
-<span class="pagenum" id="Page_147">[Pg 147]</span></p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub1">yds.     yds.<span class="ws2">&nbsp;</span><i>s.</i>   <i>d.</i></li>
-<li class="isub1">22   :   156   ∷   17 . 4</li>
-<li class="isub5"><span class="u">&emsp;&nbsp;&emsp;&emsp;156</span><span class="ws8">(227)</span></li>
-<li class="isub4">22) £135 . 4 . 0(£6 . 2 . 10¾-⁷/₁₁&emsp;&nbsp;(228)</li>
-<li class="isub6 u">132</li>
-<li class="isub7">3 × 20 + 4 = 64</li>
-<li class="isub12 u">&nbsp;44</li>
-<li class="isub12">&nbsp;20 × 12 = 240</li>
-<li class="isub16-5 u">220</li>
-<li class="isub17">20 × 4 = 80</li>
-<li class="isub20-5 u">66</li>
-<li class="isub20-5">14</li>
-</ul>
-
-<p>The student must learn by practice which is the most convenient method
-for any particular case, as no rule can be given.</p>
-
-<p>241. It may happen that the three given quantities are all of one
-denomination; nevertheless it will be found that two of them are of
-one, and the third of another sort. For example: What must an income of
-£400 pay towards an income-tax of 4<i>s.</i> 6<i>d.</i> in the pound?
-Here the three given quantities are, £400, 4<i>s.</i> 6<i>d.</i>, and
-£1, which are all of the same species, viz. money. Nevertheless, the
-first and third are income; the second is a tax, and the answer is also
-a tax; and therefore, by (152), the quantities must be placed thus:</p>
-
-<p class="f120">£1&emsp;:&emsp;£400&emsp;∷&emsp;4<i>s.</i> 6<i>d.</i></p>
-
-<p>242. The following exercises either depend directly upon this rule,
-or can be shewn to do so by a little consideration. There are many
-questions of the sort, which will require some exercise of ingenuity
-before the method of applying the rule can be found.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>If 15 cwt. 2 qrs. cost £198. 15. 4, what does 1 qr. 22 lbs. cost?</p>
-
-<p class="author"><i>Answer</i>, £5 . 14 . 5 ¾&nbsp;¹⁸⁵/₂₁₇.</p>
-
-<p>If a horse go 14 m. 3 fur. 27 yds. in 3ʰ 26ᵐ 12ˢ, how long will he be
-in going 23 miles?</p>
-
-<p class="author"><i>Answer</i>, 5ʰ 29ᵐ 34ˢ(²⁴⁶²/₂₅₃₂₇).</p>
-
-<p><span class="pagenum" id="Page_148">[Pg 148]</span>
-Two persons, A and B, are bankrupts, and owe exactly the same sum; A
-can pay 15<i>s.</i> 4½<i>d.</i> in the pound, and B only 7<i>s.</i>
-(6¾)<i>d.</i> At the same time A has in his possession £1304. 17 more
-than B; what do the debts of each amount to?</p>
-
-<p class="author"><i>Answer</i>, £3340 . 8 . 3 ¾ ⁹/₂₅.</p>
-
-<p>For every (12½) acres which one country contains, a second contains
-(56¼). The second country contains 17,300 square miles. How much does
-the first contain? Again, for every 3 people in the first, there are 5
-in the second; and there are in the first 27 people on every 20 acres.
-How many are there in each country?&mdash;<i>Answer</i>, The number of
-square miles in the first is 3844⁴/₉, and its population 3,321,600; and
-the population of the second is 5,536,000.</p>
-
-<p>If (42½) yds. of cloth, 18 in. wide, cost £59. 14. 2, how much will
-(118¼) yds. cost, if the width be 1 yd.?</p>
-
-<p class="author"><i>Answer</i>, £332. 5. (2⁴/₁₇).</p>
-
-<p>If £9. 3. 6 last six weeks, how long will £100 last?</p>
-
-<p class="author"><i>Answer</i>, (65¹⁴⁵/₃₆₇) weeks.</p>
-
-<p>How much sugar, worth (9¾d). a pound, must be given for 2 cwt. of tea,
-worth 10<i>d.</i> an ounce?</p>
-
-<p class="author"><i>Answer</i>, 32 cwt. 3 qrs. 7 lbs. ³⁵/₃₉.</p>
-
-<p>243. Suppose the following question asked: How long will it take 15 men
-to do that which 45 men can finish in 10 days? It is evident that one
-man would take 45 × 10, or 450 days, to do the same thing, and that 15
-men would do it in one-fifteenth part of the time which it employs one
-man, that is, in (450 ÷ 15) or 30 days. By this and similar reasoning
-the following questions can be solved.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>If 15 oxen eat an acre of grass in 12 days, how long will it take 26
-oxen to eat 14 acres?</p>
-<p class="author"><i>Answer</i>, (96¹²/₁₃) days.</p>
-
-<p>If 22 masons build a wall 5 feet high in 6 days, how long will it take
-43 masons to build 10 feet?</p>
-<p class="author"><i>Answer</i>, (6⁶/₄₃) days.</p>
-
-<p>244. The questions in the preceding article form part of a more general
-class of questions, whose solution is called the <span class="smcap">Double Rule
-of Three</span>, but which might, with more correctness, be called the Rule
-of <i>Five</i>, since five quantities are given, and a sixth is to be
-found. The following is an example: If 5 men can make 30 yards of cloth
-in 3 days, how long will it take 4 men to make 68 yards? The first thing
-<span class="pagenum" id="Page_149">[Pg 149]</span>
-to be done is to find out, from the first part of the question, the
-time it will take one man to make one yard. Now, since one man, in 3
-days, will do the fifth part of what 5 men can do, he will in 3 days
-make ³⁰/₅, or 6 yards. He will, therefore, make one yard in ³/₆6 or (3 × 5)/30
-of a day. From this we are to find how long it will take 4 men
-to make 68 yards. Since one man makes a yard in</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">3 × 5</td>
- <td class="tdc" rowspan="2">&nbsp;of a day, he will make 68 yards in &emsp;&nbsp;</td>
- <td class="tdc u">3 × 5</td>
- <td class="tdc" rowspan="2">&nbsp;× 68 days,</td>
- </tr><tr>
- <td class="tdc">30</td>
- <td class="tdc">30</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">or (116) in &nbsp;</td>
- <td class="tdc u">3 × 5 × 68</td>
- <td class="tdc" rowspan="2">&nbsp;days; and 4 men will do this in one-fourth;</td>
- </tr><tr>
- <td class="tdc">30</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2">of the time, that is (123), in &nbsp;</td>
- <td class="tdc u">3 × 5 × 68</td>
- <td class="tdc" rowspan="2">&nbsp;days, or in 8½ days.&emsp;&nbsp;</td>
- </tr><tr>
- <td class="tdc">30 × 4</td>
- </tr>
- </tbody>
-</table>
-
-<p>Again, suppose the question to be: If 5 men can make 30 yards in 3
-days, how much can 6 men do in 12 days? Here we must first find the
-quantity one man can do in one day, which appears, on reasoning similar
-to that in the last example, to be 30/(3 × 5) yards. Hence, 6 men, in
-one day, will make</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">6 × 30</td>
- <td class="tdc" rowspan="2">&nbsp;yards, and in 12 days will make&nbsp;</td>
- <td class="tdc u">12 × 6 × 30</td>
- <td class="tdc" rowspan="2">&nbsp;or 144 yards.</td>
- </tr><tr>
- <td class="tdc">5 × 3</td>
- <td class="tdc">5 × 3</td>
- </tr>
- </tbody>
-</table>
-
-<p>From these examples the following rule may be drawn. Write the given
-quantities in two lines, keeping quantities of the same sort under one
-another, and those which are connected with each other, in the same line.
-In the two examples above given, the quantities must be written thus:</p>
-
-<div class="figcenter">
- <img src="images/i_158a.jpg" alt="" width="600" height="228" />
-</div>
-
-<p class="center space-above2"><b>SECOND EXAMPLE.</b></p>
-
-<div class="figcenter">
- <img src="images/i_158b.jpg" alt="" width="600" height="227" />
-</div>
-
-<p>Draw a curve through the middle of each line, and the extremities
-of the other. There will be three quantities on one curve and two on
-the other. Divide the product of the three by the product of the two,
-and the quotient is the answer to the question.
-<span class="pagenum" id="Page_150">[Pg 150]</span></p>
-
-<p>If necessary, the quantities in each line must be reduced to more
-simple denominations (219), as was done in the common Rule of Three (238).</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>If 6 horses can, in 2 days, plough 17 acres, how many acres will 93
-horses plough in 4½ days?</p>
-
-<p class="author"><i>Answer</i>, 592⅞.</p>
-
-<p>If 20 men, in 3¼ days, can dig 7 rectangular fields, the sides of each
-of which are 40 and 50 yards, how long will 37 men be in digging 53
-fields, the sides of each of which are 90 and 125½ yards?</p>
-
-<table border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><i>Answer</i>, <span class="fontsize_150">75</span>&nbsp;</td>
- <td class="tdc u">2451</td>
- <td class="tdc" rowspan="2">&nbsp;days.</td>
- </tr><tr>
- <td class="tdc">20720</td>
- </tr>
- </tbody>
-</table>
-
-<p>If the carriage of 60 cwt. through 20 miles cost £14 10<i>s.</i>, what
-weight ought to be carried 30 miles for £5. 8. 9?</p>
-
-<p class="author"><i>Answer</i>, 15 cwt.</p>
-
-<p>If £100 gain £5 in a year, how much will £850 gain in 3 years and 8
-months?</p>
-
-<p class="author space-below2"><i>Answer</i>, £155. 16. 8.</p>
-
-<h3 id="SECTION_2_III">SECTION III.<br /><span class="h_subtitle">INTEREST, ETC.</span></h3>
-
-<p>245. In the questions contained in this Section, almost the only
-process which will be employed is the taking a fractional part of a
-sum of money, which has been done before in several cases. Suppose it
-required to take 7 parts out of 40 from £16, that is, to divide £16
-into 40 equal parts, and take 7 of them. Each of these parts is</p>
-
-<table border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><span class="fontsize_150">£</span></td>
- <td class="tdc u">16</td>
- <td class="tdc" rowspan="2">&nbsp;and 7 of them make&nbsp;</td>
- <td class="tdc u">16</td>
- <td class="tdc" rowspan="2">&nbsp;× 7, or &nbsp;</td>
- <td class="tdc u">16 × 7</td>
- <td class="tdc" rowspan="2">&nbsp;pounds (116).</td>
- </tr><tr>
- <td class="tdc">40</td>
- <td class="tdc">40</td>
- <td class="tdc">40</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">The process may be written as below:</p>
-
-<ul class="index fontsize_120">
-<li class="isub2-5">£16</li>
-<li class="isub2-5 u">&nbsp;&nbsp;&nbsp;7</li>
-<li class="isub1">40)112(£2 . 16<i>s.</i></li>
-<li class="isub3 u">80</li>
-<li class="isub3">32</li>
-<li class="isub3 u">&nbsp; 20</li>
-<li class="isub3">640</li>
-<li class="isub3 u">40 &nbsp;</li>
-<li class="isub3">240</li>
-<li class="isub3 u">240</li>
-<li class="isub4">0</li>
-</ul>
-
-<p><span class="pagenum" id="Page_151">[Pg 151]</span>
-Suppose it required to take 13 parts out of a hundred from £56. 13. 7½.</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub4">56 . 13 .  7½</li>
-<li class="isub4 u">&nbsp;&emsp;&nbsp;&emsp;&emsp;13</li>
-<li class="isub2">100) 736 . 17 . 1½ ( £7 . 7 . 4 ¼ ¹/₄₁</li>
-<li class="isub4 u">700</li>
-<li class="isub4-5">36 × 20 + 17 = 737</li>
-<li class="isub10-5 u">700</li>
-<li class="isub11">37 × 12 + 1 = 445</li>
-<li class="isub16-5 u">400</li>
-<li class="isub17">45 × 4 × 2 = 182</li>
-<li class="isub22-5 u">100</li>
-<li class="isub23">82</li>
-</ul>
-
-<p>Let it be required to take 2½ parts out of a hundred from £3
-12<i>s.</i> The result, by the same rule is</p>
-
-<table border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">£3 12<i>s.</i> × 2½</td>
- <td class="tdc" rowspan="2">&nbsp;, or 123 £3 12<i>s.</i> × &nbsp;</td>
- <td class="tdc">5</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc">100</td>
- <td class="tdc over">200</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">so that taking 2½ out of a hundred is the same as
-taking 5 parts out of 200.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Take 7⅓ parts out of 53 from £1 10<i>s.</i></p>
-
-<table border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><i>Answer</i>, <big>4</big><i>s.</i> <big>1</big>&nbsp;</td>
- <td class="tdc">129</td>
- <td class="tdc" rowspan="2">&nbsp;<i>d</i>.</td>
- </tr><tr>
- <td class="tdc over">159</td>
- </tr>
- </tbody>
-</table>
-
-<p>Take 5 parts out of 100 from £107 13<i>s.</i> 4¾<i>d.</i></p>
-
-<p class="author"><i>Answer</i>, £5. 7. 8 and ³/₂₀ of a farthing.</p>
-
-<p>£56 3<i>s.</i> 2<i>d.</i> is equally divided among 32 persons. How much
-does the share of 23 of them exceed that of the rest?</p>
-
-<p class="author"><i>Answer</i>, £24. 11. 4½ ½.</p>
-
-<p>246. It is usual, in mercantile business, to mention the fraction which
-one sum is of another, by saying how many parts out of a hundred must
-be taken from the second in order to make the first. Thus, instead of
-saying that £16 12<i>s.</i> is the half of £33 4<i>s.</i>, it is said
-that the first is 50 per cent of the second. Thus, £5 is 2½ per cent of
-£200; because, if £200 be divided into 100 parts, 2½ of those parts are
-£5. Also, £13 is 150 per cent of £8. 13. 4, since the first is the
-second and half the second. Suppose it asked, How much per cent is 23
-<span class="pagenum" id="Page_152">[Pg 152]</span>
-parts out of 56 of any sum? The question amounts to this: If he who has
-£56 gets £100 for them, how much will he who has 23 receive? This, by
-238, is 23 × ¹⁰⁰/₅₆ or ²³⁰⁰/₅₆ or 41¹/₁₄. Hence, 23 out of 56 is 41¹/₁₄
-per cent.</p>
-
-<p>Similarly 16 parts out of 18 is 16 × ¹⁰⁰/₁₈, or 88⁸/₉ per cent, and 2
-parts out of 5 is 2 × ¹⁰⁰/₅, or 40 per cent.</p>
-
-<p>From which the method of reducing other fractions to the rate per cent
-is evident.</p>
-
-<p>Suppose it asked, How much per cent is £6. 12. 2 of £12. 3? Since
-the first contains 1586<i>d.</i>, and the second 2916<i>d.</i>, the
-first is 1586 out of 2916 parts of the second; that is, by the last
-rule, it is ¹⁵⁸⁶⁰⁰/₂₉₁₆, or 54¹¹³⁶/₂₉₁₆, or £54. 7. 9½ per cent,
-very nearly. The more expeditious way of doing this is to reduce the
-shillings, &amp;c. to decimals of a pound. Three decimal places will
-give the rate per cent to the nearest shilling, which is near enough
-for all practical purposes. For instance, in the last example, which
-is to find how much £6·608 is of £12·15, 6·608 × 100 is 660·8, which
-divided by 12·15 gives £54·38, or £54. 7. Greater correctness may be
-had, if necessary, as in the <a href="#APPENDIX_VI">Appendix</a>.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>How much per cent is 198¼ out of 233 parts?&mdash;<i>Ans.</i> £85. 1. 8¾.</p>
-
-<p>Goods which are bought for £193. 12, are sold for £216. 13. 4; how
-much per cent has been gained by them?</p>
-
-<p class="author"><i>Answer</i>, A little less than £11. 18. 6.</p>
-
-<p>A sells goods for B to the amount of £230. 12, and is allowed a
-commission<a id="FNanchor_51" href="#Footnote_51" class="fnanchor">[51]</a>
-of 3 per cent; what does that amount to?</p>
-
-<p class="author"><i>Answer</i>, £6 . 18. 4¼ ⁷/₂₅.</p>
-
-<p>A stockbroker buys £1700 stock, brokerage being at £⅛ per cent; what
-does he receive?&mdash;<i>Answer</i>, £2. 2. 6.
-<span class="pagenum" id="Page_153">[Pg 153]</span></p>
-
-<p>A ship whose value is £15,423 is insured at 19⅔ per cent; what does the
-insurance amount to?&mdash;<i>Answer</i>, £3033. 3. 9½ ²/₅.</p>
-
-<p>247. In reckoning how much a bankrupt is able to pay his creditors, as
-also to how much a tax or rate amounts, it is usual to find how many
-shillings in the pound is paid. Thus, if a person who owes £100 can
-only pay £50, he is said to pay 10<i>s.</i> in the pound. The rule is
-easily derived from the same reasoning as in 246. For example, £50 out
-of £82 is</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><big>£</big>&nbsp;</td>
- <td class="tdc u">50</td>
- <td class="tdc" rowspan="2">&nbsp;out of £1, or &nbsp;</td>
- <td class="tdc u">50 × 20</td>
- <td class="tdc" rowspan="2">&nbsp;shillings,</td>
- </tr><tr>
- <td class="tdc">82</td>
- <td class="tdc">82</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">or 12<i>s.</i> 2½ ¹⁵/₄₁ in the pound.</p>
-
-<p>248. <span class="smcap">Interest</span> is money paid for the use of other money,
-and is always a per-centage upon the sum lent. It may be paid either yearly,
-half-yearly, or quarterly; but when it is said that £100 is lent at 4
-per cent, it must be understood to mean 4 per cent per annum; that is,
-that 4 pounds are paid every year for the use of £100.</p>
-
-<p>The sum lent is called the <i>principal</i>, and the interest upon it is of
-two kinds. If the borrower pay the interest as soon as, from the agreement,
-it becomes due, it is evident that he has to pay the same sum
-every year; and that the whole of the interest which he has to pay in
-any number of years is one year’s interest multiplied by the number of
-years. But if he do not pay the interest at once, but keeps it in his
-hands until he returns the principal, he will then have more of his
-creditor’s money in his hands every year, and if it were so agreed
-will have to pay interest upon each year’s interest for the time during
-which he keeps it after it becomes due. In the first case, the interest
-is called <i>simple</i>, and in the second <i>compound</i>. The interest
-and principal together are called the <i>amount</i>.</p>
-
-<p>249. What is the simple interest of £1049. 16. 6 for 6 years and
-one-third, at 4½ per cent? This interest must be 6⅓ times the interest
-<span class="pagenum" id="Page_154">[Pg 154]</span>
-of the same sum for one year, which (245) is found by multiplying the
-sum by 4½, and dividing by 100. The process is as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">(230)</td>
- <td class="tdr_ws1 br">(<i>a</i>)</td>
- <td class="tdr u">&nbsp;£1049 .</td>
- <td class="tdr u">16 .</td>
- <td class="tdr u">&nbsp;6</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1 br"><i>a</i> × 4</td>
- <td class="tdr">4199 .</td>
- <td class="tdr">6 .</td>
- <td class="tdr">&nbsp;0</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1 br"><i>a</i> × ½</td>
- <td class="tdr bb">524 .</td>
- <td class="tdr bb">18 .</td>
- <td class="tdr bb">&nbsp;3</td>
- </tr>
- </tbody>
-</table>
-<p class="f120 no-wrap">(82)<span class="ws3">&nbsp;</span> 100) 47,24 .  4 . 3(£47 . 4 . 10¹¹/₁₀₀</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr u">&nbsp;&nbsp;20</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">(228)&emsp;&nbsp;</td>
- <td class="tdr">4,84</td>
- <td class="tdl"><a id="FNanchor_52" href="#Footnote_52" class="fnanchor">[52]</a></td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr u">&nbsp;&nbsp;&nbsp;&nbsp;12</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr">10,11</td>
- <td class="tdl"><a id="FNanchor_53" href="#Footnote_53" class="fnanchor">[53]</a></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap space-above2" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">(<i>b</i>)</td>
- <td class="tdr u">&nbsp;£47 .</td>
- <td class="tdr u">&nbsp;4 .</td>
- <td class="tdr u">&nbsp;10¹¹/₁₀₀</td>
- <td class="tdl_ws1">Int. for one yr.</td>
- </tr><tr>
- <td class="tdr_ws1 br"><i>b</i> × 6</td>
- <td class="tdr">283 .</td>
- <td class="tdr">9 .</td>
- <td class="tdr">0⁶⁶/₁₀₀</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1 br"><i>b</i> × ⅓</td>
- <td class="tdr bb">15 .</td>
- <td class="tdr bb">&nbsp;14 .</td>
- <td class="tdr bb">&nbsp;11³⁷/₁₀₀</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">£299 .</td>
- <td class="tdr">&nbsp;4 .</td>
- <td class="tdr">&nbsp;0³/₁₀₀</td>
- <td class="tdl_ws1">Int. for 6⅓ yrs.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>What is the interest of £105. 6. 2 for 19 years and 7 weeks at 3 per cent?</p>
-
-<p class="author"><i>Answer</i>, £60. 9, very nearly.</p>
-
-<p>What is the difference between the interest of £50. 19 for 7 years at
-3 per cent, and for 8 years at 2½ per cent?</p>
-
-<p class="author"><i>Answer</i>, 10<i>s.</i> (2½)<i>d.</i></p>
-
-<p>What is the interest of £157. 17. 6 for one year at 5 per cent?</p>
-
-<p class="author"><i>Answer</i>, £7. 17. 10½.</p>
-
-<p>Shew that the interest of any sum for 9 years at 4 per cent is the same
-as that of the same sum for 4 years at 9 per cent.</p>
-
-<p>250. In order to find the interest of any sum at compound interest, it
-is necessary to find the amount of the principal and interest at the
-end of every year; because in this case (248) it is the amount of both
-<span class="pagenum" id="Page_155">[Pg 155]</span>
-principal and interest at the end of the first year, upon which interest
-accumulates during the second year. Suppose, for example, it is required
-to find the interest, for 3 years, on £100, at 5 per cent, compound
-interest. The following is the process:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr"><big>£</big>100</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">First principal.</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">&nbsp;&nbsp;&nbsp;&nbsp;5</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">First year’s interest.</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">105</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">Amount at the end of the first year.</td>
- </tr><tr>
- <td class="tdc">&nbsp;(249)&emsp;&nbsp;</td>
- <td class="tdr u" colspan="2">&emsp;&nbsp;5&nbsp;&nbsp;.  5</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">Interest for the second year on <big>£</big>105.</td>
- </tr><tr>
- <td class="tdc" rowspan="5">&nbsp;</td>
- <td class="tdr">110</td>
- <td class="tdr">.  5</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdl_ws1">Amount at the end of two years.</td>
- </tr><tr>
- <td class="tdr u" colspan="3">&nbsp;&nbsp;&nbsp;&nbsp;5&nbsp;&nbsp;. 10&nbsp;. 3</td>
- <td class="tdl_ws1">Interest due for the third year.</td>
- </tr><tr>
- <td class="tdr">115</td>
- <td class="tdr">&nbsp;. 15</td>
- <td class="tdr">&nbsp;. 3</td>
- <td class="tdl_ws1">Amount at the end of three years.</td>
- </tr><tr>
- <td class="tdr u" colspan="3">100&nbsp;.  0&nbsp;.  0</td>
- <td class="tdl_ws1">First principal.</td>
- </tr><tr>
- <td class="tdr">15</td>
- <td class="tdr">&nbsp;. 15</td>
- <td class="tdr">&nbsp;. 3</td>
- <td class="tdl_ws1">Interest gained in the three years.</td>
- </tr>
- </tbody>
-</table>
-
-<p>When the number of years is great, and the sum considerable, this
-process is very troublesome; on which account tables<a id="FNanchor_54" href="#Footnote_54" class="fnanchor">[54]</a>
-are constructed to shew the amount of one pound, for different numbers
-of years, at different rates of interest. To make use of these tables
-in the present example, look into the column headed “5 per cent;” and
-opposite to the number 3, in the column headed “Number of years,” is
-found 1·157625; meaning that £1 will become £1·157625 in 3 years. Now,
-£100 must become 100 times as great; and 1·157625 × 100 is 115·7625
-(141); but (221) £·7625 is 15<i>s.</i> 3<i>d.</i>; therefore the whole
-amount of £100 is £115. 15. 3, as before.</p>
-
-<p>251. Suppose that a sum of money has lain at simple interest 4 years,
-at 5 per cent, and has, with its interest, amounted to £350; it is
-required to find what the sum was at first. Whatever the sum was, if we
-suppose it divided into 100 parts, 5 of those parts were added every
-year for 4 years, as interest; that is, 20 of those parts have been
-added to the first sum to make £350. If, therefore, £350 be divided
-into 120 parts, 100 of those parts are the principal which we want to
-<span class="pagenum" id="Page_156">[Pg 156]</span>
-find, and 20 parts are interest upon it; that is, the principal is
-£(350 × 100)/150, or £291. 13. 4.</p>
-
-<p>252. Suppose that A was engaged to pay B £350 at the end of four years
-from this time, and that it is agreed between them that the debt shall
-be paid immediately; suppose, also, that money can be employed at 5 per
-cent, simple interest; it is plain that A ought not to pay the whole
-sum, £350, because, if he did, he would lose 4 years’ interest of the
-money, and B would gain it. It is fair, therefore, that he should only
-pay to B as much as will, <i>with interest</i>, amount in four years
-to £350, that is (251), £291. 13. 4. Therefore, £58. 6. 8 must
-be struck off the debt in consideration of its being paid before the
-time. This is called <span class="smcap">Discount</span>;<a id="FNanchor_55" href="#Footnote_55" class="fnanchor">[55]</a>
-and £291. 13. 4 is called the <i>present value</i> of £350 due four
-years hence, discount being at 5 per cent. The rule for finding the
-present value of a sum of money (251) is: Multiply the sum by 100, and
-divide the product by 100 increased by the product of the rate per
-cent and number of years. If the time that the debt has yet to run
-be expressed in years and months, or months only, the months must be
-reduced to the equivalent fraction of a year.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>What is the discount on a bill of £138. 14. 4, due 2 years hence,
-discount being at 4½ per cent?</p>
-
-<p class="author"><i>Answer</i>, £11. 9. 1.</p>
-
-<p>What is the present value of £1031. 17, due 6 months hence, interest
-being at 3 per cent?</p>
-
-<p class="author"><i>Answer</i>, £1016. 12.</p>
-
-<p>253. If we multiply by <i>a</i> + <i>b</i>, or by <i>a</i>-<i>b</i>,
-when we should multiply by <i>a</i>, the result is wrong by the fraction</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;+ <i>b</i>, or &nbsp;</td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc over"><i>a</i> - <i>b</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">of itself: being too great in the first case, and too small
-in the second. Again, if we divide by <i>a</i> + <i>b</i>, where we should
-have divided by <i>a</i>, the result is too small by the fraction
-<i>b</i>/<i>a</i> of itself; while, if we divide by <i>a</i>-<i>b</i>
-instead of <i>a</i>, the result is too great by the same fraction of
-itself. Thus, if we divide by 20 instead of 17, the result is ³/₁₇ of
-<span class="pagenum" id="Page_157">[Pg 157]</span>
-itself too small; and if we divide by 360 instead of 365, the result is
-too great by ⁵/₃₆₅, or ¹/₇₃ of itself.</p>
-
-<p>If, then, we wish to find the interest of a sum of money for a portion
-of a year, and have not the assistance of tables, it will be found
-convenient to suppose the year to contain only 360 days, in which case
-its 73d part (the 72d part will generally do) must be subtracted from
-the result, to make the alteration of 360 into 365. The number 360 has
-so large a number of divisors, that the rule of Practice (230) may
-always be readily applied. Thus, it is required to find the portion
-which belongs to 274 days, the yearly interest being £18. 9. 10, or 18·491.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">274</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr u">18·491</td>
- </tr><tr>
- <td class="tdr u">180</td>
- <td class="tdr">is ½ of 360&nbsp;&nbsp;</td>
- <td class="tdr">9·246</td>
- </tr><tr>
- <td class="tdr">94</td>
- <td class="tdr" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr u">90</td>
- <td class="tdr">is ½ of 180&nbsp;&nbsp;</td>
- <td class="tdr">4·623</td>
- </tr><tr>
- <td class="tdr">4</td>
- <td class="tdr">&nbsp;&nbsp;is ¹/₉₀ of 360</td>
- <td class="tdr u">&nbsp;&emsp;·205</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr">&nbsp;&nbsp;9)14·074</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr over">8)1·564</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr">·196</td>
- </tr><tr>
- <td class="tdr"></td>
- <td class="tdr"></td>
- <td class="tdr"></td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120">13·878 = £13 . 17 . 7 <i>Answer.</i></p>
-
-<p>But if the nearest farthing be wanted, the best way is to take 2-tenths
-of the number of days as a multiplier, and 73 as a divisor; since
-<i>m</i> ÷ 365 is 2<i>m</i> ÷ 730, or (²/₁₀)<i>m</i> ÷ 73. Thus, in
-the preceding instance, we multiply by 54·8 and divide by 73; and 54·8
-× 18·491 = 1013·3068, which divided by 73 gives 13·881, very nearly
-agreeing with the former, and giving £13. 17. 7½, which is certainly
-within a farthing of the truth.</p>
-
-<p>254. Suppose it required to divide £100 among three persons in such a
-way that their shares may be as 6, 5, and 9; that is, so that for every
-£6 which the first has, the second may have £5, and the third £9. It is
-plain that if we divide the £100 into 6 + 5 + 9, or 20 parts, the first
-must have 6 of those parts, the second 5, and the third 9. Therefore
-(245) their shares are respectively,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><big>£</big></td>
- <td class="tdc u">100 × 6</td>
- <td class="tdc" rowspan="2">&nbsp;, <big>£</big>&nbsp;</td>
- <td class="tdc u">100 × 5</td>
- <td class="tdc" rowspan="2">&nbsp;and <big>£</big>&nbsp;</td>
- <td class="tdc u">100 × 9</td>
- </tr><tr>
- <td class="tdc">20</td>
- <td class="tdc">20</td>
- <td class="tdc">20</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_158">[Pg 158]</span>
-or £30, £25, and £45.</p>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>Divide £394. 12 among four persons, so that their shares may be as 1,
-6, 7, and 18.&mdash;<i>Answer</i>, £12. 6. 7½; £73. 19. 9; £86. 6. 4½;
-£221. 19. 3.</p>
-
-<p>Divide £20 among 6 persons, so that the share of each may be as much as
-those of all who come before put together.&mdash;<i>Answer</i>, The first
-two have 12<i>s.</i> 6<i>d.</i>; the third £1. 5; the fourth £2. 10;
-the fifth £5; and the sixth £10.</p>
-
-<p>255. When two or more persons employ their money together, and gain
-or lose a certain sum, it is evidently not fair that the gain or loss
-should be equally divided among them all, unless each contributed the
-same sum. Suppose, for example, A contributes twice as much as B, and
-they gain £15, A ought to gain twice as much as B; that is, if the
-whole gain be divided into 3 parts, A ought to have two of them and B
-one, or A should gain £10 and B £5. Suppose that A, B, and C engage in
-an adventure, in which A embarks £250, B £130, and C £45. They gain
-£1000. How much of it ought each to have? Each one ought to gain as
-much for £1 as the others. Now, since there are 250 + 130 + 45, or 425
-pounds embarked, which gain £1000, for each pound there is a gain of
-£<big>¹⁰⁰⁰/₄₂₄</big>. Therefore A should gain 1000 × <big>²⁵⁰/₄₂₅</big> pounds, B should gain
-1000 × <big>¹³⁰/₄₂₅</big> pounds, and C 1000 × <big>⁴⁵/₄₂₅</big> pounds. On these principles,
-by the process in (245), the following questions may be answered.</p>
-
-<p>A ship is to be insured, in which A has ventured £1928, and B £4963.
-The expense of insurance is £474. 10. 2. How much ought each to pay
-of it?</p>
-
-<p><i>Answer</i>, A must pay £132. 15. (2½).</p>
-
-<p>A loss of £149 is to be made good by three persons, A, B, and C. Had
-there been a gain, A would have gained 4 times as much as B, and C as
-much as A and B together. How much of the loss must each bear?</p>
-
-<p><i>Answer</i>, A pays £59. 12, B £14. 18, and C £74. 10.</p>
-
-<p>256. It may happen that several individuals employ several sums of
-money together for different times. In such a case, unless there be a
-special agreement to the contrary, it is right that the more time a sum
-<span class="pagenum" id="Page_159">[Pg 159]</span>
-is employed, the more profit should be made upon it. If, for example,
-A and B employ the same sum for the same purpose, but A’s money is
-employed twice as long as B’s, A ought to gain twice as much as B. The
-principle is, that one pound employed for one month, or one year, ought
-to give the same return to each. Suppose, for example, that A employs
-£3 for 6 months, B £4 for 7 months, and C £12 for 2 months, and the
-gain is £100; how much ought each to have of it? Now, since A employs
-£3 for six months, he must gain 6 times as much as if he employed it
-one month only; that is, as much as if he employed £6 × 3, or £18, for
-one month; also, B gains as much as if he had employed £4 × 7 for one
-month; and C as if he had employed £12 × 2 for one month. If, then, we
-divide £100 into 6 × 3 + 4 × 7 + 12 × 2, or 70 parts, A must have 6 ×
-3, or 18, B must have 4 × 7, or 28, and C 12 × 2, or 24 of those parts.
-The shares of the three are, therefore,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><big>£</big></td>
- <td class="tdc">6 × 3 × 100</td>
- <td class="tdc" rowspan="2">&nbsp;, <big>£</big>&nbsp;</td>
- <td class="tdc">4 × 7 × 100</td>
- <td class="tdc" rowspan="2">&nbsp;, and <big>£</big>&nbsp;</td>
- <td class="tdc">12 × 2 × 100</td>
- </tr><tr>
- <td class="tdc over">6 × 3 + 4 × 7 + 12 × </td>
- <td class="tdc over">6 × 3 + 4 × 7 + 12 × 2</td>
- <td class="tdc over">6 × 3 + 4 × 7 + 12 × 2</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 space-above1">EXERCISES.</p>
-
-<p>A, B, and C embark in an undertaking; A placing £3. 6 for 2 years, B
-£100 for 1 year, and C £12 for 1½ years. They gain £4276. 7 How much
-must each receive of the gain?</p>
-
-<p class="author"><i>Answer</i>, A £226. 10. 4; B £3432. 1. 3; C £617. 15. 5.</p>
-
-<p>A, B, and C rent a house together for 2 years, at £150 per annum. A
-remains in it the whole time, B 16 months, and C 4½ months, during the
-occupancy of B. How much must each pay of the rent?<a id="FNanchor_56" href="#Footnote_56" class="fnanchor">[56]</a></p>
-
-<p class="author"><i>Answer</i>, A should pay £190. 12. 6; B £90. 12. 6; C £18. 15.</p>
-
-<p>257. These are the principal rules employed in the application of
-arithmetic to commerce. There are others, which, as no one who
-understands the principles here laid down can fail to see, are
-virtually contained in those which have been given. Such is what
-is commonly called the Rule of Exchange, for such questions as the
-<span class="pagenum" id="Page_160">[Pg 160]</span>
-following: If 20 shillings be worth 25½ francs, in France, what is £160
-worth? This may evidently be done by the Rule of Three. The rules here
-given are those which are most useful in common life; and the student
-who understands them need not fear that any ordinary question will be
-above his reach. But no student must imagine that from this or any
-other book of arithmetic he will learn precisely the modes of operation
-which are best adapted to the wants of the particular kind of business
-in which his future life may be passed. There is no such thing as a set
-of rules which are at once most convenient for a butcher and a banker’s
-clerk, a grocer and an actuary, a farmer and a bill-broker; but a
-person with a good knowledge of the <i>principles</i> laid down in this
-work, will be able to examine and meet his own future wants, or, at
-worst, to catch with readiness the manner in which those who have gone
-before him have done so for themselves.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_161">[Pg 161]</span></p>
-
-<h2 class="nobreak">APPENDIX TO</h2>
-</div>
-
-<p class="f120"> THE FIFTH EDITION OF<br />
-<big><b>DE MORGAN’S ELEMENTS OF ARITHMETIC</b>.</big></p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_I">I. ON THE MODE OF COMPUTING.</h3>
-</div>
-
-<p>The rules in the preceding work are given in the usual form, and the
-examples are worked in the usual manner. But if the student really wish
-to become a ready computer, he should strictly follow the methods laid
-down in this Appendix; and he may depend upon it that he will thereby
-save himself trouble in the end, as well as acquire habits of quick and
-accurate calculation.</p>
-
-<p>I. In numeration learn to connect each primary decimal number, 10,
-100, 1000, &amp;c. not with the place in which the unit falls, but with
-the number of ciphers following. Call ten a <i>one-cipher</i> number,
-a hundred a <i>two-cipher</i> number, a million a <i>six-cipher</i>
-number, and so on. If <i>five</i> figures be cut off from a number,
-those that are left are hundred-thousands; for 100,000 is a
-<i>five-cipher</i> number. Learn to connect tens, hundreds, thousands,
-tens of thousands, hundreds of thousands, millions, &amp;c. with 1, 2,
-3, 4, 5, 6, &amp;c. in the mind. What is a <i>seventeen-cipher</i> number?
-For every 6 in seventeen say <i>million</i>, for the remaining 5 say
-<i>hundred-thousand</i>: the answer is a hundred thousand millions of
-millions. If twelve places be cut off from the right of a number, what
-does the remaining number stand for?&mdash;<i>Answer</i>, As many millions
-of millions as there are units in it when standing by itself.</p>
-
-<p>II. After learning to count forwards and backwards with rapidity,
-as in 1, 2, 3, 4, &amp;c. or 30, 29, 28, 27, &amp;c., learn to count
-forwards or backwards by twos, threes, &amp;c. up to nines at least,
-beginning from any number. Thus, beginning from four and proceeding by
-<span class="pagenum" id="Page_162">[Pg 162]</span>
-sevens, we have 4, 11, 18, 25, 32, &amp;c., along which series you must
-learn to go as easily as along the series 1, 2, 3, 4, &amp;c.; that
-is, as quick as you can pronounce the words. The act of addition must
-be made in the mind without assistance: you must not permit yourself
-to say, 4 and 7 are 11, 11 and 7 are 18, &amp;c.; but only 4, 11, 18,
-&amp;c. And it would be desirable, though not so necessary, that you
-should go back as readily as forward; by sevens for instance, from
-sixty, as in 60, 53, 46, 39, &amp;c.</p>
-
-<p>III. Seeing a number and another both of one figure, learn to catch
-instantly the number you must add to the smaller to get the greater.
-Seeing 3 and 8, learn by practice to think of 5 without the necessity
-of saying 3 <i>from</i> 8 <i>and there remains</i> 5. And if the second
-number be the less, as 8 and 3, learn also by practice how to pass
-<i>up</i> from 8 to the next number which ends with 3 (or 13), and to
-catch the necessary augmentation, <i>five</i>, without the necessity
-of formally undertaking in words to subtract 8 from 13. Take rows of
-numbers, such as</p>
-
-<p class="f120">4 2 6 0 5 0 1 8 6 4</p>
-
-<p class="no-indent">and practise this rule upon every figure and the next, not
-permitting yourself in this simple case ever to name the higher one. Thus, say
-4 and 8 (4 first, 2 second, 4 from the next number that ends with 2, or
-12, leaves 8), 2 and 4, 6 and 4, 0 and 5, 5 and 5, 0 and 1, 1 and 7, 8
-and 8, 6 and 8.</p>
-
-<p>IV. Study the same exercise as the last one with two figures and one.
-Thus, seeing 27 and 6, pass from 27 up to the next number that ends
-with 6 (or 36), catch the 9 through which you have to pass, and allow
-yourself to repeat as much as “27 and 9 are 36.” Thus, the row of
-figures 17729638109 will give the following practice: 17 and 0 are 17;
-77 and 5 are 82; 72 and 7 are 79; 29 and 7 are 36; 96 and 7 are 103; 63
-and 5 are 68; 38 and 3 are 41; 81 and 9 are 90; 10 and 9 are 19.</p>
-
-<p>V. In a number of two figures, practise writing down the units at the
-moment that you are keeping the attention fixed upon the tens. In the
-preceding exercise, for instance, write down the results, repeating the
-tens with emphasis at the instant of writing down the units.
-<span class="pagenum" id="Page_163">[Pg 163]</span></p>
-
-<p>VI. Learn the multiplication table so well as to name the product the
-instant the factors are seen; that is, until 8 and 7, or 7 and 8,
-suggest 56 at once, without the necessity of saying “7 times 8 are 56.”
-Thus looking along a row of numbers, as 39706548, learn to name the
-products of every successive pair of digits as fast as you can repeat
-them, namely, 27, 63, 0, 0, 30, 20, 32.</p>
-
-<p>VII. Having thoroughly mastered the last exercise, learn further, on
-seeing three numbers, to augment the product of the first and second
-by the third without any repetition of words. Practise until 3, 8, 4,
-for instance, suggest 3 times 8 and 4, or 28, without the necessity of
-saying “3 times 8 are 24, and 4 is 28.” Thus, 179236408 will suggest
-the following practice, 16, 65, 21, 12, 22, 24, 8.</p>
-
-<p>VIII. Now, carry the last still further, as follows: Seeing four
-figures, as 2, 7, 6, 9, catch up the product of the first and second,
-increased by the third, as in the last, without a helping word; name
-the result, and add the next figure, name the whole result, laying
-emphasis upon the tens. Thus, 2, 7, 6, 9, must immediately suggest “20
-and 9 are 29.” The row of figures 773698974 will give the instances 52
-and 6 are 58; 27 and 9 are 36; 27 and 8 are 35; 62 and 9 are 71; 81 and
-7 are 88; 79 and 4 are 83.</p>
-
-<p>IX. Having four numbers, as 2, 4, 7, 9, vary the last exercise as
-follows: Catch the product of the first and second, increased by the
-third; but instead of adding the fourth, go up to the next number
-that ends with the fourth, as in exercise IV. Thus, 2, 4, 7, 9, are
-to suggest “15 and 4 are 19.” And the row of figures 1723968929 will
-afford the instances 9 and 4 are 13; 17 and 2 are 19; 15 and 1 are 16;
-33 and 5 are 38; 62 and 7 are 69; 57 and 5 are 62; 74 and 5 are 79.</p>
-
-<p>X. Learn to find rapidly the number of times a digit is contained
-in given units and tens, with the remainder. Thus, seeing 8 and 53,
-arrive at and repeat “6 and 5 over.” Common short division is the best
-practice. Thus, in dividing 236410792 by 7,</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">7)236410792</li>
-<li class="isub4"><span class="over">&nbsp;&nbsp;33772970</span>,&nbsp;&nbsp;remainder 2.</li>
-</ul>
-
-<p class="no-indent">All that is repeated should be 3 and 2; 3 and 5; 7 and 5; 7 and 2; 2
-and 6; 9 and 4; 7 and 0; 0 and 2.
-<span class="pagenum" id="Page_164">[Pg 164]</span></p>
-
-<p>In performing the several rules, proceed as follows:</p>
-
-<p><span class="smcap">Addition.</span> Not one word more than repeating the numbers written
-in the following process: the accented figure is the one to be written
-down; the doubly accented figure is carried (and don’t <i>say</i>
-“carry 3,” but do it).</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdr_ws1">47963</td>
- <td class="tdl_ws2">&#8199;6, 15, 17, 23, 31, 3″ 4′;</td>
- </tr><tr>
- <td class="tdr_ws1">1598</td>
- <td class="tdl_ws2">11, 12, 21, 22, 31, 3″7′;</td>
- </tr><tr>
- <td class="tdr_ws1">26316</td>
- <td class="tdl_ws2">&#8199;9, 17, 24, 27, 32, 4″1′;</td>
- </tr><tr>
- <td class="tdr_ws1">54792</td>
- <td class="tdl_ws2">10, 14, 20, 21, 2″8′; 7, 9, 1′3′.</td>
- </tr><tr>
- <td class="tdr_ws1">819</td>
- <td class="tdl" rowspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">6686</td>
- </tr><tr>
- <td class="tdr_ws1 over">138174</td>
- </tr>
- </tbody>
-</table>
-
-<p>In verifying additions, instead of the usual way of omitting one line,
-adding without it, and then adding the line omitted, verify each column
-by adding it both upwards and downwards.</p>
-
-<p><span class="smcap">Subtraction.</span> The following process is enough. The carriages,
-being always of <i>one</i>, need not be mentioned.</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">From&emsp;79436258190</li>
-<li class="isub3">Take&emsp;&nbsp;58645962738</li>
-<li class="isub6 over">&nbsp;20790295452</li>
-</ul>
-
-<p class="no-indent blockquot">8 and 2′, 4 and 5′, 7 and 4′, 3 and 5′,
-6 and 9′, 10 and 2′, 6 and 0′, 4 and 9′, 7 and 7′, 9 and 0′, 5 and 2′.
-It is useless to stop and say, 8 and 2 make 10; for as soon as the 2 is
-obtained, there is no occasion to remember what it came from.</p>
-
-<p><span class="smcap">Multiplication.</span> The following, put into words, is all that
-need be repeated in the multiplying part; the addition is then done as
-usual. The unaccented figures are carried.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdr">670383</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">9876</td>
- </tr><tr>
- <td class="tdr over">4022298</td>
- <td class="tdl_ws2">18′, 49′, 22′, 2′, 42′, 4′0′,</td>
- </tr><tr>
- <td class="tdr">4692681&#8199;</td>
- <td class="tdl_ws2">21′, 58′, 26′, 2′, 49′, 4′6′,</td>
- </tr><tr>
- <td class="tdr">5363064&#8199;&#8199;</td>
- <td class="tdl_ws2">24′, 66′, 30′, 3′, 56′, 5′3′,</td>
- </tr><tr>
- <td class="tdr">6033447&#8199;&#8199;&#8199;</td>
- <td class="tdl_ws2">27′, 74′, 34′, 3′, 63′, 6′0′.</td>
- </tr><tr>
- <td class="tdr over">6620702508</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>Verify each line of the multiplication and the final result by casting
-out the nines. (<a href="#APPENDIX_II"><i>Appendix</i></a> II. p. 166.)</p>
-
-<p>It would be almost as easy, for a person who has well practised the 8th
-exercise, to add each line to the one before in the process, thus:
-<span class="pagenum" id="Page_165">[Pg 165]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdr">670383</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">9876</td>
- </tr><tr>
- <td class="tdr over">4022298</td>
- <td class="tdl_ws2">8; 21 and 9 are 30′; 59 and 2</td>
- </tr><tr>
- <td class="tdr">50949108</td>
- <td class="tdl_ws2">are 61′; 27 and 2 are 29; 2</td>
- </tr><tr>
- <td class="tdr">587255508</td>
- <td class="tdl_ws2">and 2 are 4′; 49 and 0 are 49′;</td>
- </tr><tr>
- <td class="tdr">6620702508</td>
- <td class="tdl_ws2">46 and 4 are 5′0′.</td>
- </tr>
- </tbody>
-</table>
-
-<p>On the right is all the process of forming the second line, which
-completes the multiplication by 76, as the third line completes that by
-876, and the fourth line that by 9876.</p>
-
-<p><span class="smcap">Division.</span> Make each multiplication and the following
-subtraction in one step, by help of the process in the 9th exercise, as
-follows:</p>
-
-<ul class="index fontsize_110">
-<li class="isub2">27693)441972809662(15959730</li>
-<li class="isub5">165042</li>
-<li class="isub5-5">265778</li>
-<li class="isub6">165410</li>
-<li class="isub6-5">269459</li>
-<li class="isub7">202226</li>
-<li class="isub7-5">83756</li>
-<li class="isub8">6772</li>
-</ul>
-
-<p>The number of words by which 26577 is obtained from 165402 (the
-multiplier being 5) is as follows: 15 and 7′ are 2″2; 47 and 7′ are
-5″4; 35 and 5′ are 4″0; 39 and 6′ are 4″5; 14 and 2′ are 16.</p>
-
-<p>The processes for extracting the square root, and for the solution of
-equations (<a href="#APPENDIX_XI"><i>Appendix</i> XI</a>.), should be abbreviated in the same
-manner as the division.<a id="FNanchor_57" href="#Footnote_57" class="fnanchor">[57]</a></p>
-
-<hr class="chap x-ebookmaker-drop" />
-<p><span class="pagenum" id="Page_166">[Pg 166]</span></p>
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_II">APPENDIX II.<br />
-<span class="h_subtitle">ON VERIFICATION BY CASTING OUT<br /> NINES AND ELEVENS.</span></h3>
-</div>
-
-<p>The process of <i>casting out the nines</i>, as it is called, is one
-which the young computer should learn and practise, as a check upon
-his computations. It is not a complete check, since if one figure were
-made too small, and another as much too great, it would not detect
-this double error; but as it is very unlikely that such a double error
-should take place, the check furnishes a strong presumption of accuracy.</p>
-
-<p>The proposition upon which this method depends is the following: If
-<i>a, b, c, d</i> be four numbers, such that</p>
-
-<p class="f120"><i>a</i> = <i>bc</i> + <i>d</i>,</p>
-
-<p class="no-indent">and if <i>m</i> be any other number whatsoever,
-and if <i>a, b, c, d</i>, severally divided by <i>m</i>, give the
-remainders <i>p, q, r, s</i>, then</p>
-
-<p class="f120"><i>p</i> and <i>qr</i> + <i>s</i></p>
-
-<p class="no-indent">give the same remainder when divided by <i>m</i>
-(and perhaps are themselves equal).</p>
-
-<p class="f120">For instance,<span class="ws2">&nbsp;</span> 334 = 17 × 19 + 11;</p>
-
-<p class="no-indent">divide these four numbers by 7, the remainders
-are 5, 3, 5, and 4. And 5 and 5 × 3 + 4, or 5 and 19, both leave the
-remainder 5 when divided by 7.</p>
-
-<p>Any number, therefore, being used as a divisor, may be made a check
-upon the correctness of an operation. To provide a check which may be
-most fit for use, we must take a divisor the remainder to which is most
-easily found. The most convenient divisors are 3, 9, and 11, of which 9
-is far the most useful.</p>
-
-<p>As to the numbers 3 and 9, the remainder is always the same as that
-of the sum of the digits. For instance, required the remainder of
-246120377 divided by 9. The sum of the digits is 2 + 4 + 6 + 1 + 2 + 0
-+ 3 + 7 + 7, or 32, which gives the remainder 5. But the easiest way
-of proceeding is by throwing out nines as fast as they arise in the
-sum. Thus, repeat 2, 6 (2 + 4), 12 (6 + 6), say 3 (throwing out 9), 4,
-6, 9 (throw this away), 7, 14, (or throwing out the 9) 5. This is the
-remainder required, as would appear by dividing 246120377 by 9. A proof
-<span class="pagenum" id="Page_167">[Pg 167]</span>
-may be given thus: It is obvious that each of the numbers, 1, 10, 100,
-1000, &amp;c. divided by 9, leaves a remainder 1, since they are 1,
-9 + 1, 99 + 1, &amp;c. Consequently, 2, 20, 200, &amp;c. leave the
-remainder 2; 3, 30, 300, the remainder 3; and so on. If, then, we
-divide, say 1764 by 9 in parcels, 1000 will be one more than an exact
-number of nines, 700 will be seven more, and 60 will be six more. So,
-then, from 1, 7, 6, 4, put together, and the nines taken out, comes the
-only remainder which can come from 1764.</p>
-
-<p>To apply this process to a multiplication: It is asserted,
-in page 32, that</p>
-
-<p class="f120">10004569 × 3163 = 31644451747.</p>
-
-<p>In casting out the nines from the first, all that is necessary to
-repeat is, one, five, ten, one, <i>seven</i>; in the second, three,
-four, ten, one, <i>four</i>; in the third, three, four, ten, one, five,
-nine, four, nine, eight, twelve, three, ten, <i>one</i>. The remainders
-then are, 7, 4, 1. Now, 7 × 4 is 28, which, casting out the nines,
-gives 1, the same as the product.</p>
-
-<p>Again, in page 43, it is asserted that</p>
-
-<p class="f120">23796484 = 130000 × 183 + 6484.</p>
-
-<p class="no-indent">Cast out the nines from 13000, 183, 6484, and we
-have 4, 3, and 4. Now, 4 × 3 + 4, with the nines cast out, gives 7; and
-so does 23796484.</p>
-
-<p>To avoid having to remember the result of one side of the equation,
-or to write it down, in order to confront it with the result of the
-other side, proceed as follows: Having got the remainder of the more
-complicated side, into which two or more numbers enter, subtract it
-from 9, and carry the remainder into the simple side, in which there is
-only one number. Then the remainder of that side ought to be 0. Thus,
-having got 7 from the left-hand of the preceding, take 2, the rest
-of 9, forget 7, and carry in 2 as a beginning to the left-hand side,
-giving 2, 4, 7, 14, 5, 11, 2, 6, 14, 5, 9, 0.</p>
-
-<p>Practice will enable the student to cast out nines with great rapidity.</p>
-
-<p>This process of casting out the nines does not detect any errors
-in which the remainder to 9 happens to be correct. If a process be
-tedious, and some additional check be desirable, the method of casting
-out <i>elevens</i> may be followed after that of casting out the nines.
-Observe that 10 + 1, 100-1, 1000 + 1, 10000-1, &amp;c. are all
-divisible by eleven. From this the following rule for the remainder of
-<span class="pagenum" id="Page_168">[Pg 168]</span>
-division by 11 may be deduced, and readily used by those who know the
-algebraical process of subtraction. For those who have not got so far,
-it may be doubted whether the rule can be made easier than the actual
-division by 11.</p>
-
-<p>Subtract the first figure from the second, the result from the third,
-the result from the fourth, and so on. The final result, or the rest
-of 11 if the figure be negative, is the remainder required. Thus, to
-divide 1642915 by 11, and find the remainder, we have 1 from 6, 5; 5
-from 4, -1; -1 from 2, 3; 3 from 9, 6; 6 from 1, -5; -5 from 5, 10;
-and 10 is the remainder. But 164 gives-1, and 10 is the remainder;
-164291 gives-5, and 6 is the remainder. With very little practice
-these remainders may be read as rapidly as the number itself. Thus, for
-127619833424 need only be repeated, 1, 6, 0, 1, 8, 0, 3, 0, 4, -2, 6,
-and 6 is the remainder.</p>
-
-<p>When a question has been tried both by nines and elevens, there can be
-no error unless it be one which makes the result wrong by a number of
-times 99 exactly.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_III">APPENDIX III.<br />
-<span class="h_subtitle">ON SCALES OF NOTATION.</span></h3>
-</div>
-
-<p>We are so well accustomed to 10, 100, &amp;c., as standing for ten, ten
-tens, &amp;c., that we are not apt to remember that there is no reason
-why 10 might not stand for five, 100 for five fives, &amp;c., or for
-twelve, twelve twelves, &amp;c. Because we invent different columns of
-numbers, and let units in the different columns stand for collections
-of the units in the preceding columns, we are not therefore bound to
-allow of no collections except in tens.</p>
-
-<p>If 10 stood for 2, that is, if every column had its unit double of the
-unit in the column on the right, what we now represent by 1, 2, 3, 4,
-5, 6, &amp;c., would be represented by 1, 10, 11, 100, 101, 110, 111,
-1000, 1001, 1010, 1011, 1100, &amp;c. This is the <i>binary</i> scale.
-<span class="pagenum" id="Page_169">[Pg 169]</span>
-If we take the <i>ternary</i> scale, in which 10 stands for 3, we
-have 1, 2, 10, 11, 12, 20, 21, 22, 100, 101, 102, 110, &amp;c.
-In the <i>quinary</i> scale, in which 10 is five, 234 stands for
-2 twenty-fives, 3 fives, and 4, or sixty-nine. If we take the
-<i>duodenary</i> scale, in which 10 is twelve, we must invent new
-symbols for ten and eleven, because 10 and 11 now stand for twelve
-and thirteen; use the letters <i>t</i> and <i>e</i>. Then 176 means 1
-twelve-twelves, 7 twelves, and 6, or two hundred and thirty-four; and
-1<i>te</i> means two hundred and seventy-five.</p>
-
-<p>The number which 10 stands for is called the <i>radix</i> of the
-<i>scale of notation</i>. To change a number from one scale into
-another, divide the number, written as in the first scale, by the
-number which is to be the radix of the new scale; repeat this division
-again and again, and the remainders are the digits required. For
-example, what, in the quinary scale, is that number which, in the
-decimal scale, is 17036?</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">5)<span class="u">17036</span></li>
-<li class="isub2-5">5)3407 &emsp;Remʳ. &emsp;1</li>
-<li class="isub3">5)<span class="u">681</span><span class="ws4">   2</span></li>
-<li class="isub3-5">5)<span class="u">136</span><span class="ws4"> 1</span></li>
-<li class="isub4">5)<span class="u">27</span><span class="ws4"> 1</span></li>
-<li class="isub4-5">5)<span class="u">5 </span><span class="ws4">2</span></li>
-<li class="isub5">5)<span class="u">1 </span><span class="ws3">  0</span></li>
-<li class="isub5-5"> 0<span class="ws4">1</span></li>
-</ul>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdr"><i>Answer</i> 1021121</td>
- <td class="tdl_ws2" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">Quinary.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">Decimal.</td>
- </tr><tr>
- <td class="tdr"><i>Verification</i>, 1000000</td>
- <td class="tdc">&nbsp;&emsp;means&nbsp;</td>
- <td class="tdr">15625</td>
- </tr><tr>
- <td class="tdr">20000</td>
- <td class="tdc" rowspan="6">&nbsp;</td>
- <td class="tdr">1250</td>
- </tr><tr>
- <td class="tdr">1000</td>
- <td class="tdr">125</td>
- </tr><tr>
- <td class="tdr">100</td>
- <td class="tdr">25</td>
- </tr><tr>
- <td class="tdr">20</td>
- <td class="tdr">10</td>
- </tr><tr>
- <td class="tdr">1</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr over">1021121</td>
- <td class="tdr over">17036</td>
- </tr>
- </tbody>
-</table>
-
-<p>The reason of this rule is easy. Our process of division is nothing
-but telling off 17036 into 3407 fives and 1 over; we then find 3407
-fives to be 681 fives of fives and 2 <i>fives</i> over. Next we form
-681 fives of fives into 136 fives of fives of fives and 1 five of fives
-over; and so on.</p>
-
-<p>It is a useful exercise to multiply and divide numbers represented in
-other scales of notation than the common or decimal one. The rules are
-in all respects the same for all systems, <i>the number carried being
-always the radix of the system</i>. Thus, in the quinary system we
-carry fives instead of tens. I now give an example of multiplication
-and division:
-<span class="pagenum" id="Page_170">[Pg 170]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdr">Quinary.</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">Decimal.</td>
- </tr><tr>
- <td class="tdr">42143</td>
- <td class="tdc">&nbsp;&emsp;means&nbsp;</td>
- <td class="tdr">2798</td>
- </tr><tr>
- <td class="tdr">1234</td>
- <td class="tdc" rowspan="6">&nbsp;</td>
- <td class="tdr">194</td>
- </tr><tr>
- <td class="tdr over">324232</td>
- <td class="tdr over">11192</td>
- </tr><tr>
- <td class="tdr">232034&#8199;</td>
- <td class="tdr">25182&#8199;</td>
- </tr><tr>
- <td class="tdr">134341&#8199;&#8199;</td>
- <td class="tdr">2798&#8199;&#8199;</td>
- </tr><tr>
- <td class="tdr">42143&#8199;&#8199;&#8199;</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr over">114332222</td>
- <td class="tdr over">542812</td>
- </tr>
- </tbody>
-</table>
-<p>&nbsp;</p>
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdc">Duodecimal.</td>
-
- <td class="tdc">Decimal.</td>
- </tr><tr>
- <td class="tdl">4<i>t</i>9)76<i>t</i>4<i>e</i>08(16687</td>
- <td class="tdl_ws1">705)22610744(32071</td>
- </tr><tr>
- <td class="tdl_ws1">&#8199;4<i>t</i>9</td>
- <td class="tdl_ws2">&#8199;&#8199;1460</td>
- </tr><tr>
- <td class="tdl_ws1 over">&#8199;2814</td>
- <td class="tdl_ws2">&#8199;&#8199;&#8199;5074</td>
- </tr><tr>
- <td class="tdl_ws1 u">&#8199;2546</td>
- <td class="tdl_ws2">&#8199;&#8199;&#8199;&#8199;1394</td>
- </tr><tr>
- <td class="tdl_ws2">28<i>te</i></td>
- <td class="tdl_ws2">&#8199;&#8199;&#8199;&#8199;&#8199;689</td>
- </tr><tr>
- <td class="tdl_ws2 u">2546</td>
- <td class="tdl_ws1" rowspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdl_ws2">&#8199;3650</td>
- </tr><tr>
- <td class="tdl_ws2 u">&#8199;3320</td>
- </tr><tr>
- <td class="tdl_ws2">&#8199;&#8199;3308</td>
- </tr><tr>
- <td class="tdl_ws2 u">&#8199;&#8199;2<i>t</i>33</td>
- </tr><tr>
- <td class="tdl_ws2">&#8199;&#8199;&#8199;495</td>
- </tr>
- </tbody>
-</table>
-
-<p>Another way of turning a number from one scale into another is as
-follows: Multiply the first digit by the <i>old</i> radix <i>in the new
-scale</i>, and add the next digit; multiply the result again by the old
-radix in the new scale, and take in the next digit, and so on to the
-end, always using the radix of the scale you want to leave, and the
-notation of the scale you want to end in.</p>
-
-<p>Thus, suppose it required to turn 16687 (duodecimal) into the decimal
-scale, and 16432 (septenary) into the quaternary scale:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdc">16687</td>
- <td class="tdc">16432</td>
- </tr><tr>
- <td class="tdr">Duodecimals into Decimals.</td>
- <td class="tdr">&nbsp;&emsp;Septenaries into Quaternaries.</td>
- </tr><tr>
- <td class="tdr_ws1">1 × 12 + 6 = 18</td>
- <td class="tdr_ws1">1 × 7 + 6 = 31</td>
- </tr><tr>
- <td class="tdr_ws1">× 12 + 6</td>
- <td class="tdr_ws1">× 7 + 4</td>
- </tr><tr>
- <td class="tdr_ws1"><span class="over">222</span><span class="ws1-5">&nbsp;</span></td>
- <td class="tdr_ws1"><span class="over">1133</span><span class="ws1-5">&nbsp;</span></td>
- </tr><tr>
- <td class="tdr_ws1">× 12 + 8</td>
- <td class="tdr_ws1">× 7 + 3</td>
- </tr><tr>
- <td class="tdr_ws1"><span class="over">2672</span><span class="ws1-5">&nbsp;</span></td>
- <td class="tdr_ws1"><span class="over">22130</span><span class="ws1-5">&nbsp;</span></td>
- </tr><tr>
- <td class="tdr_ws1">× 12 + 7</td>
- <td class="tdr_ws1">× 7 + 2</td>
- </tr><tr>
- <td class="tdr_ws1"><i>Answer</i> <span class="over">32071</span>&#8199;&#8199;</td>
- <td class="tdr_ws1"><span class="over">1021012</span>&#8199;&#8199;</td>
- </tr>
- </tbody>
-</table>
-
-<p><span class="pagenum" id="Page_171">[Pg 171]</span>
-Owing to our division of a foot into 12 equal parts, the duodecimal
-scale often becomes very convenient. Let the square foot be also
-divided into 12 parts, each part is 12 square inches, and the 12th of
-the 12th is one square inch. Suppose, now, that the two sides of an
-oblong piece of ground are 176 feet 9 inches 7-12ths of an inch, and
-65 feet 11 inches 5-12ths of an inch. Using the duodecimal scale, and
-<i>duodecimal fractions</i>, these numbers are 128·97 and 55·<i>e</i>5.
-Their product, the number of square feet required, is thus found:</p>
-
-<ul class="index fontsize_120">
-<li class="isub3">128·97</li>
-<li class="isub3-5">55·<i>e</i>5</li>
-<li class="isub3 over">617<i>ee</i></li>
-<li class="isub2-5">116095</li>
-<li class="isub2-5">617<i>ee</i></li>
-<li class="isub2">617<i>ee</i></li>
-<li class="isub2 over"> 68<i>e</i>8144<i>e</i></li>
-</ul>
-
-<p class="blockquot"><i>Answer</i>, 68<i>e</i>8·144<i>e</i> (duod.) square feet, or 11660
-square feet 16 square inches ⁴/₁₂ and ¹¹/₁₄₄ of a square inch.</p>
-
-<p>It would, however, be exact enough to allow 2-hundredths of a foot
-for every quarter of an inch, an additional hundredth for every 3
-inches,<a id="FNanchor_58" href="#Footnote_58" class="fnanchor">[58]</a>
-and 1-hundredth more if there be a 12th or 2-12ths above
-the quarter of an inch. Thus, 9⁷/₁₂ inches should be ·76 + ·03 + ·01,
-or ·80, and 11⁵/₁₂ would be ·95; and the preceding might then be found
-decimally as 176·8 × 65·95 as 11659·96 square feet, near enough for
-every practical purpose.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_IV">APPENDIX IV.<br />
-<span class="h_subtitle">ON THE DEFINITION OF FRACTIONS.</span></h3>
-</div>
-
-<p>The definition of a fraction given in the text shews that ⁷/₉, for
-instance, is the <i>ninth</i> part of <i>seven</i>, which is shewn
-to be the same thing as <i>seven-ninths</i> of a unit. But there are
-various modes of speech under which a fraction may be signified, all of
-which are more or less in use.
-<span class="pagenum" id="Page_172">[Pg 172]</span></p>
-
-<div class="blockquot">
-<p>1. In <span class="fontsize_150">⁷/₉</span> we have the 9th part of 7.</p>
-
-<p>2. 7-9ths of a unit.</p>
-
-<p>3. The fraction which 7 is of 9.</p>
-
-<p>4. The times and parts of a time (in this case part of a time only)
-which 7 contains 9.</p>
-
-<p>5. The multiplier which turns <i>nines</i> into <i>sevens</i>.</p>
-
-<p>6. The <i>ratio</i> of 7 to 9, or the <i>proportion</i> of 7 to 9.</p>
-
-<p>7. The multiplier which alters a number in the ratio of 9 to 7.</p>
-
-<p>8. The 4th proportional to 9, 1, and 7.</p>
-</div>
-
-<p>The first two views are in the text. The third is deduced thus: If
-we divide 9 into 9 equal parts, each is 1, and 7 of the parts are 7;
-consequently the fraction which 7 is of 9 is ⁷/₉. The fourth view
-follows immediately: For <i>a time</i> is only a word used to express
-one of the repetitions which take place in multiplication, and we allow
-ourselves, by an easy extension of language, to speak of a portion of
-a number as being that number taken a <i>part of a time</i>. The fifth
-view is nothing more than a change of words: A number reduced to ⁷/₉
-of its amount has every 9 converted into a 7, and any fraction of a 9
-which may remain over into the corresponding fraction of 7. This is
-completely proved when we prove the equation ⁷/₉ of <i>a</i> = 7 times
-<i>a</i>/9. The sixth, seventh, and eighth views are illustrated in the
-chapter on proportion.</p>
-
-<p>When the student comes to algebra, he will find that, in all the
-applications of that science, fractions such as <i>a</i>/<i>b</i> most
-frequently require that <i>a</i> and <i>b</i> should be themselves
-supposed to be fractions. It is, therefore, of importance that he
-should learn to accommodate his views of a fraction to this more
-complicated case.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary="" cellpadding="2" >
- <tbody><tr>
- <td class="tdl" rowspan="2">Suppose we take&nbsp;</td>
- <td class="tdc">2½</td>
- <td class="tdl" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc over">&nbsp;4³/₅&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">We shall find that we have, in this case, a better
-idea of the views from and after the third inclusive, than of the first
-and second, which are certainly the most simple ways of conceiving ⁷/₉.
-We have no notion of the (4³/₅)th part of 2½,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2">nor of <span class="fontsize_150">2</span></td>
- <td class="tdc">1</td>
- <td class="tdl" rowspan="2"><span class="fontsize_200">(</span></td>
- <td class="tdl" rowspan="2">&nbsp;<span class="fontsize_150">4</span></td>
- <td class="tdc">3</td>
- <td class="tdl" rowspan="2"><span class="fontsize_200">)</span></td>
- </tr><tr>
- <td class="tdc over">&nbsp;2&nbsp;</td>
- <td class="tdc over">&nbsp;5&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">of a unit; indeed, we coin a new species of
-adjective when we talk of the (4³/₅)th part of anything. But we can
-readily imagine that 2½ is some fraction of 4³/₅; that the first is
-<i>some</i> part of a time the second; that there must be <i>some</i>
-multiplier which turns every 4³/₅ in a number into 2½; and so on. Let
-us now see whether we can invent a distinct mode of applying the first
-and second views to such a compound fraction as the above.
-<span class="pagenum" id="Page_173">[Pg 173]</span></p>
-
-<p>We can easily imagine a fourth part of a length, and a fifth part,
-meaning the lines of which 4 and 5 make up the length in question;
-and there is also in existence a length of which four lengths and
-two-fifths of a length make up the original length in question. For
-instance, we might say that 6, 6, 2 is a division of 14 into 2⅓ equal
-parts&mdash;2 equal parts, 6, 6, and a third of a part, 2. So we might agree
-to say, that the (2⅓)th, or (2⅓)rd, or (2⅓)st (the reader may coin the
-adjective as he pleases) part of 14 is 6. If we divide the line <span class="smcap">a b</span>
-into eleven equal parts in <span class="smcap">c, d, e</span>, &amp;c., we must then
-say that <span class="smcap">a c</span> is the 11th part,</p>
-
-<div class="figcenter">
- <img src="images/i_182a.jpg" alt="" width="600" height="100" />
-</div>
-
-<p><span class="smcap">a d</span> the (5½)th, <span class="smcap">a e</span> the (3⅔)th, <span class="smcap">a f</span> the
-(2¾)th, <span class="smcap">a g</span> the (2⅕)th, <span class="smcap">a h</span> the (1⅚)th, <span class="smcap">a i</span>
-the (1⁴/₇)th, <span class="smcap">a k</span> the (1⅜)th, <span class="smcap">a l</span> the (1²/₉)th,
-<span class="smcap">a m</span> the (1⅒)th, and <span class="smcap">a b</span> itself the 1st part of
-<span class="smcap">a b</span>. The reader may refuse the language if he likes (though it is
-not so much in defiance of etymology as talking of <i>multiplying</i>
-by ½); but when <span class="smcap">a b</span> is called 1, he must either call
-<span class="smcap">a f</span> 1/(2¾), or make one definition of one class of fractions
-and another of another. Whatever abbreviations they may choose, all
-persons will agree that <i>a</i>/<i>b</i> is a direction to find such
-a fraction as, repeated <i>b</i> times, will give 1, and then to take
-that fraction <i>a</i> times.</p>
-
-<p>So, to get 2½/4⅗, the simplest way is to divide the whole unit into 46
-parts; 10 of these parts, repeated 4⅗ times, give the whole. The</p>
-
-<div class="figcenter">
- <img src="images/i_182b.jpg" alt="" width="600" height="169" />
-</div>
-
-<p>4⅗th is then ¹⁰/₄₆, and 2½ such parts is ²⁵/₄₆, or <span class="smcap">a c</span>.
-The student should try several examples of this mode of interpreting
-complex fractions.</p>
-
-<p>But what are we to say when the denominator itself is less than unity,
-as in 3¼/⅖? Are we to have a (⅖)th part of a unit? and what is it? Had
-<span class="pagenum" id="Page_174">[Pg 174]</span>
-there been a 5 in the denominator, we should have taken the part of
-which 5 will make a unit. As there is ⅖ in the denominator, we must
-take the part of which ⅖ will be a unit. That part is larger than a
-unit; it is 2½ units; 2½ is that of which ⅖ is 1. The above fraction
-then directs us to repeat 2½ units 3¼ times. By extending our word
-‘multiplication’ to the taking of a part of a time, all multiplications
-are also divisions, and all divisions multiplications, and all the
-terms connected with either are subject to be applied to the results of
-the other.</p>
-
-<p>If 2⅓ yards cost 3½ shillings, how much does one yard cost? In such a
-case as this, the student looks at a more simple question. If 5 yards
-cost 10 shillings, he sees that each yard costs ¹⁰/₅, or 2 shillings,
-and, concluding that the same process will give the true result when
-the data are fractional, he forms 3½/2⅓, reduces it by rules to ³/₂
-or 1½, and concludes that 1 yard costs 18 pence. The answer happens
-to be correct; but he is not to suppose that this rule of copying for
-fractions whatever is seen to be true of integers is one which requires
-no demonstration. In the above question we want money which, repeated
-2⅓ times, shall give 3½ shillings. If we divide the shilling into 14
-equal parts, 6 of these parts repeated 2⅓ times give the shilling. To
-get 3½ times as much by the same repetition, we must take 3½ of these 6
-parts at each step, or 21 parts. Hence, ²¹/₁₄, or 1½, is the number of
-shillings in the price.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_V">APPENDIX V.<br />
-<span class="h_subtitle">ON CHARACTERISTICS.</span></h3>
-</div>
-
-<p>When the student comes to use logarithms, he will find what follows
-very useful. In the mean while, I give it merely as furnishing a rapid
-rule for finding the place of a decimal point in the quotient before
-the division is commenced.</p>
-
-<p>When a bar is written over a number, thus, <span class="over">&nbsp;7&nbsp;</span> let the number be called
-negative, and let it be thus used: Let it be augmented by additions of
-its own species, and diminished by subtractions; thus, <span class="over">&nbsp;7&nbsp;</span>
-and <span class="over">&nbsp;2&nbsp;</span> give
-<span class="over">&nbsp;9&nbsp;</span>, and let <span class="over">&nbsp;7&nbsp;</span>
-with <span class="over">&nbsp;2&nbsp;</span> subtracted give <span class="over">&nbsp;5&nbsp;</span>.
-But let the <i>addition</i>
-<span class="pagenum" id="Page_175">[Pg 175]</span>
-of a number without the bar <i>diminish</i> the negative number, and
-the <i>subtraction increase</i> it. Thus, <span class="over">&nbsp;7&nbsp;</span>
-and 4 are <span class="over">&nbsp;3&nbsp;</span>, <span class="over">&nbsp;7&nbsp;</span> and
-12 make 5, <span class="over">&nbsp;7&nbsp;</span> with 8 subtracted is
-<span class="over">&nbsp;15&nbsp;</span>. In fact, consider 1, 2, 3,
-&amp;c., as if they were gains, and <span class="over">&nbsp;1&nbsp;</span>,
-<span class="over">&nbsp;2&nbsp;</span>, <span class="over">&nbsp;3&nbsp;</span>,
-as if they were losses:
-let the addition of a gain or the removal of a loss be equivalent
-things, and also the removal of a gain and the addition of a loss.
-Thus, when we say that <span class="over">&nbsp;4&nbsp;</span> diminished
-by <span class="over">&nbsp;11&nbsp;</span> gives 7, we say that a loss
-of 4 incurred at the moment when a loss of 11 is removed, is, on the
-whole, equivalent to a gain of 7; and saying that <span class="over">&nbsp;4&nbsp;</span>
-diminished by 2 is <span class="over">&nbsp;6&nbsp;</span>, we say that a loss of 4,
-accompanied by the removal of a gain of 2, is altogether a loss of 6.</p>
-
-<p>By the <i>characteristic</i> of a number understand as follows: When
-there are places before the decimal point, it is one less than the
-number of such places. Thus, 3·214, 1·0083, 8 (which is 8·00 ...) 9·999,
-all have 0 for their characteristics. But 17·32, 48, 93·116, all have
-1; 126·03 and 126 have 2; 11937264·666 has 7. But when there are no
-places before the decimal point, look at the first decimal place which
-is significant, and make the characteristic negative accordingly. Thus,
-·612, ·121, ·9004, in all of which significance begins in the first
-decimal place, have the characteristic <span class="over">&nbsp;1&nbsp;</span>;
-but ·018 and ·099 have <span class="over">&nbsp;2&nbsp;</span>;
-·00017 has <span class="over">&nbsp;4&nbsp;</span>;
-·000000001 has <span class="over">&nbsp;9&nbsp;</span>.</p>
-
-<p>To find the characteristic of a quotient, subtract the characteristic
-of the divisor from that of the dividend, carrying one before
-subtraction if the first significant figures of the divisor are greater
-than those of the dividend. For instance, in dividing 146·08 by ·00279.
-The characteristics are 2 and <span class="over">&nbsp;3&nbsp;</span>;
-and 2 with <span class="over">&nbsp;3&nbsp;</span> removed would be 5. But
-on looking, we see that the first significant figures of the divisor,
-27, taken by themselves, and without reference to their local value,
-mean a larger number than 14, the first two figures of the dividend.
-Consequently, to <span class="over">&nbsp;3&nbsp;</span> we carry 1 before
-subtracting, and it then becomes <span class="over">&nbsp;2&nbsp;</span>,
-which, taken from 2, gives 4. And this 4 is the characteristic of
-the quotient, so that the quotient has 5 places before the decimal
-point. Or, if <i>abcdef</i> be the first figures of the quotient, the
-decimal point must be thus placed, <i>abcde·f</i>. But if it had been
-to divide ·00279 by 146·08, no carriage would have been required; and
-<span class="pagenum" id="Page_176">[Pg 176]</span>
-<span class="over">&nbsp;3&nbsp;</span> diminished by 2 is
-<span class="over">&nbsp;5&nbsp;</span>; that is, the first significant figure
-of the quotient is in the 5th place. The quotient, then, has ·0000 before
-any significant figure. A few applications of this rule will make it
-easy to do it in the head, and thus to assign the meaning of the first
-figure of the quotient even before it is found.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_VI">APPENDIX VI.<br />
-<span class="h_subtitle">ON DECIMAL MONEY.</span></h3>
-</div>
-
-<p>Of all the simplifications of commercial arithmetic, none is comparable
-to that of expressing shillings, pence, and farthings as decimals of a
-pound. The rules are thereby put almost upon as good a footing as if
-the country possessed the advantage of a real decimal coinage.</p>
-
-<p>Any fraction of a pound sterling may be decimalised by rules which can
-be made to give the result at once.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">Two shillings is</td>
- <td class="tdr br">£·100</td>
- <td class="tdl" rowspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">One shilling is</td>
- <td class="tdr br">£·050</td>
- </tr><tr>
- <td class="tdr_ws1">Sixpence is</td>
- <td class="tdr br">£·025</td>
- </tr><tr>
- <td class="tdr_ws1">One farthing is</td>
- <td class="tdr br">£·001</td>
- <td class="tdl">04⅙</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Thus, every pair of shillings is a unit in the
-first decimal place; an odd shilling is a 50 in the second and third
-places; a farthing is so nearly the thousandth part of a pound, that
-to say one farthing is ·001, two farthings is ·002, &amp;c., is so
-near the truth that it makes no error in the first three decimals till
-we arrive at sixpence, and then 24 farthings is exactly ·025 or 25
-thousandths. But 25 farthings is ·026, 26 farthings is ·027, &amp;c.
-Hence the rule for the <i>first three places</i> is</p>
-
-<p><i>One in the first for every pair of shillings; 50 in the second
-and third for the odd shilling, if any; and 1 for every farthing
-additional, with 1 extra for sixpence.</i>
-<span class="pagenum" id="Page_177">[Pg 177]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">Thus,</td>
- <td class="tdr_ws1">0<i>s.</i></td>
- <td class="tdr">3½<i>d.</i> = £·014</td>
- </tr><tr>
- <td class="tdr_ws1" rowspan="7">&nbsp;</td>
- <td class="tdr_ws1">0<i>s.</i></td>
- <td class="tdr">7¾<i>d.</i> = £·032</td>
- </tr><tr>
- <td class="tdr_ws1">1<i>s.</i></td>
- <td class="tdr">2½<i>d.</i> = £·060</td>
- </tr><tr>
- <td class="tdr_ws1">1<i>s.</i></td>
- <td class="tdr">11¼<i>d.</i> = £·096</td>
- </tr><tr>
- <td class="tdr_ws1">2<i>s.</i></td>
- <td class="tdr">6<i>d.</i> = £·125</td>
- </tr><tr>
- <td class="tdr_ws1">2<i>s.</i></td>
- <td class="tdr">9½<i>d.</i> = £·139</td>
- </tr><tr>
- <td class="tdr_ws1">3<i>s.</i></td>
- <td class="tdr">2¾<i>d.</i> = £·161</td>
- </tr><tr>
- <td class="tdr_ws1">13<i>s.</i></td>
- <td class="tdr">10¾<i>d.</i> = £·694</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">In the fourth and fifth places, and those which
-follow, it is obvious that we have no produce from any farthings except
-those above sixpence. For at every sixpence, ·00004⅙ is converted into
-·001, and this has been already accounted for. Consequently, to fill up
-the <i>fourth and fifth</i> places,</p>
-
-<p><i>Take 4 for every farthing</i><a id="FNanchor_59" href="#Footnote_59" class="fnanchor">[59]</a>
-<i>above the last sixpence, and an additional 1 for every six farthings, or three halfpence.</i></p>
-
-<p>The remaining places arise altogether from ·00000⅙ for every farthing
-above the last three halfpence; for at every three halfpence complete,
-·00000⅙ is converted into ·00001, and has been already accounted for.
-Consequently, to fill up <i>all the places after the fifth</i>,</p>
-
-<p><i>Let the number of farthings above the last three halfpence be a
-numerator, 6 a denominator, and annex the figures of the corresponding
-decimal fraction.</i></p>
-
-<p>It may be easily remembered that
-<span class="pagenum" id="Page_178">[Pg 178]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">The figures of</td>
- <td class="tdl_ws1"><span class="fontsize_150">¹/₆</span></td>
- <td class="tdc">&nbsp;&nbsp;are&nbsp;&nbsp;</td>
- <td class="tdr">166666...</td>
- </tr><tr>
- <td class="tdc">”</td>
- <td class="tdl_ws1"><span class="fontsize_150">²/₆</span></td>
- <td class="tdc">...</td>
- <td class="tdr">333333...</td>
- </tr><tr>
- <td class="tdc">”</td>
- <td class="tdl_ws1"><span class="fontsize_150">³/₆</span></td>
- <td class="tdc">...</td>
- <td class="tdl">5</td>
- </tr><tr>
- <td class="tdc">”</td>
- <td class="tdl_ws1"><span class="fontsize_150">⁴/₆</span></td>
- <td class="tdc">...</td>
- <td class="tdr">666666...</td>
- </tr><tr>
- <td class="tdc">”</td>
- <td class="tdl_ws1"><span class="fontsize_150">⁵/₆</span></td>
- <td class="tdc">...</td>
- <td class="tdr">833333...</td>
- </tr>
- </tbody>
-</table>
-<p>&nbsp;</p>
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdr">0<i>s.</i></td>
- <td class="tdr">3½<i>d.</i> =</td>
- <td class="tdl br2">·014</td>
- <td class="tdc br2">58</td>
- <td class="tdl">3333...</td>
- </tr><tr>
- <td class="tdr">0<i>s.</i></td>
- <td class="tdr">7¾<i>d.</i> =</td>
- <td class="tdl br2">·032</td>
- <td class="tdc br2">29</td>
- <td class="tdl">1666...</td>
- </tr><tr>
- <td class="tdr">1<i>s.</i></td>
- <td class="tdr">2½<i>d.</i> =</td>
- <td class="tdl br2">·060</td>
- <td class="tdc br2">41</td>
- <td class="tdl">6666...</td>
- </tr><tr>
- <td class="tdr">1<i>s.</i></td>
- <td class="tdr">11¼<i>d.</i> =</td>
- <td class="tdl br2">·096</td>
- <td class="tdc br2">87</td>
- <td class="tdl">83333...</td>
- </tr><tr>
- <td class="tdr">2<i>s.</i></td>
- <td class="tdr">6<i>d.</i>  =</td>
- <td class="tdl br2">·125</td>
- <td class="tdc br2">00</td>
- <td class="tdl">0000...</td>
- </tr><tr>
- <td class="tdr">2<i>s.</i></td>
- <td class="tdr">9½<i>d.</i> =</td>
- <td class="tdl br2">·139</td>
- <td class="tdc br2">58</td>
- <td class="tdl">3333...</td>
- </tr><tr>
- <td class="tdr">3<i>s.</i></td>
- <td class="tdr">2¾<i>d.</i> =</td>
- <td class="tdl br2">·161</td>
- <td class="tdc br2">45</td>
- <td class="tdl">83333...</td>
- </tr><tr>
- <td class="tdr">13<i>s.</i></td>
- <td class="tdr">10¾<i>d.</i> =</td>
- <td class="tdl br2">694</td>
- <td class="tdc br2">79</td>
- <td class="tdl">1666...</td>
- </tr>
- </tbody>
-</table>
-
-<p>The following examples will shew the use of this rule, if the student
-will also work them in the common way.</p>
-
-<p>To turn pounds, &amp;c., into farthings: Multiply the pounds by 960,
-or by 1000-40, or by 1000(1-<big>⁴/₁₀₀</big>); that is, from 1000 times the
-pounds subtract 4 per cent of itself. Thus, required the number of
-farthings in £1663. 11. 9¾.</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">1663·590625 × 1000</td>
- <td class="tdc">&nbsp;=&nbsp;</td>
- <td class="tdr">1663590·625</td>
- </tr><tr>
- <td class="tdr">4 per cent of this,&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr u">&nbsp;&emsp;66543·625</td>
- </tr><tr>
- <td class="tdr">No. of farthings required,</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">1597047</td>
- </tr>
- </tbody>
-</table>
-
-<p>What is 47½ per cent of £166. 13. 10 and ·6148 of £2971. 16. 9?</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr u">166·691&#8199;</td>
- </tr><tr>
- <td class="tdr_ws1">40 p. c.</td>
- <td class="tdr">66·6764</td>
- </tr><tr>
- <td class="tdr">5 p. c.</td>
- <td class="tdr_ws1">8·3346</td>
- </tr><tr>
- <td class="tdr">2½ p. c.</td>
- <td class="tdr_ws1">4·1673</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr over">79·1783</td>
- </tr><tr>
- <td class="tdr greyish"><big>£79.3.6¾</big></td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr u">2971·837</td>
- </tr><tr>
- <td class="tdl">·6</td>
- <td class="tdr">1783·1022</td>
- </tr><tr>
- <td class="tdl">·01</td>
- <td class="tdr">29·7184</td>
- </tr><tr>
- <td class="tdl">·004</td>
- <td class="tdr">11·8873</td>
- </tr><tr>
- <td class="tdl">·0008</td>
- <td class="tdr">2·3775</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdr over">1827·0854</td>
- </tr><tr>
- <td class="tdl greyish"><big>£1827.1.8½</big></td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>The inverse rule for turning the decimal of a pound into shillings,
-pence, and farthings, is obviously as follows:</p>
-
-<p><i>A pair of shillings for every unit in the first place; an odd
-shilling for 50 (if there be 50) in the second and third places; and a
-farthing for every thousandth left, after abating 1 if the number of
-thousandths so left exceed 24.</i></p>
-
-<p>The direct rule (with three places) gives too little, the inverse rule
-too much, except at the end of a sixpence, when both are accurate.
-Thus, £·183 is rather less than 3<i>s.</i> 8<i>d.</i>, and 6<i>s.</i>
-4¾<i>d.</i> is rather greater than £319; or when the two do not exactly
-agree, the <i>common money is the greatest</i>. But £·125 and £·35 are
-exactly 2<i>s.</i> 6<i>d.</i> and 7<i>s.</i>
-<span class="pagenum" id="Page_179">[Pg 179]</span></p>
-
-<p>Required the price of 17 cwt. 81 lb. 13½ oz. at £3.11.9¾ per cwt.
-true to the hundredth of a farthing.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="3" colspan="2">&nbsp;</td>
- <td class="tdr">3·590625</td>
- </tr><tr>
- <td class="tdr">17</td>
- </tr><tr>
- <td class="tdr over">61·040625</td>
- </tr><tr>
- <td class="tdr">lb.</td>
- <td class="tdr_ws1">56 ½</td>
- <td class="tdr">1·795313</td>
- </tr><tr>
- <td class="tdc" rowspan="3">&nbsp;</td>
- <td class="tdr_ws1">16 ⅐</td>
- <td class="tdr">·512946</td>
- </tr><tr>
- <td class="tdr_ws1">7 ⅛</td>
- <td class="tdr">·224414</td>
- </tr><tr>
- <td class="tdr_ws1">2 ⅛</td>
- <td class="tdr">·064118</td>
- </tr><tr>
- <td class="tdr">oz.</td>
- <td class="tdr_ws1">8 ¼</td>
- <td class="tdr">·016029</td>
- </tr><tr>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdr_ws1">4 ½</td>
- <td class="tdr">·008015</td>
- </tr><tr>
- <td class="tdr_ws1">1 ¼</td>
- <td class="tdr">·002004</td>
- </tr><tr>
- <td class="tdr_ws1">½ ½</td>
- <td class="tdr">·001002</td>
- </tr><tr>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr over">£63·664466</td>
- </tr><tr>
- <td class="tdc greyish" colspan="2"><big>£63.13.3½</big></td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>Three men, A, B, C, severally invest £191.12.7¾, £61.14.8, and
-£122.1.9½ in an adventure which yields £511.12.6½. How ought the
-proceeds to be divided among them?</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">&nbsp;&nbsp;A,&nbsp;&nbsp;</td>
- <td class="tdl">191·63229</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdc">B,</td>
- <td class="tdl">61·73333</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdc">C,</td>
- <td class="tdl u">122·08958</td>
- <td class="tdr">Produce of £1.</td>
- </tr><tr>
- <td class="tdc" rowspan="7">&nbsp;</td>
- <td class="tdl">375·45520)511·62708</td>
- <td class="tdl">(1·362686</td>
- </tr><tr>
- <td class="tdr">136·17188</td>
- <td class="tdc" rowspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdr">23·53532</td>
- </tr><tr>
- <td class="tdr">1·00801</td>
- </tr><tr>
- <td class="tdr">25710</td>
- </tr><tr>
- <td class="tdr">3183</td>
- </tr><tr>
- <td class="tdr">180</td>
- </tr>
- </tbody>
-</table>
-<p class="space-above1"><span class="pagenum" id="Page_180">[Pg 180]</span></p>
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">1·362686</td>
- <td class="tdc" rowspan="11"><span class="ws2">&nbsp;</span></td>
- <td class="tdr">1·362686</td>
- <td class="tdc" rowspan="11"><span class="ws2">&nbsp;</span></td>
- <td class="tdr">1·362686</td>
- </tr><tr>
- <td class="tdr u">92·236191</td>
- <td class="tdr u">33·33716&#8199;</td>
- <td class="tdr u">85·980221</td>
- </tr><tr>
- <td class="tdr">1·362686</td>
- <td class="tdr">8·17612&#8199;</td>
- <td class="tdr">1·362686</td>
- </tr><tr>
- <td class="tdr">1·226417</td>
- <td class="tdr">13627&#8199;</td>
- <td class="tdr">272537</td>
- </tr><tr>
- <td class="tdr">13627</td>
- <td class="tdr">9538&#8199;</td>
- <td class="tdr">27254</td>
- </tr><tr>
- <td class="tdr">8176</td>
- <td class="tdr">409&#8199;</td>
- <td class="tdr">1090</td>
- </tr><tr>
- <td class="tdr">409</td>
- <td class="tdr">41&#8199;</td>
- <td class="tdr">122</td>
- </tr><tr>
- <td class="tdr">27</td>
- <td class="tdr">4&#8199;</td>
- <td class="tdr">7</td>
- </tr><tr>
- <td class="tdr">3</td>
- <td class="tdr over">8·41231&#8199;</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdr">1</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr over">1·663697</td>
- </tr><tr>
- <td class="tdr over">2·611346</td>
- <td class="tdr">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap space-above1" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">261·1346 ...</td>
- <td class="tdc">&nbsp;&nbsp;A’s&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&nbsp;share&nbsp;&nbsp;</td>
- <td class="tdr">£261.2.8¼</td>
- </tr><tr>
- <td class="tdr">84·1231 ...</td>
- <td class="tdc">B’s</td>
- <td class="tdc">...</td>
- <td class="tdr">84.2.5¾</td>
- </tr><tr>
- <td class="tdr">166·3697 ...</td>
- <td class="tdc">C’s</td>
- <td class="tdc">...</td>
- <td class="tdr">166.7.4¾</td>
- </tr><tr>
- <td class="tdr"><span class="over">511·6274</span>&#8199;&#8199;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr over">£511.2.6¾</td>
- </tr>
- </tbody>
-</table>
-
-<p>If ever the fraction of a farthing be wanted, remember that the
-<i>coinage</i>-result is larger than the decimal of a pound, when we
-use only three places. From 1000 times the decimal take 4 per cent,
-and we get the exact number of farthings, and we need only look at the
-decimal then left to set the preceding right. Thus, in</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">134·6&#8199;</td>
- <td class="tdc" rowspan="3"><span class="ws2">&nbsp;</span></td>
- <td class="tdr">123·1&#8199;</td>
- <td class="tdc" rowspan="3"><span class="ws2">&nbsp;</span></td>
- <td class="tdr">369·7&#8199;</td>
- </tr><tr>
- <td class="tdr u">&#8199;&#8199;5·38</td>
- <td class="tdr u">&#8199;&#8199;4·92</td>
- <td class="tdr u">&#8199;14·79</td>
- </tr><tr>
- <td class="tdr">·22</td>
- <td class="tdr">·18</td>
- <td class="tdr">·91</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">we see that (if we use four decimals only) the
-pence of the above results are nearly 8<i>d.</i> ·22 of a farthing,
-5½<i>d.</i> ·18, and 4½<i>d.</i> ·91.</p>
-
-<p>A man can pay £2376. 4. 4½, his debts being £3293. 11. 0¾. How much
-per cent can he pay, and how much in the pound?</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">3293·553)2376·2180(·7214756</li>
-<li class="isub7">70·7309</li>
-<li class="isub7-5">4·8598</li>
-<li class="isub7-5">1·5662</li>
-<li class="isub8-5">2488</li>
-<li class="isub9">183</li>
-<li class="isub9-5">18</li>
-<li class="isub2">&nbsp;</li>
-<li class="isub2"><i>Answer</i>, £72. 2.11½ per cent.</li>
-<li class="isub6-5">0.14. 5¼ per pound.</li>
-</ul>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_VII">APPENDIX VII.<br />
-<span class="h_subtitle">ON THE MAIN PRINCIPLE<br />OF BOOK-KEEPING.</span></h3>
-</div>
-
-<p>A brief notice of the principle on which accounts are kept (when they
-are <i>properly</i> kept) may perhaps be useful to students who are
-learning book-keeping, as the treatises on that subject frequently give
-too little in the way of explanation.</p>
-
-<p>Any person who is engaged in business must desire to know accurately,
-whenever an investigation of the state of his affairs is made.
-<span class="pagenum" id="Page_181">[Pg 181]</span></p>
-
-<p>1, What he had at the commencement of the account, or immediately after
-the last investigation was made; 2, What he has gained and lost in the
-interval in all the several branches of his business; 3, What he is now
-worth. From the first two of these things he obviously knows the third.
-In the interval between two investigations, he may at any one time
-desire to know how any one account stands.</p>
-
-<p>An <i>account</i> is a recital of all that has happened, in reference
-to any class of dealings, since the last investigation. It can only
-consist of receipts and expenditures, and so it is said to have two
-sides, a <i>debtor</i> and a <i>creditor</i> side.</p>
-
-<p>All accounts are kept in <i>money</i>. If goods be bought, they are
-estimated by the money paid for them. If a debtor give a bill of
-exchange, being a promise to pay a certain sum at a certain time, it is
-put down as worth that sum of money. All the tools, furniture, horses,
-&amp;c. used in the business are rated at their value in money. All the
-actual coin, bank-notes, &amp;c., which are in or come in, being the
-only money in the books which really is money, is called <i>cash</i>.</p>
-
-<p>The accounts are kept as if every different sort of account belonged
-to a separate person, and had an interest of its own, which every
-transaction either promotes or injures. If the student find that it
-helps him, he may imagine a clerk to every account: one to take charge
-of, and regulate, the actual cash; another for the bills which the
-house is to receive when due; another for those which it is to pay when
-due; another for the cloth (if the concern deal in cloth); another
-for the sugar (if it deal in sugar); one for every person who has an
-account with the house; one for the profits and losses; and so on.</p>
-
-<p>All these clerks (or accounts) belonging to one merchant, must account
-to him in the end&mdash;must either produce all they have taken in charge,
-or relieve themselves by shewing to whom it went. For all that they
-have received, for every responsibility they have undertaken to
-<i>the concern itself</i>, they are bound, or are <i>debtors</i>; for
-everything which has passed out of charge, or about which they are
-relieved from answering <i>to the concern</i>, they are unbound, or are
-<i>creditors</i>. These words must be taken in a very wide sense by any
-<span class="pagenum" id="Page_182">[Pg 182]</span>
-one to whom book-keeping is not to be a mystery. Thus, whenever
-any account assumes responsibility to any parties <i>out of the
-concern</i>, it must be creditor in the books, and debtor whenever it
-discharges any other parties of their responsibility. But whenever an
-account removes responsibility from any other account in the same books
-it is debtor, and creditor whenever it imposes the same.</p>
-
-<p>To whom are all these parties, or accounts, bound, and from whom are
-they released? Undoubtedly the merchant himself, or, more properly,
-the <i>balance-clerk</i>, presently mentioned. But it is customary to
-say that the accounts are debtors <i>to</i> each other, and creditors
-<i>by</i> each other. Thus, cash <i>debtor</i> to bills receivable,
-means that the cash account (or the clerk who keeps it) is bound to
-answer for a sum which was paid on a bill of exchange due to the
-house. At full length it would be: “Mr. C (who keeps the cash-box)
-has received, and is answerable for, this sum which has been paid in
-by Mr. A, when he paid his bill of exchange.” On the other hand, the
-corresponding entry in the account of bills receivable runs&mdash;bills
-receivable, <i>creditor</i> by cash. At full length: “Mr. B (who keeps
-the bills receivable) is freed from all responsibility for Mr. A’s
-bill, which he once held, by handing over to Mr. C, the cash-clerk, the
-money with which Mr. A took it up.” Bills receivable creditor <i>by</i>
-cash is intelligible, but cash debtor <i>to</i> bills receivable is
-a misnomer. The cash account is debtor <i>to the merchant by</i> the
-sum received for the bill, and it should be cash debtor <i>by</i> bill
-receivable. The fiction of debts, not one of which is ever paid to the
-party <i>to</i> whom it is said to be owing, though of no consequence
-in practice, is a stumbling-block to the learner; but he must keep the
-phrase, and remember its true meaning.</p>
-
-<p>The account which is made <i>debtor</i>, or bound, is said to be
-<i>debited</i>; that which is made <i>creditor</i>, or released, is
-said to be <i>credited</i>. All who receive must be <i>debited</i>; all
-who give must be <i>credited</i>.</p>
-
-<p>No cancel is ever made. If cash received be afterwards repaid, the
-sum paid is not struck off the receipts (or debtor-side of the cash
-account), but a discharge, or credit, is written on the expenditure
-(or credit) side.
-<span class="pagenum" id="Page_183">[Pg 183]</span></p>
-
-<p>The book in which the accounts are kept is called a <i>ledger</i>.
-It has double columns, or else the debtor-side is on one page, and the
-creditor side on the opposite, of each account. The debtor-side is
-always the left. Other books are used, but they are only to help in
-keeping the ledger correct. Thus there may be a <i>waste-book</i>, in
-which all transactions are entered as they occur, in common language;
-a <i>journal</i>, in which the transactions described in the waste-book
-are entered at stated periods, in the language of the ledger. The items
-entered in the journal have references to the pages of the ledger
-to which they are carried, and the items in the ledger have also
-references to the pages of the journal from which they come; and by
-this mode of reference it is easy to make a great deal of abbreviation
-in the ledger. Thus, when it happens, in making up the journal to a
-certain date, that several different sums were paid or received at or
-near the same time, the totals may be entered in the ledger, and the
-cash account may be made debtor to, or creditor by, sundry accounts,
-or sundries; the sundry accounts being severally credited or debited
-for their shares of the whole. The only book that need be explained is
-the ledger. All the other books, and the manner in which they are kept,
-important as they may be, have nothing to do with the main principle
-of the method. Let us, then, suppose that all the items are entered
-at once in the ledger as they arise. It has appeared that every item
-is entered twice. If A pay on account of B, there is an entry, “A,
-creditor by B;” and another, “B, debtor to A.” This is what is called
-<i>double-entry</i>; and the consequence of it is, that the sum of
-all the debtor items in the whole book is equal to the sum of all the
-creditor items. For what is the first set but the second with the
-items in a different order? If it were convenient, one entry of each
-sum might be made a double-entry. The multiplication table is called
-a table of <i>double-entry</i>, because 42, for instance, though it
-occurs only once, appears in two different aspects, namely, as 6 times
-7 and as 7 times 6. Suppose, for example, that there are five accounts,
-A, B, C, D, E, and that each account has one transaction of its own
-with every other account; and let the debits be in the <i>columns</i>,
-the credits in the <i>rows</i>, as follows:
-<span class="pagenum" id="Page_184">[Pg 184]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <tbody><tr>
- <td class="tdr_ws1">Debtor</td>
- <td class="tdc">&nbsp;&nbsp;<big><b>A</b></big>&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&nbsp;<big><b>B</b></big>&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&nbsp;<big><b>C</b></big>&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&nbsp;<big><b>D</b></big>&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&nbsp;<big><b>E</b></big>&nbsp;&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1 bt2 bb">A, Creditor</td>
- <td class="tdc bt2 bb">&nbsp;</td>
- <td class="tdc bt2 bb">23</td>
- <td class="tdc bt2 bb">19</td>
- <td class="tdc bt2 bb">32</td>
- <td class="tdc bt2 bb">&#8199;4</td>
- </tr><tr>
- <td class="tdr_ws1 bb">B, Creditor</td>
- <td class="tdc bb">17</td>
- <td class="tdc bb">&nbsp;</td>
- <td class="tdc bb">&#8199;6</td>
- <td class="tdc bb">11</td>
- <td class="tdc bb">25</td>
- </tr><tr>
- <td class="tdr_ws1 bb">C, Creditor</td>
- <td class="tdc bb">&#8199;9</td>
- <td class="tdc bb">41</td>
- <td class="tdc bb">&nbsp;</td>
- <td class="tdc bb">10</td>
- <td class="tdc bb">&#8199;2</td>
- </tr><tr>
- <td class="tdr_ws1 bb">D, Creditor</td>
- <td class="tdc bb">14</td>
- <td class="tdc bb">28</td>
- <td class="tdc bb">16</td>
- <td class="tdc bb">&nbsp;</td>
- <td class="tdc bb">&#8199;3</td>
- </tr><tr>
- <td class="tdr_ws1">E, Creditor</td>
- <td class="tdc bb">15</td>
- <td class="tdc bb">&#8199;4</td>
- <td class="tdc bb">60</td>
- <td class="tdc bb">&#8199;1</td>
- <td class="tdc bb">&nbsp;</td>
- </tr><tr>
- <td class="tdc bt" colspan="6">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>Here the 16 is supposed to appear in D’s account as D creditor by C,
-and in C’s account as C debtor to D. And to say that the sum of debtor
-items is the same as that of creditor items, is merely to say that the
-preceding numbers give the same sum, whether the rows or the columns be
-first added up.</p>
-
-<p>If it be desired to close the ledger when it stands as above, the
-following is the way the accounts will stand: the lines in italics will
-presently be explained.
-<span class="pagenum" id="Page_185">[Pg 185]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc bb2" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdc bb2 br" colspan="2"><b>A, Debtor.</b></td>
- <td class="tdc bb2 br" colspan="2"><b>A, Creditor.</b></td>
- <td class="tdc bb2 br" colspan="2"><b>B, Debtor.</b></td>
- <td class="tdc bb2" colspan="2"><b>B, Creditor.</b></td>
- </tr><tr>
- <td class="tdl">To B</td> <td class="tdr_ws1 br">17</td>
- <td class="tdl_ws1">By B</td> <td class="tdr_ws1 br">23</td>
- <td class="tdl_ws1">To A</td> <td class="tdr_ws1 br">23</td>
- <td class="tdl_ws1">By A</td> <td class="tdr_ws1">17</td>
- </tr><tr>
- <td class="tdl">To C</td> <td class="tdr_ws1 br">9</td>
- <td class="tdl_ws1">By C</td> <td class="tdr_ws1 br">19</td>
- <td class="tdl_ws1">To C</td> <td class="tdr_ws1 br">41</td>
- <td class="tdl_ws1">By C</td> <td class="tdr_ws1">6</td>
- </tr><tr>
- <td class="tdl">To D</td> <td class="tdr_ws1 br">14</td>
- <td class="tdl_ws1">By D</td> <td class="tdr_ws1 br">32</td>
- <td class="tdl_ws1">To D</td> <td class="tdr_ws1 br">28</td>
- <td class="tdl_ws1">By D</td> <td class="tdr_ws1">11</td>
- </tr><tr>
- <td class="tdl">To E</td> <td class="tdr_ws1 br">15</td>
- <td class="tdl_ws1">By E</td> <td class="tdr_ws1 br">4</td>
- <td class="tdl_ws1">To E</td> <td class="tdr_ws1 br">4</td>
- <td class="tdl_ws1">By E</td> <td class="tdr_ws1">25</td>
- </tr><tr>
- <td class="tdl">To Balance&emsp;&nbsp;</td> <td class="tdr_ws1 br">23</td>
- <td class="tdc">&nbsp;</td> <td class="tdc br">&nbsp;</td>
- <td class="tdc">&nbsp;</td> <td class="tdc br">&nbsp;</td>
- <td class="tdl_ws1">By Balance&emsp;&nbsp;</td> <td class="tdr_ws1 bb">37</td>
- </tr><tr>
- <td class="tdl bb2">&nbsp;</td> <td class="tdr_ws1 br bb2 bt">78</td>
- <td class="tdl_ws1 bb2">&nbsp;</td> <td class="tdr_ws1 br bb2 bt">78</td>
- <td class="tdl_ws1 bb2">&nbsp;</td> <td class="tdr_ws1 br bb2 bt">96</td>
- <td class="tdl_ws1 bb2">&nbsp;</td> <td class="tdr_ws1 bb2 bt">96</td>
- </tr><tr>
- <td class="tdc bb2 br" colspan="2"><b>C, Debtor.</b></td>
- <td class="tdc bb2 br" colspan="2"><b>C, Creditor.</b></td>
- <td class="tdc bb2 br" colspan="2"><b>D, Debtor.</b></td>
- <td class="tdc bb2" colspan="2"><b>D, Creditor.</b></td>
- </tr><tr>
- <td class="tdl">To A</td> <td class="tdr_ws1 br">19</td>
- <td class="tdl_ws1">By A</td> <td class="tdr_ws1 br">9</td>
- <td class="tdl_ws1">To A</td> <td class="tdr_ws1 br">32</td>
- <td class="tdl_ws1">By A</td> <td class="tdr_ws1">14</td>
- </tr><tr>
- <td class="tdl">To B</td> <td class="tdr_ws1 br">6</td>
- <td class="tdl_ws1">By B</td> <td class="tdr_ws1 br">41</td>
- <td class="tdl_ws1">To B</td> <td class="tdr_ws1 br">11</td>
- <td class="tdl_ws1">By B</td> <td class="tdr_ws1">28</td>
- </tr><tr>
- <td class="tdl">To D</td> <td class="tdr_ws1 br">16</td>
- <td class="tdl_ws1">By D</td> <td class="tdr_ws1 br">10</td>
- <td class="tdl_ws1">To C</td> <td class="tdr_ws1 br">10</td>
- <td class="tdl_ws1">By C</td> <td class="tdr_ws1">16</td>
- </tr><tr>
- <td class="tdl">To E</td> <td class="tdr_ws1 br">60</td>
- <td class="tdl_ws1">By E</td> <td class="tdr_ws1 br">2</td>
- <td class="tdl_ws1">To E</td> <td class="tdr_ws1 br">1</td>
- <td class="tdl_ws1">By E</td> <td class="tdr_ws1">3</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td> <td class="tdc br">&nbsp;</td>
- <td class="tdl_ws1">By Balance&emsp;&nbsp;</td> <td class="tdr_ws1 br">39</td>
- <td class="tdl_ws1">To Balance&emsp;&nbsp;</td> <td class="tdr_ws1 br">7</td>
- <td class="tdc">&nbsp;</td> <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdl bb2">&nbsp;</td> <td class="tdr_ws1 bt bb2 br">101</td>
- <td class="tdl bb2">&nbsp;</td> <td class="tdr_ws1 bt bb2 br">101</td>
- <td class="tdl bb2">&nbsp;</td> <td class="tdr_ws1 bt bb2 br">61</td>
- <td class="tdl bb2">&nbsp;</td> <td class="tdr_ws1 bt bb2">61</td>
- </tr><tr>
- <td class="tdc bb2 br" colspan="2"><b>E, Debtor.</b></td>
- <td class="tdc bb2 br" colspan="2"><b>E, Creditor.</b></td>
- <td class="tdc bb2 br" colspan="2"><i><b>Balance, Debtor.</b></i></td>
- <td class="tdc bb2" colspan="2"><i><b>Balance, Cred.</b></i></td>
- </tr><tr>
- <td class="tdl">To A</td> <td class="tdr_ws1 br">4</td>
- <td class="tdl_ws1">By A</td> <td class="tdr_ws1 br">15</td>
- <td class="tdl_ws1"><i>To B</i></td> <td class="tdr_ws1 br">37</td>
- <td class="tdl_ws1"><i>By A</i></td> <td class="tdr_ws1">23</td>
- </tr><tr>
- <td class="tdl">To B</td> <td class="tdr_ws1 br">25</td>
- <td class="tdl_ws1">By B</td> <td class="tdr_ws1 br">4</td>
- <td class="tdl_ws1"><i>To C</i></td> <td class="tdr_ws1 br">39</td>
- <td class="tdl_ws1"><i>By D</i></td> <td class="tdr_ws1">7</td>
- </tr><tr>
- <td class="tdl">To C</td> <td class="tdr_ws1 br">2</td>
- <td class="tdl_ws1">By C</td> <td class="tdr_ws1 br">60</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br">&nbsp;</td>
- <td class="tdl_ws1"><i>By E</i></td> <td class="tdr_ws1">46</td>
- </tr><tr>
- <td class="tdl"></td> <td class="tdr_ws1 br"></td>
- <td class="tdl_ws1"></td> <td class="tdr_ws1 br"></td>
- <td class="tdl_ws1"></td> <td class="tdr_ws1 br"></td>
- <td class="tdl_ws1"></td> <td class="tdr_ws1"></td>
- </tr><tr>
- <td class="tdl">To D</td> <td class="tdr_ws1 br">3</td>
- <td class="tdl_ws1">By D</td> <td class="tdr_ws1 br">1</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br bt">76</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 bt">76</td>
- </tr><tr>
- <td class="tdl"><i>To Balance</i></td> <td class="tdr_ws1 br">46</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td> <td class="tdr_ws1 br bt">80</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br bt">80</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc bt2" colspan="8">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>In all the part of the above which is printed in Roman letters we see
-nothing but the preceding table repeated. But when all the accounts
-have been completed, and no more entries are left to be made, there
-remains the last process, which is termed <i>balancing the ledger</i>.
-To get an idea of this, suppose a new clerk, who goes round all the
-accounts, collecting debts and credits, and taking them all upon
-himself, that he alone may be entitled to claim the debts and to be
-responsible for the assets of the concern. To this new clerk, whom I
-will call the <i>balance-clerk</i>, every account gives up what it has,
-whether the same be debt or credit. The cash-clerk gives up all the
-cash; the clerks of the two kinds of bills give up all their documents,
-whether bills receivable or entries of bills payable (remember that
-any entry against which there is money set down in the books counts as
-money when given up, that is, as money due or money owing); the clerks
-of the several accounts of goods give up all their unsold remainders
-at cost prices; the clerks of the several personal accounts give up
-vouchers for the sums owing to or from the several parties; and so
-on. But where more has been paid out than received, the balance-clerk
-<span class="pagenum" id="Page_186">[Pg 186]</span>
-adjusts these accounts by giving instead of receiving; in fact, he so
-acts as to make the debtor and creditor sides of the accounts he visits
-equal in amount. For instance, the A account is indebted to the concern
-55, while payments or discharges to the amount of 78 have been made by
-it. The balance-clerk accordingly hands over 23 to that account, for
-which it becomes debtor, while the balance enters itself as creditor to
-the same amount. But in the B account there is 96 of receipt, and only
-59 of payment or discharge. The balance-clerk then receives 37 from
-this account, which is therefore credited by balance, while the balance
-acknowledges as much of debt. The balance account must, of course,
-exactly balance itself, if the accounts be all right; for of all the
-equal and opposite entries of which the ledger consists, so far as
-they do not balance one another, one goes into one side of the balance
-account, and the other into the other. Thus the balance account becomes
-a test of the accuracy of one part of the work: if its two sides do not
-give the same sums, either there have been entries which have not had
-their corresponding balancing entries correctly made, or else there has
-been error in the additions.</p>
-
-<p>But since the balance account must thus always give the <i>same
-sum</i> on both sides, and since <i>balance debtor</i> implies what
-is favourable to the concern, and <i>balance creditor</i> what is
-unfavourable, does it not appear as if this system could only be
-applied to cases in which there is neither loss nor gain? This brings
-us to the two accounts in which are entered all that the concern
-<i>began with</i>, and all that it <i>gains or loses</i>&mdash;the
-<i>stock account</i>, and the <i>profit-and-loss account</i>. In order
-to make all that there was to begin with a matter of double entry, the
-opening of the ledger supposes the merchant himself to put his several
-clerks in charge of their several departments. In the stock account,
-<i>stock</i>, which here stands for the owner of the books, is made
-creditor by all the property, and debtor by all the liabilities; while
-the several accounts are made debtors for all they take from the stock,
-and creditors by all the responsibilities they undertake. Suppose, for
-instance, there are £500 in cash at the commencement of the ledger.
-There will then appear that the merchant has handed over to the
-cash-box £500, and in the stock account will appear, “Stock creditor by
-<span class="pagenum" id="Page_187">[Pg 187]</span>
-cash, £500;” while in the cash account will appear, “Cash debtor to
-stock, £500.” Suppose that at the beginning there is a debt outstanding
-of £50 to Smith and Co., then there will appear in the stock account,
-“Stock debtor to Smith and Co. £50,” and in Smith and Co.’s account
-will appear “Smith and Co. creditors by stock, £50.” Thus there is
-double entry for all that the concern begins with by this contrivance
-of the stock account.</p>
-
-<p>The account to which everything is placed for which an actual
-equivalent is not seen in the books is the <i>profit-and-loss</i>
-account. This profit-and-loss account, or the clerk who keeps it, is
-made answerable for every loss, and the supposed cause of every gain.
-This account, then, becomes debtor for every loss, and creditor by
-every gain. If goods be damaged to the amount of £20 by accident,
-and a loss to that amount occur in their sale, say they cost £80 and
-sell for £60 cash, it is clear that there is an entry “Cash debtor to
-goods £60,” and “Goods creditor by cash £60.” Now, there is an entry
-of £80 somewhere to the debit of the goods for cash laid out, or bills
-given, for the whole of the goods. It would affect the accuracy of
-the accounts to take no notice of this; for when the balance-clerk
-comes to adjust this account, he would find he receives £20 less than
-he might have reckoned upon, without any explanation of the reason;
-and there would be a failure of the principle of double-entry. Since
-it is convenient that the balance account of the goods should merely
-represent the stock in hand at the close, the account of goods
-therefore lays the responsibility of £20 upon the profit-and-loss
-account, or there is the entry “Goods creditor by profit-and-loss,
-£20,” and also “Profit-and-loss debtor to goods, £20.” Again, in
-all payments which are not to bring in a specific return, such as
-house and trade expenses, wages, &amp;c. these several accounts are
-supposed to adjust matters with the profit-and-loss account before the
-balance begins. Thus, suppose the outgoings from the mere premises
-occupied exceed anything those premises yield by £200, or the debits
-of the house account exceed its credits by £200, the account should
-be balanced by transferring the responsibility to the profit-and-loss
-<span class="pagenum" id="Page_188">[Pg 188]</span>
-account, under the entries “House expenses creditor by profit-and-loss,
-£200”, “Profit-and-loss debtor to house expenses, £200.” In this way
-the profit-and-loss account steps in from time to time before the
-balance account commences its operations, in order that that same
-balance account may consist of <i>nothing but the necessary matters of
-account for the next year’s ledger</i>.</p>
-
-<p>This <i>transference of accounts</i>, or transfusion of one account
-into another, requires attentive consideration. The receiving account
-becomes creditor for the credits, and debtor for the debits, of the
-transmitting account. The rule, therefore, is: Make the transmitting
-account balance itself, and, on whichever side it is necessary to enter
-a balancing sum, make the account debtor or creditor, as the case may
-be, to the receiving account, and the latter creditor or debtor to the
-former. Thus, suppose account A is to be transferred to account B, and
-the latter is to arrange with the balance account. If the two stand as
-in Roman letters, the processes in Italic letters will occur before the
-final close.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc bb2" colspan="8">&nbsp;</td>
- </tr><tr>
- <td class="tdc bb2 br" colspan="2"><b>A, Debtor.</b></td>
- <td class="tdc bb2 br2" colspan="2"><b>A, Creditor.</b></td>
- <td class="tdc bb2 br" colspan="2"><b>B, Debtor.</b></td>
- <td class="tdc bb2" colspan="2"><b>B, Creditor.</b></td>
- </tr><tr>
- <td class="tdl">To sundries&emsp;&nbsp;</td> <td class="tdr_ws1 br">£100</td>
- <td class="tdl_ws1">By sundries&emsp;&nbsp;</td> <td class="tdr_ws1 br2">£500</td>
- <td class="tdl_ws1">To sundries&emsp;&nbsp;</td> <td class="tdr_ws1 br">£600</td>
- <td class="tdl_ws1">By sundries&emsp;&nbsp;</td> <td class="tdr_ws1">£400</td>
- </tr><tr>
- <td class="tdl"><i>To B</i></td> <td class="tdr_ws1 br">400</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br2">&nbsp;</td>
- <td class="tdl_ws1"><i>To Balance</i></td> <td class="tdr_ws1 br">200</td>
- <td class="tdl_ws1"><i>By A</i></td> <td class="tdr_ws1">400</td>
- </tr><tr>
- <td class="tdl">&nbsp;</td> <td class="tdr_ws1 br bt">£500</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br2 bt">£500</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 br bt">£800</td>
- <td class="tdl_ws1">&nbsp;</td> <td class="tdr_ws1 bt">£800</td>
- </tr><tr>
- <td class="tdc bt2" colspan="8">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">And the entry in the balance account will be, “Creditor by B, £200,”
-shewing that, on these two accounts, the credits exceed the debits by £200.</p>
-
-<p>Still, before the balance account is made up, it is desirable that the
-profit-and-loss account should be transferred to the stock account;
-for the profit and loss of this year is of no moment as a part of
-next year’s ledger, except in so far as it affects the stock at the
-commencement of the latter. Let this be done, and the balance account
-may then be made in the form required.</p>
-
-<p>The stock account and the profit-and-loss account, the latter being the
-only direct channel of alteration for the former, differ in a peculiar
-manner<a id="FNanchor_60" href="#Footnote_60" class="fnanchor">[60]</a>
-from the other preliminary accounts, and the balance account
-<span class="pagenum" id="Page_189">[Pg 189]</span>
-is a species of umpire. They represent the merchant: their interests
-are his interests; he is solvent upon the excess of their credits
-over their debits, insolvent upon the excess of their debits over
-their credits. It is exactly the reverse in all the other accounts.
-If a malicious person were to get at the ledger, and put on a cipher
-to the pounds in various items, with a view of making the concern
-appear worse than it really is, he would make his alterations on
-the <i>debtor</i> sides of the stock and profit-and-loss accounts,
-and on the <i>creditor</i> sides of all the others. Accordingly, in
-the balance account, the net stock, after the incorporation of the
-profit-and-loss account, appears on the <i>creditor</i> side (if not,
-it should be called amount of <i>insolvency</i>, not <i>stock</i>), and
-the debts of the concern appear on the same side. But on the debit side
-of the balance account appear all the assets of the concern (for which
-the balance-clerk is debtor to the clerks from whom he has taken them).</p>
-
-<p>The young student must endeavour to get the enlarged view of the words
-debtor and creditor which is requisite, and must then learn by practice
-(for nothing else will give it) facility in allotting the actual
-entries in the waste-book to the proper sides of the proper accounts.
-I do not here pretend to give more than such a view of the subject as
-may assist him in studying a treatise on book-keeping, which he will
-probably find to contain little more than examples.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<p><span class="pagenum" id="Page_190">[Pg 190]</span></p>
-<h3 class="nobreak" id="APPENDIX_VIII">APPENDIX VIII.<br />
-<span class="h_subtitle">ON THE REDUCTION OF FRACTIONS TO<br />
-OTHERS OF NEARLY EQUAL VALUE.</span></h3>
-</div>
-
-<p>There is a useful method of finding fractions which shall be nearly
-equal to a given fraction, and with which the computer ought to be
-acquainted. Proceed as in the rule for finding the greatest common
-measure of the numerator and denominator, and bring all the quotients
-into a line. Then write down,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2"><span class="ws2">&nbsp;</span></td>
- <td class="tdc">2nd Quot.</td>
- </tr><tr>
- <td class="tdc over">1st Quot.</td>
- <td class="tdc over">1st Quot. × 2d Quot. + 1</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Then take the third quotient, multiply the
-numerator and denominator of the second by it, and add to the products
-the preceding numerator and denominator. Form a third fraction with the
-results for a numerator and denominator. Then take the fourth quotient,
-and proceed with the third and second fractions in the same way; and so
-on till the quotients are exhausted. For example, let the fraction be
-<big>⁹¹³¹/₁₃₁₂₈</big>.</p>
-
-<ul class="index fontsize_120">
-<li class="isub2">9131)13128(1, 2</li>
-<li class="isub2">1137   3997(3, 1</li>
-<li class="isub2-5">551    586(1, 15</li>
-<li class="isub2-5">201      35(1, 2</li>
-<li class="isub3">26        9(1, 8</li>
-<li class="isub3-5">8        1</li>
-</ul>
-
-<p>This is the process for finding the greatest common measure of 9131 and
-13128 in its most compact form, and the quotients and fractions are:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr class="fontsize_150">
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">15</td>
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">1</td>
- <td class="tdc">8</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">7</td>
- <td class="tdc">9</td>
- <td class="tdc">16</td>
- <td class="tdc">249</td>
- <td class="tdc">265</td>
- <td class="tdc">779</td>
- <td class="tdc">1044</td>
- <td class="tdc">9131</td>
- </tr><tr>
- <td class="tdc bt">&nbsp;1&nbsp;</td>
- <td class="tdc bt">&nbsp;3&nbsp;</td>
- <td class="tdc bt">&nbsp;10&nbsp;</td>
- <td class="tdc bt">&nbsp;13&nbsp;</td>
- <td class="tdc bt">&nbsp;23&nbsp;</td>
- <td class="tdc bt">&nbsp;358&nbsp;</td>
- <td class="tdc bt">&nbsp;381&nbsp;</td>
- <td class="tdc bt">&nbsp;1120&nbsp;</td>
- <td class="tdc bt">&nbsp;1501&nbsp;</td>
- <td class="tdc bt">&nbsp;13128&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>It will be seen that we have thus a set of fractions ending with the
-original fraction itself, and formed by the above rule, as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr" rowspan="2">1st Fraction =&nbsp;</td>
- <td class="tdl">&nbsp;&emsp;1</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdl over">1st Quot.</td>
- <td class="tdc over">&nbsp;1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2">2d Fraction =&nbsp;</td>
- <td class="tdl"><span class="ws3">2d Quot.</span></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">2</td>
- </tr><tr>
- <td class="tdl over">1st Quot. × 2d Quot. + 1</td>
- <td class="tdc over">&nbsp;3&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr" rowspan="2">3d Fraction =&nbsp;</td>
- <td class="tdc">2d Numʳ. × 3d Quot. + 1st Numʳ.</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">2 × 3 + 1</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">7</td>
- </tr><tr>
- <td class="tdc bt">2d Denʳ. × 3d Quot. + 1st Denʳ.</td>
- <td class="tdc bt">3 × 3 + 1</td>
- <td class="tdc bt">10</td>
- </tr><tr>
- <td class="tdr" rowspan="2">4th Fraction =&nbsp;</td>
- <td class="tdc">3d Numʳ. × 4th Quot. + 2d Numʳ.</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">7 × 1 + 2 </td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc">9</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc bt">3d Denʳ. × 4th Quot. + 2d Denʳ.</td>
- <td class="tdc bt">10 × 1 + 3</td>
- <td class="tdc bt">13</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_191">[Pg 191]</span>
-and so on. But we have done something more than merely reascend to the
-original fraction by means of the quotients. The set of fractions, ¹/₁,
-²/₃, ⁷/₁₀, ⁹/₁₃, &amp;c. are continually approaching in value to the
-original fraction, the first being too great, the second too small, the
-third too great, and so on alternately, but each one being nearer to
-the given fraction than any of those before it. Thus, ¹/₁ is too great,
-and ²/₃ is too small; but ²/₃ is not so much too small as ¹/₁ is too
-great. And again, ⁷/₁₀, though too great, is not so much too great as
-²/₃ is too small.</p>
-
-<p>Moreover, the difference of any of the fractions from the original
-fraction is never greater than a fraction having unity for its
-numerator and the product of the denominator and the next denominator
-for its denominator. Thus, ¹/₁ does not err by so much as ¹/₃, nor ²/₃
-by so much as ¹/₃₀, nor ⁷/₁₀ by so much as ¹/₁₃₀, nor ⁹/₁₃ by so much
-as ¹/₂₉₉, &amp;c.</p>
-
-<p>Lastly, no fraction of a less numerator and denominator can come
-so near to the given fraction as any one of the fractions in the
-list. Thus, no fraction with a less numerator than 249, and a less
-denominator than 358, can come so near to</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">9131</td>
- <td class="tdc" rowspan="2">&nbsp;as&nbsp;</td>
- <td class="tdc">249</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc bt">13128</td>
- <td class="tdc bt">358</td>
- </tr>
- </tbody>
-</table>
-
-<p>The reader may take any example for himself, and the test of the
-accuracy of the process is the ultimate return to the fraction begun
-with. Another test is as follows: The numerator of the difference of
-any two consecutive approximating fractions ought to be unity. Thus,
-in our instance, we have <big>¹⁶/₂₃</big> and <big>²⁴⁹/₃₅₈</big>, which, with
-a common denominator, 23 × 358, have 5728 and 5727 for their numerators.</p>
-
-<p>As another example, let us examine this question: The length of the
-year is 365·24224 days, which is called in common life 365¼ days. Take
-the fraction <big>²⁴²²⁴/₁₀₀₀₀₀</big>, and proceed as in the rule.</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">24224)100000(4, 7, 1, 4, 9, 2</li>
-<li class="isub2-5">2496     3104</li>
-<li class="isub3-5">64       608</li>
-<li class="isub4">0         32</li>
-</ul>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc">7</td>
- <td class="tdc">8</td>
- <td class="tdc">39</td>
- <td class="tdc">359</td>
- <td class="tdc">757</td>
- </tr><tr>
- <td class="tdc over">&nbsp;4&nbsp;</td>
- <td class="tdc over">&nbsp;29&nbsp;</td>
- <td class="tdc over">&nbsp;33&nbsp;</td>
- <td class="tdc over">&nbsp;161&nbsp;</td>
- <td class="tdc over">&nbsp;1482&nbsp;</td>
- <td class="tdc over">&nbsp;3125&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and <big>⁷⁵⁷/₃₁₂₅</big> is ·24224 in its
-lowest terms. Hence, it appears that the excess of the year over
-365 days amounts to about 1 day in 4 years, <span class="pagenum"
-id="Page_192">[Pg 192]</span> which is not wrong by so much as 1 day in
-116 years; more accurately, to 7 days in 29 years, which is not wrong
-by so much as 1 day in 957 years; more accurately still, to 8 days in
-33 years, which is not wrong by so much as 1 day in 5313 years; and so
-on.</p>
-
-<p>This method may be applied to finding fractions nearly equal to the
-square roots of integers, in the following manner:</p>
-
-<ul class="index fontsize_130">
-<li class="isub3-5 u">&nbsp;&nbsp;&nbsp;&nbsp;</li>
-<li class="isub3">√43 = 6 + ...</li>
-</ul>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr br">6</td>
- <td class="tdl br">1 5 4 5 5 4 5 1 6 6</td>
- <td class="tdl">1 5 4, &amp;c.</td>
- </tr><tr>
- <td class="tdl br bb">1</td>
- <td class="tdl br bb">7 6 3 9 2 9 3 6 7 1</td>
- <td class="tdl bb">7 6 3, &amp;c.</td>
- </tr><tr>
- <td class="tdl br">6</td>
- <td class="tdl br">1 1 3 1 5 1 3 1 1 1 2</td>
- <td class="tdl">1 1 3, &amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p>Set down the number whose square root is wanted, say 43. This square
-root is 6 and a fraction. Set down the integer 6 in the first and third
-row, and 1 in the second row always. Form the successive rows each from
-the one before, in the following manner:</p>
-
-<table class="no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">One row<br />being</td>
- <td class="tdc">The next row has <i>b′</i>, <i>a′</i>, <i>c′</i>, formed<br /> in this order, thus,</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdl"><i>a′</i> = excess of <i>b′c′</i>, already formed, over <i>a</i>.</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdl"><i>b′</i> = quotient of 43 - <i>a</i>² divided by <i>b</i>.</td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdl"><i>c′</i> = integer in the quotient of 6 + <i>a</i> divided by <i>b′</i>.</td>
- </tr><tr>
- <td class="tdl_space-above1" colspan="2">Thus the second row is formed from the first, as under:</td>
- </tr><tr>
- <td class="tdr br">6</td>
- <td class="tdl">1 = excess of 7 × 1 (both just found) over 6.</td>
- </tr><tr>
- <td class="tdr br"><span class="u">1</span></td>
- <td class="tdl"><span class="u">7</span> = 43 - 6 × 6 divided by 1.</td>
- </tr><tr>
- <td class="tdr br">6</td>
- <td class="tdl">1 = integer of 6 + 6 divided by 7 (just found).</td>
- </tr><tr>
- <td class="tdl_space-above1" colspan="2">The third row is formed from the second, thus:</td>
- </tr><tr>
- <td class="tdr">1&nbsp;</td>
- <td class="tdl">5 = excess of 1 × 6 over 1.</td>
- </tr><tr>
- <td class="tdr">7&nbsp;</td>
- <td class="tdl">6 = 43 - 1 × 1 divided by 7.</td>
- </tr><tr>
- <td class="tdr">1&nbsp;</td>
- <td class="tdl">1 = integer of 6 + 1 divided by 6;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on. In process of time the second column,
-1, 7, 1, occurs again, after which the several columns are repeated in
-the same order. As a final process, take the set in the lowest line
-(excluding the first, 6), namely, 1, 1, 3, 1, 5, 1, 3, &amp;c. and use
-them by the rule given at the beginning of this article, as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr class="fontsize_150">
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">3</td>
- <td class="tdc">1</td>
- <td class="tdc">5</td>
- <td class="tdc">1</td>
- <td class="tdc">3</td>
- <td class="tdc">1</td>
- <td class="tdc">1,</td>
- <td class="tdc"><span class="fontsize_80">&nbsp;&amp;c.</span></td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">4</td>
- <td class="tdc">5</td>
- <td class="tdc">29</td>
- <td class="tdc">34</td>
- <td class="tdc">131</td>
- <td class="tdc">165</td>
- <td class="tdc">296</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc bt">&nbsp;1&nbsp;</td>
- <td class="tdc bt">&nbsp;2&nbsp;</td>
- <td class="tdc bt">&nbsp;7&nbsp;</td>
- <td class="tdc bt">&nbsp;9&nbsp;</td>
- <td class="tdc bt">&nbsp;52&nbsp;</td>
- <td class="tdc bt">&nbsp;61&nbsp;</td>
- <td class="tdc bt">&nbsp;235&nbsp;</td>
- <td class="tdc bt">&nbsp;296&nbsp;</td>
- <td class="tdc bt">&nbsp;531&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_193">[Pg 193]</span>
-Hence, <big>6¹⁶⁵/₂₉₆</big> is very near the square root of 43, not erring by so
-much as</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc bt">296 × 531</td>
- </tr>
- </tbody>
-</table>
-
-<p>If we try it, we shall find <big>(⁶¹⁶⁵/₂₉₆)</big> to be <big>¹⁹⁴¹/₂₉₆</big>,
-the square of which is <big>³⁷⁶⁷⁴⁸¹/₈₇₆₁₆</big>, or <big>43⁷/₈₇₆₁₆</big>.</p>
-
-<p>This rule is of use when it is frequently wanted to use one square
-root, and therefore desirable to ascertain whether any easy
-approximation exists by means of a common fraction. For example, √2 is
-often used.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr br">√2</td>
- <td class="tdl">&nbsp;= 1 + ...</td>
- </tr><tr>
- <td class="tdr br">1</td>
- <td class="tdl">1 &nbsp;1</td>
- </tr><tr>
- <td class="tdr br">1</td>
- <td class="tdl">1 &nbsp;1</td>
- </tr><tr>
- <td class="tdr br">1</td>
- <td class="tdl">2 &nbsp;2    2    2    2    2</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">5</td>
- <td class="tdc">12</td>
- <td class="tdc">29</td>
- <td class="tdc">70</td>
- <td class="tdc" rowspan="2">&nbsp;&amp;c.</td>
- </tr><tr>
- <td class="tdc bt">&nbsp;2&nbsp;</td>
- <td class="tdc bt">&nbsp;5&nbsp;</td>
- <td class="tdc bt">&nbsp;12&nbsp;</td>
- <td class="tdc bt">&nbsp;29&nbsp;</td>
- <td class="tdc bt">&nbsp;70&nbsp;</td>
- <td class="tdc bt">&nbsp;169&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>Here it appears that</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr" rowspan="2"><span class="fontsize_150">1</span></td>
- <td class="tdc">29</td>
- <td class="tdc" rowspan="2">&nbsp;does not err by&nbsp;</td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc bt">70</td>
- <td class="tdc bt">70 × 169</td>
- </tr>
- </tbody>
-</table>
-<p>&nbsp;</p>
-<table class="fontsize_110 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr" rowspan="2">consequently,</td>
- <td class="tdc">99</td>
- <td class="tdc" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc bb">100 - 1</td>
- <td class="tdc" rowspan="2">&nbsp;is,</td>
- </tr><tr>
- <td class="tdc bt">70</td>
- <td class="tdc">70</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">considering the ease of the operation, a fair approximation.
-In fact, <big>⁹⁹/₇₀</big> is 1·4142857 ... the truth being 1·4142135 ...</p>
-
-<p>The following is an additional example:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="2" summary=" " cellpadding="2" >
- <tbody><tr>
- <td class="tdr">√</td>
- <td class="tdr br bt">19</td>
- <td class="tdl">&nbsp;= 4 + ...</td>
- </tr><tr>
- <td class="tdc" rowspan="3">&nbsp;</td>
- <td class="tdr br">4</td>
- <td class="tdl">2    3    3    2    4    4    2</td>
- </tr><tr>
- <td class="tdr br">1</td>
- <td class="tdl">3    5    2    5    3    1    3</td>
- </tr><tr>
- <td class="tdr br">4</td>
- <td class="tdl">2    1    3    1    2    8    2    1    3    1    2, &amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">4</td>
- <td class="tdc">5</td>
- <td class="tdc">14</td>
- <td class="tdc" rowspan="2">,&nbsp;&amp;c.</td>
- </tr><tr>
- <td class="tdc bt">&nbsp;2&nbsp;</td>
- <td class="tdc bt">&nbsp;3&nbsp;</td>
- <td class="tdc bt">&nbsp;11&nbsp;</td>
- <td class="tdc bt">&nbsp;14&nbsp;</td>
- <td class="tdc bt">&nbsp;39&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_IX">APPENDIX IX.<br />
-<span class="h_subtitle">ON SOME GENERAL PROPERTIES OF NUMBERS.</span></h3>
-</div>
-
-<p id="PROP_1"><b><span class="smcap">Prop. 1.</span></b> If a fraction be reduced to
-its lowest terms, <i>so called</i>,<a id="FNanchor_61" href="#Footnote_61" class="fnanchor">[61]</a>
-that is, if neither, numerator nor denominator be divisible by any
-integer greater than unity, then no fraction of a smaller numerator and
-denominator can have the same value.</p>
-
-<p>Let <i>a</i>/<i>b</i> be a fraction in which <i>a</i> and <i>b</i>
-have no common measure greater than unity: and, if possible, let
-<i>c</i>/<i>d</i> be a fraction of the same value, <i>c</i> being less
-than <i>a</i>, and <i>d</i> less than <i>b</i>. Now, since</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;we have&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>d</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_194">[Pg 194]</span>
-let <i>m</i> be the integer quotient of these last fractions (which
-must exist, since <i>a</i> &gt; <i>c</i>, <i>b</i> &gt; <i>d</i>), and let
-<i>e</i> and <i>f</i> be the remainders. Then</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;or&nbsp;</td>
- <td class="tdc u">&nbsp;<i>mc</i> + <i>e</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>mc</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>md</i> + <i>f</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>md</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Hence,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>e</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc u">&nbsp;<i>mc</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;must be equal,  for if not,</td>
- </tr><tr>
- <td class="tdc"><i>f</i></td>
- <td class="tdc"><i>md</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>mc</i> + <i>e</i></td>
- <td class="tdc" rowspan="2">&nbsp;would lie between&nbsp;</td>
- <td class="tdc u">&nbsp;<i>mc</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;and&nbsp;</td>
- <td class="tdc u">&nbsp;<i>e</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>md</i> + <i>f</i></td>
- <td class="tdc"><i>md</i></td>
- <td class="tdc"><i>f</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">instead of being equal to the former. Hence,</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>e</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>f</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">so that if a fraction whose numerator and denominator have
-no common measure greater than unity, be equal to a fraction of lower numerator
-and denominator, it is equal to another in which the numerator and
-denominator are still lower. If we proceed with</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>e</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;in a similar manner, we find</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>f</i></td>
- </tr>
- </tbody>
-</table>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>g</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;where <i>g</i> &lt; <i>e</i>,&emsp;<i>h</i> &lt; <i>f</i>,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>h</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and so on. Now, if there be any process which perpetually
-diminishes the terms of a fraction by one or more units at every step, it must
-at last bring either the numerator or denominator, or both, to 0. Let</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>v</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>w</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">be one of the steps,
-and let <i>a</i> = <i>kv</i> + <i>x</i>, <i>b</i> = <i>kw</i> + <i>y</i>; so that</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>kv</i> + <i>x</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>v</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>kw</i> + <i>y</i></td>
- <td class="tdc"><i>w</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Now, if <i>x</i> = 0 but not <i>y</i>, this is absurd, for it gives</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><i>kv</i></td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>kv</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc over"><i>kw</i> + <i>y</i></td>
- <td class="tdc"><i>kw</i></td>
- </tr>
- </tbody>
-</table>
-
-<p>A similar absurdity follows if <i>y</i> be 0, but not <i>x</i>; and if
-both <i>x</i> and <i>y</i> be = 0, then <i>a</i> = <i>kv</i>, <i>b</i>
-= <i>kw</i>, or <i>a</i> and <i>b</i> have a common measure, <i>k</i>.
-Now <i>k</i> must be greater than 1, for <i>v</i> and <i>w</i> are less
-than <i>c</i> and <i>d</i>, which by hypothesis are less than <i>a</i>
-and <i>b</i>. Consequently <i>a</i> and <i>b</i> have a common measure
-<i>k</i> greater than 1, which by hypothesis they have not. If, then,
-<i>a</i> and <i>b</i> be integers not divisible by any integer greater
-than 1, the fraction <i>a</i>/<i>b</i> is really <i>in its lowest
-terms</i>. Also <i>a</i> and <i>b</i> are said to be <i>prime to one
-another</i>.</p>
-
-<p id="PROP_2"><b><span class="smcap">Prop. 2.</span></b> If the product <i>ab</i> be divisible
-by <i>c</i>, and if <i>c</i> be prime to <i>b</i>, it must divide <i>a</i>. Let</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u"><i>ab</i></td>
- <td class="tdc" rowspan="2">&nbsp;= <i>d</i>, then&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;.</td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>c</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Now <i>b</i>/<i>c</i> is in its lowest terms; therefore, by
-the last proposition, <i>d</i> and <i>a</i> must have a common measure. Let the
-greatest common measure be <i>k</i>, and let <i>a</i> = <i>kl</i>,
-<i>d</i> = <i>km</i>. Then</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>b</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>km</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;<i>m</i>&nbsp;</td>
- <td class="tdc" rowspan="2">, &nbsp;and &nbsp;</td>
- <td class="tdc u">&nbsp;<i>m</i>&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>kl</i></td>
- <td class="tdc"><i>l</i></td>
- <td class="tdc"><i>l</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">is also in its lowest terms; but so is <i>b</i>/<i>c</i>;
-therefore we must have <i>m</i> = <i>b</i>, <i>l</i> = <i>c</i>, for otherwise
-a fraction in its lowest terms would be equal to another of lower terms.
-Therefore <i>a</i> = <i>kc</i>, or <i>a</i> is divisible by <i>c</i>.
-And from this it follows, that if a number be prime to two others, it
-<span class="pagenum" id="Page_195">[Pg 195]</span>
-is prime to their product. Let <i>a</i> be prime to <i>b</i> and
-<i>c</i>, then no measure of <i>a</i> can measure either <i>b</i> or
-<i>c</i>, and no such measure can measure the product <i>bc</i>; for
-any measure of <i>bc</i> which is prime to one must measure the other.</p>
-
-<p id="PROP_3"><b><span class="smcap">Prop. 3.</span></b> If <i>a</i> be prime to <i>b</i>, it is prime to
-all the powers of <i>b</i>. Every measure<a id="FNanchor_62" href="#Footnote_62" class="fnanchor">[62]</a>
-of <i>a</i> is prime to <i>b</i>, and therefore does not divide
-<i>b</i>. Hence, by the last, no measure of <i>a</i> divides <i>b</i>²;
-hence, <i>a</i> is prime to <i>b</i>², and so is every measure of it;
-therefore, no measure of <i>a</i> divides <i>bb</i>², consequently
-<i>a</i> is prime to <i>b</i>³, and so on.</p>
-
-<p>Hence, if <i>a</i> be prime to <i>b</i>, <i>a</i> cannot divide without
-remainder any power of <i>b</i>. This is the reason why no fraction
-can be made into a decimal unless its denominator be measured by no
-prime<a id="FNanchor_63" href="#Footnote_63" class="fnanchor">[63]</a>
-numbers except 2 and 5. For if</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;=&nbsp;</td>
- <td class="tdc u">&nbsp;&nbsp;<i>c</i>&nbsp;&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">10ⁿ</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">which last is the general form of a decimal fraction, let</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">&nbsp;<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;be in its lowest terms; then&nbsp;</td>
- <td class="tdc u">&nbsp;10ⁿ<i>a</i>&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;,</td>
- </tr><tr>
- <td class="tdc"><i>b</i></td>
- <td class="tdc">b</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">is an integer, whence (<a href="#PROP_2"><b>Prop. 2</b></a>)
-<i>b</i> must divide 10ⁿ, and so must all the divisors of <i>b</i>. If, then, among
-the divisors of <i>b</i> there be any prime numbers except 2 and 5,
-we have a prime number (which is of course a number prime to 10) not
-dividing 10, but dividing one of its powers, which is absurd.</p>
-
-<p id="PROP_4"><b><span class="smcap">Prop. 4.</span></b> If <i>b</i> be prime to <i>a</i>, all
-the multiples of <i>b</i>, as <i>b</i>, 2<i>b</i>, ... up to (<i>a</i>-1)<i>b</i>
-must leave different remainders when divided by <i>a</i>. For if,
-<i>m</i> being greater than <i>n</i>, and both less than <i>a</i>, we
-have <i>mb</i> and <i>nb</i> giving the same remainder, it follows that
-<i>mb</i>-<i>nb</i>, or (<i>m</i>-<i>n</i>)<i>b</i>, is divisible
-by <i>a</i>; whence (<a href="#PROP_2"><b>Prop. 2</b></a>), a divides
-<i>m</i>-<i>n</i>, a number less than itself, which is absurd.</p>
-
-<hr class="r65" />
-
-<p>If a number be divided into its prime factors, or reduced to a product
-of prime numbers only (as in 360 = 2 × 2 × 2 × 3 × 3 × 5), and if
-<i>a</i>, <i>b</i>, <i>c</i>, &amp;c. be the prime factors, and α, β,
-γ, &amp;c. the number of times they severally enter, so that the number
-is <big><i>a</i><sup>α</sup> × <i>b</i>ᵝ × <i>c</i>ᵞ ×</big> &amp;c., then this can be
-done in only one way: For any prime number <i>v</i>, not included in
-<span class="pagenum" id="Page_196">[Pg 196]</span>
-the above list, is prime to <i>a</i>, and therefore to <i>a</i><sup>α</sup>,
-to <i>b</i> and therefore to <i>b</i>ᵝ and therefore to <big><i>a</i><sup>α</sup> ×
-<i>b</i>ᵝ</big> Proceeding in this way, we prove that <i>v</i> is prime to
-the complete product above, or to the given number itself.</p>
-
-<p>The number of divisors which the preceding number
-<big><i>a</i><sup>α</sup><i>b</i>ᵝ<i>c</i>ᵞ</big> ... can have, 0 and itself included, is
-<big>(α + 1)(β+ 1)(γ + 1)</big>.... For <big><i>a</i><sup>α</sup></big>
-as the divisors <big>1, <i>a</i>, <i>a</i>² ... <i>a</i><sup>α</sup></big>
-and no others, α + 1 in all. Similarly, <big><i>b</i>ᵝ</big> has β+ 1 divisors, and so
-on. Now as all the divisors are made by multiplying together one out of each
-set, their number (page 202) is <big>(α + 1)(β + 1)(γ+ 1)</big>....</p>
-
-<p>If a number, <i>n</i>, be divisible by certain prime numbers, say 3,
-5, 7, 11, then the third part of all the numbers up to <i>n</i> is
-divisible by 3, the fifth part by 5, and so on. But more than this:
-when the multiples of 3 are omitted, exactly the fifth part of <i>those
-which remain</i> are divisible by 5; for the fifth part of the whole
-are divisible by 5, and the fifth part of those which are removed
-are divisible by 5, therefore the fifth part of those which are left
-are divisible by 5. Again, because the seventh part of the whole are
-divisible by 7, and the seventh part of those which are divisible by 3,
-or by 5, or by 15, it follows that when all those which are multiples
-of 3 or 5, or both, are removed, the seventh part of those which
-remain are divisible by 7; and so on. Hence, the number of numbers not
-exceeding n, which are not divisible by 3, 5, 7, or 11, is <big>¹⁰/₁₁</big>
-of <big>⁶/₇</big> of <big>⁴/₅</big> of ²<big>/₃</big> of n. Proceeding in
-this way, we find that the number of numbers which are prime to
-<i>n</i>, that is, which are not divisible by any one of its prime
-factors, <i>a</i>, <i>b</i>, <i>c</i>, ... is</p>
-
-<table class="fontsize_110 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><big><i>n</i></big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i> -1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i> - 1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>c</i> - 1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;...</td>
- </tr><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>c</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="f110">or <i>a</i><sup>α-1</sup><i>b</i><sup>β-1</sup><i>c</i><sup>γ-1</sup> ...
-(<i>a</i> - 1)(<i>b</i> - 1)(<i>c</i> - 1)....</p>
-
-<p class="no-indent">Thus, 360 being 2³3²5, its number of divisors is 4 × 3 × 2,
-or 24, and there are 2³3.1.2.4 or 96 numbers less than 360 which are prime to it.</p>
-
-<p id="PROP_5"><b><span class="smcap">Prop. 5.</span></b> If <i>a</i> be prime to <i>b</i>, then the terms
-of the series, <i>a</i>, <i>a</i>², <i>a</i>³, ... severally divided by
-<i>b</i>, must all leave different remainders, until 1 occurs as a
-remainder, after which the cycle of remainders will be again repeated.</p>
-
-<p>Let <i>a</i> + <i>b</i> give the remainder <i>r</i> (not unity); then
-<i>a</i>² ÷ <i>b</i> gives the same remainder as <i>r</i><i>a</i> +
-<i>b</i>, which (<a href="#PROP_4"><b>Prop. 4</b></a>) cannot be <i>r</i>: let it be <i>s</i>.
-<span class="pagenum" id="Page_197">[Pg 197]</span>
-Then <i>a</i>ˢ ÷ <i>b</i> gives the same remainder as <i>s</i><i>a</i>
-÷ <i>b</i>, which (<b><a href="#PROP_4">Prop. 4</a></b>) cannot be either <i>r</i>
-or <i>s</i>, unless <i>s</i> be 1: let it be <i>t</i>. Then <i>a</i>ᵗ ÷ <i>b</i>
-gives the same remainder as <i>ta</i> ÷ <i>b</i>; if <i>t</i> be not
-1, this cannot be either <i>r</i>, <i>s</i>, or <i>t</i>: let it be
-<i>u</i>. So we go on getting different remainders, until 1 occurs as
-a remainder; after which, at the next step, the remainder of <i>a</i>
-÷ <i>b</i> is repeated. Now, 1 must come at last; for division by
-<i>b</i> cannot give any remainders but 0, 1, 2, ... <i>b</i>-
-1; and 0 never arrives (<b><a href="#PROP_3">Prop. 3</a></b>), so that as soon as
-<i>b</i>-2 <i>different</i> remainders have occurred, no one of which is unity,
-the next, which must be different from all that precede, must be 1. If
-not before, then at <i>a</i>ᵇ⁻¹ we must have a remainder 1; after which
-the cycle will obviously be repeated.</p>
-
-<p>Thus, 7, 7², 7³, 7⁴, &amp;c. will, when divided by 5, be found to give
-the remainders 2, 4, 3, 1, &amp;c.</p>
-
-<p id="PROP_6"><b><span class="smcap">Prop. 6.</span></b> The difference of two
-<i>m</i>th powers is always divisible without remainder by the
-difference of the roots; or <i>a</i>ᵐ -<i>b</i>ᵐ is divisible by
-<i>a</i>-<i>b</i>; for</p>
-
-<p class="f120"><i>a</i>ᵐ - <i>b</i>ᵐ = <i>a</i>ᵐ - <i>a</i>ᵐ⁻¹<i>b</i> + <i>a</i>ᵐ⁻¹<i>b</i> - <i>b</i>ᵐ</p>
-<p class="f120"><span class="ws4">= <i>a</i>ᵐ⁻¹(<i>a</i> - <i>b</i>) + <i>b</i>(<i>a</i>ᵐ⁻¹ - <i>b</i>ᵐ⁻¹)</span></p>
-
-<p class="no-indent">From which, if <big><i>aᵐ⁻¹</i>-<i>bᵐ⁻¹</i></big> is divisible
-by <i>a</i> - <i>b</i>, so is <big><i>a</i>ᵐ-<i>b</i>ᵐ</big>. But <i>a</i> - <i>b</i>
-is divisible by <i>a</i> - <i>b</i>; so therefore is <big><i>a</i>²- <i>b</i>²</big>;
-so therefore is <big><i>a</i>³-<i>b</i>³</big>; and so on.</p>
-
-<p>Therefore, if <i>a</i> and <i>b</i>, divided by <i>c</i>, leave the
-same remainder, <i>a</i>² and <i>b</i>², <i>a</i>³ and <i>b</i>³,
-&amp;c. severally divided by <i>c</i>, leave the same remainders;
-for this means that <i>a</i> - <i>b</i> is divisible by <i>c</i>.
-But <i>a</i>ᵐ - <i>b</i>ᵐ is divisible by <i>a</i> - <i>b</i>, and
-therefore by every measure of <i>a</i>-<i>b</i>, or by <i>c</i>; but
-<big><i>a</i>ᵐ - <i>b</i>ᵐ</big> cannot be divisible by <i>c</i>, unless <big><i>a</i>ᵐ</big>
-and <big><i>b</i>ᵐ</big>, severally divided by <i>c</i>, give the same remainder.</p>
-
-<p id="PROP_7"><b><span class="smcap">Prop. 7.</span></b> If <i>b</i> be a prime
-number, and <i>a</i> be not divisible by <i>b</i>, then <big><i>a</i>ᵇ</big> and
-<big>(<i>a</i>-1)ᵇ + 1</big> leave the same remainder when divided by
-<i>b</i>. This proposition cannot be proved here, as it requires a
-little more of algebra than the reader of this work possesses.<a id="FNanchor_64" href="#Footnote_64" class="fnanchor">[64]</a></p>
-
-<p id="PROP_8"><span class="pagenum" id="Page_198">[Pg 198]</span>
-<b><span class="smcap">Prop. 8.</span></b> In the last case, <big><i>a</i>ᵇ⁻¹</big> divided
-by <i>b</i> leaves a remainder 1. From the last, <i>a</i>ᵇ-<i>a</i> leaves the
-same remainder as <big>(<i>a</i>-1)ᵇ + 1-<i>a</i></big> or <big>(<i>a</i>-1)ᵇ-
-(<i>a</i>-1)</big>; that is, the remainder of <big><i>a</i>ᵇ - <i>a</i></big> is not
-altered if <i>a</i> be reduced by a unit. By the same rule, it may be
-reduced another unit, and so on, still without any alteration of the
-remainder. At last it becomes <big>1ᵇ-1</big>, or 0, the remainder of which is
-0. Accordingly, <big><i>a</i>ᵇ - <i>a</i></big>, which is <big><i>a</i>(<i>a</i>ᵇ⁻¹- 1)</big>,
-is divisible by <i>b</i>; and since <i>b</i> is prime to <i>a</i>,
-it must (<b><a href="#PROP_2">Prop. 2</a></b>) divide <big><i>a</i>ᵇ⁻¹-1</big>; that is,
-<big><i>a</i>ᵇ⁻¹</big>, divided by <i>b</i>, leaves a remainder 1, if <i>b</i> be a prime
-number and <i>a</i> be not divisible by <i>b</i>.</p>
-
-<p>From the above it appears (<b><a href="#PROP_5">Prop. 5</a> and <a href="#PROP_7">7</a></b>),
-that if <i>a</i> be prime to <i>b</i>, the set 1, <i>a</i>, <i>a</i>², <i>a</i>³,
-&amp;c. successively divided by <i>b</i>, give a set of remainders beginning
-with 1, and in which 1 occurs again at <i>a</i>ᵇ⁻¹, if not before, and
-at <i>a</i>ᵇ⁻¹ certainly (whether before or not), if <i>b</i> be a
-prime number. From the point at which 1 occurs, the cycle of remainders
-recommences, and 1 is always the beginning of a cycle. If, then,
-<i>a</i>ᵐ be the first power which gives 1 for remainder, <i>m</i>
-must either be <i>b</i>-1, or a measure of it, <i>when b is a prime
-number</i>.</p>
-
-<p>But if we divide the terms of the series <big><i>m</i>, <i>ma</i>,
-<i>ma</i>², <i>ma</i>³</big>, &amp;c. by <i>b</i>, <i>m</i> being less than
-<i>b</i>, we have cycles of remainders beginning with <i>m</i>. If 1,
-<i>r</i>, <i>s</i>, <i>t</i>, &amp;c. be the first set of remainders,
-then the second set is the set of remainders arising from <i>m</i>,
-<i>mr</i>, <i>ms</i>, <i>mt</i>, &amp;c. If 1 never occur in the first
-set before <big><i>a</i>ᵇ⁻¹</big> (except at the beginning), then all the
-numbers under <i>b</i>-1 inclusive are found among the set 1, <i>r</i>,
-<i>s</i>, <i>t</i>, &amp;c.; and if <i>m</i> be prime to <i>b</i>
-(<b><a href="#PROP_4">Prop. 4</a></b>), all the same numbers are found,
-in a different order, among the remainders of <i>m</i>, <i>mr</i>,
-&amp;c. But should it happen that the set 1, <i>r</i>, <i>s</i>,
-<i>t</i>, &amp;c. is not complete, then <i>m</i>, <i>mr</i>, <i>ms</i>,
-&amp;c. may give a different set of remainders.</p>
-
-<p>All these last theorems are constantly verified in the process for
-reducing a fraction to a decimal fraction. If <i>m</i> be prime to
-<i>b</i>, or the fraction <i>m</i>/<i>b</i> in its lowest terms, the
-process involves the successive division of <i>m</i>, <i>m</i> × 10,
-<i>m</i> × 10², &amp;c. by <i>b</i>. This process can never come to
-an end unless some power of 10, say 10ⁿ, is divisible by <i>b</i>;
-which cannot be, if <i>b</i> contain any prime factors except 2 and 5.
-In every other case the quotient repeats itself, the repeating part
-sometimes commencing from the first figure, sometimes from a later
-<span class="pagenum" id="Page_199">[Pg 199]</span>
-figure. Thus, ¹/₇ yields ·142857142857, &amp;c., but <big>¹/₁₄</big> gives
-·07(142857)(142857), &amp;c., and <big>¹/₂₈</big> gives ·03(571428)(571428),
-&amp;c.</p>
-
-<p>In <i>m</i>/<i>b</i>, the quotient always repeats from the very
-beginning whenever <i>b</i> is a prime number and <i>m</i> is less
-than <i>b</i>; and the number of figures in the repeating part is then
-always <i>b</i>-1, or a measure of it. That it must be so, appears
-from the above propositions.</p>
-
-<p>Before proceeding farther, we write down the repeating part of a
-quotient, with the remainders which are left after the several figures
-are formed. Let the fraction be <big>¹/₁₇</big>, we have</p>
-
-<p class="f120">0₁₀5₁₅8₁₄8₄2₆3₉5₅2₁₆9₇4₂1₃1₁₃7₁₁6₈4₁₂7₁</p>
-
-<p class="no-indent">This may be read thus: 10 by 17, quotient 0, remainder 10;
-10² by 17, quotient 05, remainder 15; 10³ by 17, quotient 058, remainder 14; and
-so on. It thus appears that 10¹⁶ by 17 leaves a remainder 1, which is
-according to the theorem.</p>
-
-<p>If we multiply 0588, &amp;c. by <i>any number under</i> 17, the same
-cycle is obtained with a different beginning. Thus, if we multiply by
-13, we have</p>
-
-<p class="f120">7647058823529411</p>
-
-<p class="no-indent">beginning with what comes after remainder 13 in
-the first number. If we multiply by 7, we have 4117, &amp;c. The reason
-is obvious: ¹/₁₇ × 13, or ¹³/₁₇, when turned into a decimal fraction,
-starts with the divisor 130, and we proceed just as we do in forming
-¹/₁₇, when within four figures of the close of the cycle.</p>
-
-<p>It will also be seen, that in the last half of the cycle the quotient
-figures are complements to 9 of those in the first half, and that the
-remainders are complements to 17. Thus, in 0₁₀5₁₅8₁₄8₄, &amp;c. and
-9₇4₂1₃1₁₃, &amp;c. we see 0 + 9 = 9, 5 + 4 = 9, 8 + 1 = 9, &amp;c.,
-and 10 + 7 = 17, 15 + 2 = 17, 14 + 3 = 17, &amp;c. We may shew the
-necessity of this as follows: If the remainder 1 never occur till we
-come to use <big><i>a</i>ᵇ⁻¹</big>, then, <i>b</i> being prime, <i>b</i>-1 is
-even; let it be 2<i>k</i>. Accordingly, <big><i>a</i>²ᵏ-1</big> is divisible by
-<i>b</i>; but this is the product of <big><i>a</i>ᵏ-1</big> and <big><i>a</i>ᵏ + 1</big>,
-one of which must be divisible by <i>b</i>. It cannot be <big><i>a</i>ᵏ - 1</big>,
-for then a power of <i>a</i> preceding the (<i>b</i> - 1)th would leave
-remainder 1, which is not the case in our instance: it must then be
-<big><i>a</i>ᵏ + 1</big>, so that <big><i>a</i>ᵏ</big> divided by <i>b</i> leaves a remainder
-<span class="pagenum" id="Page_200">[Pg 200]</span>
-<i>b</i>-1; and the <i>k</i>th step concludes the first half of the process. Accordingly,
-in our instance, we see, <i>b</i> being 17 and <i>a</i> being 10, that remainder 16
-occurs at the 8th step of the process. At the next step, the remainder
-is that yielded by 10(<i>b</i>-1), or 9<i>b</i> + <i>b</i> - 10, which gives the remainder <i>b</i>-10.
-But the first remainder of all was 10, and 10 + (<i>b</i> - 10) = <i>b</i>. If ever this
-complemental character occur in any step, it must continue, which we
-shew as follows: Let <i>r</i> be a remainder, and <i>b</i> - <i>r</i> a subsequent remainder,
-the sum being <i>b</i>. At the next step after the first remainder, we divide
-10<i>r</i> by <i>b</i>, and, at the next step after the second remainder, we divide
-10<i>b</i> - 10<i>r</i> by <i>b</i>. Now, since the sum of 10<i>r</i> and 10<i>b</i> - 10<i>r</i> is divisible
-by <i>b</i>, the two remainders from these new steps must be such as added
-together will give <i>b</i>, and so on; and the <i>quotients</i> added together must
-give 9, for the sum of the remainders 10<i>r</i> and 10<i>b</i> - 10<i>r</i> yields a quotient
-10, of which the two remainders give 1.</p>
-
-<p>If <big>¹/₅₉</big> and <big>¹/₆₁</big> be taken, the repeating parts will be found
-to contain 58 and 60 figures. Of these we write down only the first halves, as the
-reader may supply the rest by the complemental property just given.</p>
-
-<p class="f120">01694915254237288135593220338, &amp;c.<br />
-016393442622950819672131147540, &amp;c.</p>
-
-<p class="no-indent">Here, then, are two numbers, the first of which multiplied
-by any number under 59, and the second by any number under 61, can have the
-products formed by carrying certain of the figures from one end to the other.</p>
-
-<p>But, <i>b</i> being still prime, it may happen that remainder 1 may
-occur before <i>b</i> - 1 figures are obtained; in which case, as
-shewn, the number of figures must be a measure of <i>b</i> - 1. For
-example, take ¹/₄₁. The repeating quotient, written as above, has only
-5 figures, and 5 measures 41 - 1.</p>
-
-<p class="f120">0₁₀2₁₈4₁₆3₃₇9₁</p>
-
-<p class="no-indent">Now, this period, it will be found, has its figures merely
-transposed, if we multiply by 10, 18, 16, or 37. But if we multiply by any other
-number under 41, we convert this period into the period of another
-<span class="pagenum" id="Page_201">[Pg 201]</span>
-fraction whose denominator is 41. The following are 8 periods which may
-be found.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" rules="cols" >
- <tbody><tr>
- <td class="tdl">0₁₀2₁₈4₁₆3₃₇9₁&nbsp;&nbsp;&nbsp;</td>
- <td class="tdl_ws1">1₉2₈1₃₉9₂₁5₅</td>
- </tr><tr>
- <td class="tdl">0₂₀4₃₆8₃₂7₃₃8₂</td>
- <td class="tdl_ws1">1₁₉4₂₆6₁₄3₁₇4₆</td>
- </tr><tr>
- <td class="tdl">0₃₀7₁₃3₇1₂₉7₃</td>
- <td class="tdl_ws1">2₂₈6₃₄8₁₂2₃₈9₁₁</td>
- </tr><tr>
- <td class="tdl">0₄₀9₈₁7₂₃5₂₅6₄</td>
- <td class="tdl_ws1">3₂₇6₂₄5₃₅8₂₂5₁₅</td>
- </tr>
- </tbody>
-</table>
-
-<p>To find <big><i>m</i>/41</big>, look out for <i>m</i> among the remainders,
-and take the period in which it is, beginning after the remainder. Thus,
-<big>³⁴/₄₁</big> is ·8292682926, &amp;c., and <big>¹⁵/₄₁</big> is ·3658536585, &amp;c.
-These periods are complemental, four and four, as 02439 and 97560, 07317 and
-92682, &amp;c. And if the first number, 02439, be multiplied by any
-number under 41, look for that number among the remainders, and the
-product is found in the period of that remainder by beginning after the
-remainder. Thus, 02439 multiplied by 23 gives 56097, and by 6 gives 14634.</p>
-
-<p>The reader may try to decipher for himself how it is that, with no more
-figures than the following, we can extend the result of our division.
-The fraction of which the period is to be found is <big>¹/₈₇</big>.</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2">87)100(01149425</li>
-<li class="isub3-5">130</li>
-<li class="isub4">430</li>
-<li class="isub4-5">820<span class="ws6-5">01149425 × 25</span></li>
-<li class="isub5">370<span class="ws6-5">28735625 × 25</span></li>
-<li class="isub5-5">220<span class="ws6-5">718390625 × 25</span></li>
-<li class="isub6">460<span class="ws6-5">17959765625 × 25</span></li>
-<li class="isub6-5">25<span class="ws7">448994140625</span></li>
-<li class="isub3">0114942528735625</li>
-<li class="isub10-5">718390625</li>
-<li class="isub13-5">1795976 5625</li>
-<li class="isub17-5">448994</li>
-<li class="isub3-5 over">0114942528735632183908045977<b>|</b>011494</li>
-<li class="isub17-5"><b>|</b></li>
-</ul>
-
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_X">APPENDIX X.<br />
-<span class="h_subtitle">ON COMBINATIONS.</span></h3>
-</div>
-
-<p>There are some things connected with combinations which I place in an
-appendix, because I intend to demonstrate them more briefly than the
-matters in the text.
-<span class="pagenum" id="Page_202">[Pg 202]</span></p>
-
-<p>Suppose a number of boxes, say 4, in each of which there are counters,
-say 5, 7, 3, and 11 severally. In how many ways can one counter be
-taken out of each box, the order of going to the boxes not being
-regarded. <i>Answer</i>, in 5 × 7 × 3 × 11 ways. For out of the first
-box we may draw a counter in 5 different ways, and to each such drawing
-we may annex a drawing from the second in 7 different ways&mdash;giving 5 ×
-7 ways of making a drawing from the first two. To each of these we may
-annex a drawing from the third box in 3 ways&mdash;giving 5 × 7 × 3 drawings
-from the first three; and so on. The following statements may now be
-easily demonstrated, and similar ones made as to other cases.</p>
-
-<p>If the order of going to the boxes make a difference, and if <i>a</i>,
-<i>b</i>, <i>c</i>, <i>d</i> be the numbers of counters in the several
-boxes, there are 4 × 2 × 3 × 1 × <i>a</i> × <i>b</i> × <i>c</i> ×
-<i>d</i> distinct ways. If we want to draw, say 2 out of the first box,
-3 out of the second, 1 out of the third, and 3 out of the fourth, and
-if the order of the boxes be not considered, the number of ways is</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><big><i>a</i></big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>a</i> -1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp; × &nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i> - 1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>b</i> - 2&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;× <big><i>c</i></big> × <big><i>d</i></big>&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i> - 1&nbsp;</td>
- <td class="tdc" rowspan="2">&nbsp;</td>
- <td class="tdc u">&nbsp;<i>d</i> - 2&nbsp;</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">If the order of going to the boxes be considered,
-we must multiply the preceding by 4 × 3 × 2 × 1. If the order of the
-drawings out of the boxes makes a difference, but not the order of the
-boxes, then the number of ways is</p>
-
-<p class="f110"><i>a</i>(<i>a</i>-1)<i>b</i>(<i>b</i>-1)(<i>b</i>-2)<i>cd</i>(<i>d</i>-1)(<i>d</i>-2)</p>
-
-<p>The nth power of <i>a</i>, or <i>a</i>ⁿ, represents the number of
-ways in which <i>a</i> counters <i>differently marked</i> can be
-distributed in <i>n</i> boxes, order of placing them in each box not
-being considered. Suppose we want to distribute 4 differently-marked
-counters among 7 boxes. The first counter may go into either box,
-which gives 7 ways; the second counter may go into either; and any of
-the first 7 allotments may be combined with any one of the second 7,
-giving 7 × 7 distinct ways; the third counter varies each of these in 7
-different ways, giving 7 × 7 × 7 in all; and so on. But if the counters
-be undistinguishable, the problem is a very different thing.</p>
-
-<p>Required the number of ways in which a number can be compounded of
-<span class="pagenum" id="Page_203">[Pg 203]</span>
-other numbers, different orders counting as different ways. Thus, 1 +
-3 + 1 and 1 + 1 + 3 are to be considered as distinct ways of making 5.
-It will be obvious, on a little examination, that each number can be
-composed in exactly twice as many ways as the preceding number. Take
-8 for instance. If every possible way of making 7 be written down, 8
-may be made either by increasing the last component by a unit, or by
-annexing a unit at the end. Thus, 1 + 3 + 2 + 1 may yield 1 + 3 + 2
-+ 2, or 1 + 3 + 2 + 1 + 1: and all the ways of making 8 will thus be
-obtained; for any way of making 8, say <i>a</i> + <i>b</i> + <i>c</i>
-+ <i>d</i>, must proceed from the following mode of making 7, <i>a</i>
-+ <i>b</i> + <i>c</i> + (<i>d</i> - 1). Now, (<i>d</i> - 1) is either
-0&mdash;that is, <i>d</i> is unity and is struck out&mdash;or (<i>d</i> - 1)
-remains, a number 1 less than <i>d</i>. Hence it follows that the
-number of ways of making <i>n</i> is <big>2ⁿ⁻¹</big>. For there is obviously 1 way
-of making 1, 2 of making 2; then there must be, by our rule, 2² ways of
-making 3, 2³ ways of making 4; and so on.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="9">&nbsp;1&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdc" rowspan="4"><img src="images/cbl-4.jpg" alt="" width="23" height="82" /></td>
- <td class="tdl">1 + 1 + 1 + 1</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdc" rowspan="3"><img src="images/cbl-3.jpg" alt="" width="16" height="57" /></td>
- <td class="tdl">1 + 1 + 1&nbsp;</td>
- <td class="tdl">1 + 1 + 2</td>
- </tr><tr>
- <td class="tdc" rowspan="5"><img src="images/cbl-5.jpg" alt="" width="30" height="107" /></td>
- <td class="tdc">1 + 1&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">1 + 2 + 1</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">1 + 2</td>
- <td class="tdl">1 + 3</td>
- </tr><tr>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc" rowspan="3"><img src="images/cbl-3.jpg" alt="" width="16" height="57" /></td>
- <td class="tdl">2 + 1</td>
- <td class="tdc" rowspan="4"><img src="images/cbl-4.jpg" alt="" width="23" height="82" /></td>
- <td class="tdl">2 + 1 + 1</td>
- </tr><tr>
- <td class="tdl">2</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">2 + 2</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl">3</td>
- <td class="tdl">3 + 1</td>
- </tr><tr>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdl">4</td>
- </tr>
- </tbody>
-</table>
-
-<p>This table exhibits the ways of making 1, 2, 3, and 4. Hence it follows
-(which I leave the reader to investigate) that there are twice as many
-ways of forming <i>a</i> + <i>b</i> as there are of forming <i>a</i>
-and then annexing to it a formation of <i>b</i>; four times as many
-ways of forming <i>a</i> + <i>b</i> + <i>c</i> as there are of annexing
-to a formation of <i>a</i> formations of <i>b</i> and of <i>c</i>; and
-so on. Also, in summing numbers which make up <i>a</i> + <i>b</i>,
-there are ways in which <i>a</i> is a rest, and ways in which it is
-not, and as many of one as of the other.</p>
-
-<p>Required the number of ways in which a number can be compounded of
-odd numbers, different orders counting as different ways. If <i>a</i>
-be the number of ways in which <i>n</i> can be so made, and <i>b</i>
-the number of ways in which <i>n</i> + 1 can be made, then <i>a</i> +
-<i>b</i> must be the number of ways in which <i>n</i> + 2 can be made;
-for every way of making 12 out of odd numbers is either a way of making
-<span class="pagenum" id="Page_204">[Pg 204]</span>
-10 with the last number increased by 2, or a way of making 11 with a 1
-annexed. Thus, 1 + 5 + 3 + 3 gives 12, formed from 1 + 5 + 3 + 1 giving
-10. But 1 + 9 + 1 + 1 is formed from 1 + 9 + 1 giving 11. Consequently,
-the number of ways of forming 12 is the sum of the number of ways of
-forming 10 and of forming 11. Now, 1 can only be formed in 1 way, and 2
-can only be formed in 1 way; hence 3 can only be formed in 1 + 1 or 2
-ways, 4 in only 1 + 2 or 3 ways. If we take the series 1, 1, 2, 3, 5,
-8, 13, 21, 34, 55, 89, &amp;c. in which each number is the sum of the
-two preceding, then the <i>n</i>th number of this set is the number of
-ways (orders counting) in which <i>n</i> can be formed of odd numbers.
-Thus, 10 can be formed in 55 ways, 11 in 89 ways, &amp;c.</p>
-
-<p>Shew that the number of ways in which <i>mk</i> can be made of numbers
-divisible by <i>m</i> (orders counting) is 2ᵏ⁻¹.</p>
-
-<p class="center">In the two series, 1 1 1 2 3 4 6 9 13 19 28, &amp;c.<br />
-<span class="ws8">   0 1 0 1 1 1 2 2   3   4   5, &amp;c.,</span></p>
-
-<p class="no-indent">the first has each new term after the third equal
-to the sum of the last and last but two; the second has each new term
-after the third equal to the sum of the last but one and last but two.
-Shew that the <i>n</i>th number in the first is the number of ways in
-which <i>n</i> can be made up of numbers which, divided by 3, leave a
-remainder 1; and that the <i>n</i>th number in the second is the number
-of ways in which <i>n</i> can be made up of numbers which, divided by
-3, leave a remainder 2.</p>
-
-<p>It is very easy to shew in how many ways a number can be made up of
-a given number of numbers, if different orders count as different
-ways. Suppose, for instance, we would know in how many ways 12 can
-be thus made of 7 numbers. If we write down 12 units, there are 11
-intervals between unit and unit. There is no way of making 12 out of 7
-numbers which does not answer to distributing 6 partition-marks in the
-intervals, 1 in each of 6, and collecting all the units which are not
-separated by partition-marks. Thus, 1 + 1 + 3 + 2 + 1 + 2 + 2, which is
-one way of making 12 out of 7 numbers, answers to</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc br">1&nbsp;</td>
- <td class="tdc br">&nbsp;1&nbsp;</td>
- <td class="tdc br">&nbsp;111&nbsp;</td>
- <td class="tdc br">&nbsp;11&nbsp;</td>
- <td class="tdc br">&nbsp;1&nbsp;</td>
- <td class="tdc br">&nbsp;11&nbsp;</td>
- <td class="tdc">&nbsp;11</td>
- </tr><tr>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_205">[Pg 205]</span>
-in which the partition-marks come in the 1st, 2d, 5th, 7th, 8th, and
-10th of the 11 intervals. Consequently, to ask in how many ways 12 can
-be made of 7 numbers, is to ask in how many ways 6 partition-marks can
-be placed in 11 intervals; or, how many combinations or selections can
-be made of 6 out of 11. The answer is,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc u">11 × 10 × 9 × 8 × 7 × 6</td>
- <td class="tdc" rowspan="2">,&nbsp; or 462.</td>
- </tr><tr>
- <td class="tdc">1 × 2 × 3 × 4 × 5 × 6</td>
- </tr>
- </tbody>
-</table>
-
-<p>Let us denote by <i>m</i>ₙ the number of ways in which <i>m</i>
-things can be taken out of <i>n</i> things, so that <i>m</i>ₙ is the
-abbreviation for</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary="" cellpadding="0" >
- <tbody><tr>
- <td class="tdc" rowspan="2"><i>n</i> ×&nbsp;</td>
- <td class="tdc u"><i>n</i> - 1</td>
- <td class="tdc" rowspan="2">&nbsp;×&nbsp;</td>
- <td class="tdc u"><i>n</i> - 2</td>
- <td class="tdc" rowspan="2">&nbsp;... as far as&nbsp;</td>
- <td class="tdc u"><i>n</i> - <i>m</i> + 1</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- <td class="tdc"><i>m</i></td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Then <i>m</i>ₙ also represents the number of ways
-in which <i>m</i> + 1 numbers can be put together to make <i>n</i> + 1.
-What we proved above is, that 6₁₁ is the number of ways in which we can
-put together 7 numbers to make 12. There will now be no difficulty in
-proving the following:</p>
-
-<p class="f120">2ⁿ = 1 + 1ₙ + 2ₙ + 3ₙ ... + <i>n</i>ₙ</p>
-
-<p>In the preceding question, 0 did not enter into the list of numbers
-used. Thus, 3 + 1 + 0 + 0 was not considered as one of the ways of
-putting together four numbers to make 5. But let us now ask, what is
-the number of ways of putting together 7 numbers to make 12, allowing
-0 to be in the list of numbers. There can be no more (nor fewer)
-ways of doing this than of putting 7 numbers together, among which 0
-is <i>not</i> included, to make 19. Take every way of making 12 (0
-included), and put on 1 to each number, and we get a way of making
-19 (0 not included). Take any way of making 19 (0 not included), and
-strike off 1 from each number, and we have one of the ways of making
-12 (0 included). Accordingly, 6₁₈ is the number of ways of putting
-together 7 numbers (0 being allowed) to make 12. And (<i>m</i>-
-1)ₙ₊ₘ₋₁ is the number of ways of putting together <i>m</i> numbers to
-make <i>n</i>, 0 being included.</p>
-
-<p>This last amounts to the solution of the following: In how many
-ways can <i>n</i> counters (undistinguishable from each other) be
-distributed into <i>m</i> boxes? And the following will now be easily
-proved: The number of ways of distributing <i>c</i> undistinguishable
-<span class="pagenum" id="Page_206">[Pg 206]</span>
-counters into <i>b</i> boxes is <big>(<i>b</i> - 1)<sub><i>b</i> + <i>c</i> -
-1</sub></big>, if any box or boxes may be left empty. But if there must be 1 at
-least in each box, the number of ways is <big>(<i>b</i> - 1)<sub><i>c</i> - 1</sub></big>;
-if there must be 2 at least in each box, it is <big>(<i>b</i> - 1)<sub><i>c-
-b</i>-1</sub></big>; if there must be 3 at least in each box, it is
-<big>(<i>b</i> - 1)<sub><i>c</i> - 2<i>b</i> - 1</sub></big>; and so on.</p>
-
-<p>The number of ways in which <i>m odd</i> numbers can be put together to
-make <i>n</i>, is the same as the number of ways in which <i>m</i> even
-numbers (0 included) can be put together to make <i>n</i>-<i>m</i>;
-and this is the number of ways in which <i>m</i> numbers (odd or
-even, 0 included) can be put together to make ½(<i>n</i>-<i>m</i>).
-Accordingly, the number of ways in which m odd numbers can be put
-together to make <i>n</i> is the same as the number of combinations of
-<i>m</i>-1 things out of ½(<i>n</i>-<i>m</i>) + <i>m</i>-1, or
-½(<i>n</i> + <i>m</i>)-1. Unless <i>n</i> and <i>m</i> be both even
-or both odd, the problem is evidently impossible.</p>
-
-<p>There are curious and useful relations existing between numbers of
-combinations, some of which may readily be exhibited, under the simple
-expression of <i>m</i>ₙ to stand for the number of ways in which
-<i>m</i> things may be taken out of <i>n</i>. Suppose we have to take
-5 out of 12: Let the 12 things be marked <span class="smcap">a, b, c</span>, &amp;c. and
-set apart one of them, <span class="allsmcap">a</span>. Every collection of 5 out of the 12
-either does or does not include <span class="allsmcap">a</span>. The number of the latter
-sort must be 5₁₁; the number of the former sort must be 4₁₁, since it
-is the number of ways in which the <i>other four</i> can be chosen out
-of all but <span class="allsmcap">a</span>. Consequently, 5₁₂ must be 5₁₁ + 4₁₁, and thus we
-prove in every case,</p>
-
-<p class="f120"><i>m</i>ₙ′ = <i>m</i>ₙ₋₁ + (<i>m</i> - 1)ₙ₋₁</p>
-
-<p class="no-indent">0ₙ and <i>n</i>ₙ both are 1; for there is but one way of taking
-<i>none</i>, and but one way of taking <i>all</i>. And again <i>m</i>ₙ
-and (<i>n</i>-<i>m</i>)ₙ are the same things. And if <i>m</i> be
-greater than <i>n</i>, <i>m</i>ₙ is 0; for there are no ways of doing
-it. We make one of our preceding results more symmetrical if we write
-it thus,</p>
-
-<p class="f120">2ⁿ = 0ₙ + 1ₙ + 2ₙ + ... + <i>n</i>ₙ</p>
-
-<p>If we now write down the table of symbols in which the (<i>m</i> + 1)th
-<span class="pagenum" id="Page_207">[Pg 207]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl">&nbsp;</td>
- <td class="tdl_ws1 bb">0</td>
- <td class="tdl_ws1 bb">1</td>
- <td class="tdl_ws1 bb">2</td>
- <td class="tdl_ws1 bb">3</td>
- <td class="tdl_ws1 bb">&amp;c.</td>
- </tr><tr>
- <td class="tdl br">1</td>
- <td class="tdl_ws1">0₁</td>
- <td class="tdl_ws1">1₁</td>
- <td class="tdl_ws1">2₁</td>
- <td class="tdl_ws1">3₁,</td>
- <td class="tdl_ws1">&amp;c.</td>
- </tr><tr>
- <td class="tdl br">2</td>
- <td class="tdl_ws1">0₂</td>
- <td class="tdl_ws1">1₂</td>
- <td class="tdl_ws1">2₂</td>
- <td class="tdl_ws1">3₂,</td>
- <td class="tdl_ws1">&amp;c.</td>
- </tr><tr>
- <td class="tdl br">3</td>
- <td class="tdl_ws1">0₃</td>
- <td class="tdl_ws1">1₃</td>
- <td class="tdl_ws1">2₃</td>
- <td class="tdl_ws1">3₃,</td>
- <td class="tdl_ws1">&amp;c.</td>
- </tr><tr>
- <td class="tdl br">&amp;c.&nbsp;</td>
- <td class="tdl_ws1">&amp;c.</td>
- <td class="tdl_ws1">&amp;c.</td>
- <td class="tdl_ws1">&amp;c.</td>
- <td class="tdl_ws1">&amp;c.</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">number of the <i>n</i>th row represents <i>m</i>ₙ,
-the number of combinations of <i>m</i> out of <i>n</i>, we see it
-proved above that the law of formation of this table is as follows:
-Each number is to be the sum of the number above it and the number
-preceding the number above it. Now, the first row must be 1, 1, 0, 0,
-0, &amp;c. and the first column must be 1, 1, 1, 1, &amp;c. so that we
-have a table of the following kind, which may be carried as far as we please:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdr_ws1 bb">0</td>
- <td class="tdr_ws1 bb">1</td>
- <td class="tdr_ws1 bb">2</td>
- <td class="tdr_ws1 bb">3</td>
- <td class="tdr_ws1 bb">4</td>
- <td class="tdr_ws1 bb">5</td>
- <td class="tdr_ws1 bb">6</td>
- <td class="tdr_ws1 bb">7</td>
- <td class="tdr_ws1 bb">8</td>
- <td class="tdr_ws1 bb">9</td>
- <td class="tdr_ws1 bb">10</td>
- </tr><tr>
- <td class="tdr br">1&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">2&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">2</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">3&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">3</td>
- <td class="tdr_ws1">3</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">4&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">4</td>
- <td class="tdr_ws1">6</td>
- <td class="tdr_ws1">4</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">5&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">5</td>
- <td class="tdr_ws1">10</td>
- <td class="tdr_ws1">10</td>
- <td class="tdr_ws1">5</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">6&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">6</td>
- <td class="tdr_ws1">15</td>
- <td class="tdr_ws1">20</td>
- <td class="tdr_ws1">15</td>
- <td class="tdr_ws1">6</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">7&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">7</td>
- <td class="tdr_ws1">21</td>
- <td class="tdr_ws1">35</td>
- <td class="tdr_ws1">35</td>
- <td class="tdr_ws1">21</td>
- <td class="tdr_ws1">7</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">8&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">8</td>
- <td class="tdr_ws1">28</td>
- <td class="tdr_ws1">56</td>
- <td class="tdr_ws1">70</td>
- <td class="tdr_ws1">56</td>
- <td class="tdr_ws1">28</td>
- <td class="tdr_ws1">8</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">9&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">9</td>
- <td class="tdr_ws1">36</td>
- <td class="tdr_ws1">84</td>
- <td class="tdr_ws1">126</td>
- <td class="tdr_ws1">126</td>
- <td class="tdr_ws1">84</td>
- <td class="tdr_ws1">36</td>
- <td class="tdr_ws1">9</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- </tr><tr>
- <td class="tdr br">10&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">10</td>
- <td class="tdr_ws1">45</td>
- <td class="tdr_ws1">120</td>
- <td class="tdr_ws1">210</td>
- <td class="tdr_ws1">252</td>
- <td class="tdr_ws1">210</td>
- <td class="tdr_ws1">120</td>
- <td class="tdr_ws1">45</td>
- <td class="tdr_ws1">10</td>
- <td class="tdr_ws1">1</td>
- </tr>
- </tbody>
-</table>
-<p>Thus, in the row 9, under the column headed 4, we see 126, which is 9
-× 8 × 7 × 6 ÷ (1 × 2 × 3 × 4), the number of ways in which 4 can be
-chosen out of 9, which we represent by 4-{9}.</p>
-
-<p>If we add the several rows, we have 1 + 1 or 2, 1 + 2 + 1 or 2², next
-1 + 3 + 3 + 1 or 2³, &amp;c. which verify a theorem already announced; and
-the law of formation shews us that the several columns are formed thus:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr_ws1">1 1&nbsp;&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&emsp;&nbsp;</td>
- <td class="tdr_ws1">1 2 1&nbsp;&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;&emsp;&nbsp;</td>
- <td class="tdr_ws1">1 3 3 1&nbsp;&nbsp;&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1 bb">1 1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr_ws1 bb">1 2 1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr_ws1 bb">1 3 3 1</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr_ws1">1 2 1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr_ws1">1 3 3 1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr_ws1">1 4 6 4 1</td>
- <td class="tdr">, &amp;c.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">so that the sum in each row must be double of the sum in
-the preceding. But we can carry the consequences of this mode of formation
-further. If we make the powers of 1 + <i>x</i> by actual algebraical
-<span class="pagenum" id="Page_208">[Pg 208]</span>
-multiplication, we see that the process makes the same oblique addition in
-the formation of the numerical multipliers of the powers of <i>x</i>.</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub2-5">1 + <i>x</i></li>
-<li class="isub2-5">1 + <i>x</i></li>
-<li class="isub2-5 over">1 + <i>x</i></li>
-<li class="isub4"><i>x</i> + <i>x</i>²</li>
-<li class="isub2 over"> 1 + 2<i>x</i> + <i>x</i>²</li>
-<li class="isub2">&nbsp;</li>
-<li class="isub2">1 + 2<i>x</i> + &nbsp;&nbsp;<i>x</i>²</li>
-<li class="isub2">1 + &nbsp;&nbsp;<i>x</i></li>
-<li class="isub2 over"> 1 + 2<i>x</i> + &nbsp;&nbsp;<i>x</i>²</li>
-<li class="isub4"><i>x</i> + 2<i>x</i>² + <i>x</i>³</li>
-<li class="isub2 over"> 1 + 3<i>x</i> + 3<i>x</i>² + <i>x</i>³</li>
-</ul>
-
-<p class="no-indent">Here are the second and third powers of 1 + <i>x</i>:
-the fourth, we can tell beforehand from the table, must be
-1 + 4<i>x</i> + 6<i>x</i>² + 4<i>x</i>³ + <i>x</i>⁴; and so on.
-Hence we have</p>
-
-<p class="f120 no-wrap">(1 + <i>x</i>)ⁿ = 0ₙ + 1ₙ<i>x</i> + 2ₙ<i>x</i>²
- + 3ₙ<i>x</i>³ + ... + <i>n</i>ₙ<i>x</i>ⁿ</p>
-
-<p class="no-indent">which is usually written with the symbols 0ₙ, 1ₙ, &amp;c.
-at length, thus,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl" rowspan="2"><big>(1 + <i>x</i>)ⁿ = 1 + <i>nx</i> + <i>n</i></big>&nbsp;</td>
- <td class="tdc u"><i>n</i> - 1</td>
- <td class="tdl" rowspan="2">&nbsp;<big><i>x</i>² + <i>n</i></big>&nbsp;</td>
- <td class="tdc u"><i>n</i> - 1</td>
- <td class="tdl" rowspan="2">&nbsp;</td>
- <td class="tdc u"><i>n</i> - 2</td>
- <td class="tdl" rowspan="2">&nbsp;<big><i>x</i>³</big> + &amp;c.</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">This is the simplest case of what in algebra is
-called the <i>binomial theorem</i>. If instead of 1 + <i>x</i> we use
-<i>x</i> + <i>a</i>, we get</p>
-
-<p class="f120 no-wrap">(<i>x</i> + <i>a</i>)ⁿ = <i>x</i>ⁿ + 1ₙ<i>ax</i>ⁿ⁻¹ + 2ₙ<i>a</i>²<i>x</i>ⁿ⁻² + 3ₙ<i>a</i>³<i>x</i>ⁿ⁻³ + ... + <i>n</i>ₙ<i>a</i>ⁿ</p>
-
-<p class="no-indent">We can make the same table in another form. If we
-take a row of ciphers beginning with unity, and setting down the first,
-add the next, and then the next, and so on, and then repeat the process
-with one step less, and then again with one step less, we have the following:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdr">&nbsp;1&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- <td class="tdc">1</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">2</td>
- <td class="tdc">3</td>
- <td class="tdc">4</td>
- <td class="tdc">5</td>
- <td class="tdc">6</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">3</td>
- <td class="tdc">6</td>
- <td class="tdc">10&#8199;</td>
- <td class="tdc">15&#8199;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">4</td>
- <td class="tdc">10&#8199;</td>
- <td class="tdc">20&#8199;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">5</td>
- <td class="tdc">15&#8199;</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">6</td>
- <td class="tdc" colspan="5">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">In the oblique columns we see 1 1, 1 2 1, 1 3 3
-1, &amp;c. the same as in the original table, and formed by the same
-<span class="pagenum" id="Page_209">[Pg 209]</span>
-additions. If, before making the additions, we had always multiplied by
-<i>a</i>, we should have got the several components of the powers of
-1 + <i>a</i>, thus,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdr">&nbsp;1&nbsp;</td>
- <td class="tdc">&#8199;0</td>
- <td class="tdc">&#8199;0</td>
- <td class="tdc">&#8199;0</td>
- <td class="tdc">&#8199;0</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">&#8199;<i>a</i></td>
- <td class="tdc">&#8199;<i>a</i>²</td>
- <td class="tdc">&#8199;<i>a</i>³</td>
- <td class="tdc"><i>a</i>⁴</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">2<i>a</i></td>
- <td class="tdc">3<i>a</i>²</td>
- <td class="tdc">4<i>a</i>³</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">3<i>a</i></td>
- <td class="tdc">6<i>a</i>²</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc">4<i>a</i></td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">1</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">where the oblique columns 1 + <i>a</i>, 1 + 2<i>a</i> + <i>a</i>²,
-1 + 3<i>a</i> + 3<i>a</i>² + <i>a</i>³, &amp;c., give the several powers
-of 1 + <i>a</i>. If instead of beginning with 1, 0, 0, &amp;c. we
-had begun with <i>p</i>, 0, 0, &amp;c. we should have got <i>p</i>,
-<i>p</i> × 4<i>a</i>, <i>p</i> × 6<i>a</i>², &amp;c. at the bottom
-of the several columns; and if we had written at the top <i>x</i>⁴,
-<i>x</i>³, <i>x</i>², <i>x</i>, 1, we should have had all the materials
-for forming <i>p</i>(<i>x</i> + <i>a</i>)⁴ by multiplying the terms at
-the top and bottom of each column together, and adding the results.</p>
-
-<p>Suppose we follow this mode of forming <i>p</i>(<i>x</i> + <i>a</i>)³
-+ <i>q</i>(<i>x</i> + <i>a</i>)² + <i>r</i>(<i>x</i> + <i>a</i>) + <i>s</i>.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc"><i>x</i>³</td>
- <td class="tdc"><i>x</i>²</td>
- <td class="tdc"><i>x</i></td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="6">&emsp;&nbsp;</td>
- <td class="tdc"><i>x</i>²</td>
- <td class="tdc"><i>x</i></td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="6">&emsp;&nbsp;</td>
- <td class="tdc"><i>x</i></td>
- <td class="tdc">1</td>
- <td class="tdc" rowspan="6">&emsp;&nbsp;</td>
- <td class="tdc">1</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc">0</td>
- <td class="tdc">0</td>
- <td class="tdc">0</td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc">0</td>
- <td class="tdc">0</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc">0</td>
- <td class="tdc">1</td>
- </tr><tr>
- <td class="tdc"><i>p</i> </td>
- <td class="tdc"><i>pa</i></td>
- <td class="tdc"><i>pa</i>²</td>
- <td class="tdc"><i>pa</i>³</td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc"><i>qa</i></td>
- <td class="tdc"><i>qa</i>²</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc"><i>ra</i></td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc">2<i>pa</i></td>
- <td class="tdc">3<i>pa</i>²</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc">2<i>qa</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>r</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc">3<i>pa</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc"><i>q</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120 no-wrap"><i>px</i>³ + 3<i>pax</i>² + 3<i>pa</i>²<i>x</i> + <i>pa</i>³
- + <i>qx</i>² + 2<i>qax</i> + <i>qa</i>² + <i>rx</i> + <i>ra</i> + <i>s</i></p>
-
-<p class="f120 no-wrap">= <i>px</i>³ + (3<i>pa</i> + <i>q</i>)<i>x</i>² + (3<i>pa</i>²
- + 2<i>qa</i> + <i>r</i>)<i>x</i> + <i>pa</i>³ + <i>qa</i>² + <i>ra</i> + <i>s</i></p>
-
-<p class="no-indent">Now, observe that all this might be done in one process, by entering
-<i>q</i>, <i>r</i>, and <i>s</i> under their proper powers of <i>x</i>
-in the first process, as follows</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc"><i>x</i>³</td>
- <td class="tdl_ws1"><i>x</i>²</td>
- <td class="tdc" rowspan="6">&emsp;&nbsp;</td>
- <td class="tdl_ws1"><i>x</i></td>
- <td class="tdc" rowspan="6">&emsp;&nbsp;</td>
- <td class="tdl_ws1">1</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdl_ws1"><i>q</i></td>
- <td class="tdl_ws1"><i>r</i></td>
- <td class="tdl_ws1"><i>s</i></td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdl_ws1"><i>pa</i> + <i>q</i></td>
- <td class="tdl_ws1"><i>pa</i>² + <i>qa</i> + <i>r</i></td>
- <td class="tdl_ws1"><i>pa</i>³ + <i>qa</i>² + <i>ra</i> + <i>s</i></td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdl_ws1">2<i>pa</i> + <i>q</i></td>
- <td class="tdl_ws1">3<i>pa</i>² + 2<i>qa</i> + <i>r</i></td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdl_ws1">3<i>pa</i> + <i>q</i></td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- <td class="tdl_ws1">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent"><span class="pagenum" id="Page_210">[Pg 210]</span>
-This process<a id="FNanchor_65" href="#Footnote_65" class="fnanchor">[65]</a>
-is the one used in <a href="#APPENDIX_XI">Appendix XI</a>., with the slight
-alteration of varying the sign of the last letter, and making
-subtractions instead of additions in the last column. As it stands, it
-is the most convenient mode of writing <i>x</i> + <i>a</i> instead of
-<i>x</i> in a large class of algebraical expressions. For instance,
-what does 2<i>x</i>⁵ + <i>x</i>⁴ + 3<i>x</i>² + 7<i>x</i> + 9 become
-when <i>x</i> + 5 is written instead of <i>x</i>? The expression, made
-complete, is,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" rules="cols">
- <tbody><tr>
- <td class="tdc">2<i>x</i>⁵ +</td>
- <td class="tdr_ws1">1<i>x</i>⁴ +</td>
- <td class="tdr_ws1">0<i>x</i>³ +</td>
- <td class="tdr_ws1">3<i>x</i>² +</td>
- <td class="tdr_ws1">7<i>x</i> +</td>
- <td class="tdr_ws1">9</td>
- </tr><tr>
- <td class="tdc">&nbsp;&emsp;&nbsp;</td>
- <td class="tdr_ws1">1</td>
- <td class="tdr_ws1">0</td>
- <td class="tdr_ws1">3</td>
- <td class="tdr_ws1">7</td>
- <td class="tdr_ws1">9</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdr_ws1">11</td>
- <td class="tdr_ws1">55</td>
- <td class="tdr_ws1">278</td>
- <td class="tdr_ws1">1397</td>
- <td class="tdr_ws1">6994</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdr_ws1">21</td>
- <td class="tdr_ws1">160</td>
- <td class="tdr_ws1">1078</td>
- <td class="tdr_ws1">6787</td>
- <td class="tdr_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdr_ws1">31</td>
- <td class="tdr_ws1">315</td>
- <td class="tdr_ws1">2653</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdr_ws1">41</td>
- <td class="tdr_ws1">520</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- </tr><tr>
- <td class="tdc">2</td>
- <td class="tdr_ws1">51</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- <td class="tdr_ws1">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="f120"><i>Answer</i>,&emsp;2<i>x</i>⁵ + 51<i>x</i>⁴ + 520<i>x</i>³
- + 2653<i>x</i>² + 6787<i>x</i> + 6994.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_XI">APPENDIX XI.<br />
-<span class="h_subtitle">ON HORNER’S METHOD OF SOLVING EQUATIONS.</span></h3>
-</div>
-
-<p>The rule given in this chapter is inserted on account of its excellence
-as an exercise in computation. The examples chosen will require but
-little use of algebraical signs, that they may be understood by those
-who know no more of algebra than is contained in the present work.</p>
-
-<p>To solve an equation such as</p>
-
-<p class="f120 no-wrap">2<i>x</i>⁴ + <i>x</i>² - 3<i>x</i> = 416793,</p>
-
-<p class="no-indent">or, as it is usually written,</p>
-
-<p class="f120 no-wrap">2<i>x</i>⁴ + <i>x</i>² - 3<i>x</i> - 416793 = 0,</p>
-
-<p class="no-indent">we must first ascertain by trial not only the first figure of
-the root, but also the denomination of it: if it be a 2, for instance, we must
-know whether it be 2, or 20, or 200, &amp;c., or ·2, or ·02, or ·002, &amp;c.
-<span class="pagenum" id="Page_211">[Pg 211]</span>
-This must be found by trial; and the shortest way of making the
-trial is as follows: Write the expression in its complete form. In the
-preceding case the form is not complete, and the complete form is</p>
-
-<p class="f120 no-wrap">2<i>x</i>⁴ + 0<i>x</i>³ + 1<i>x</i>² - 3<i>x</i> - 416793.</p>
-
-<p class="no-indent">To find what this is when x is any number, for
-instance, 3000, the best way is to take the first multiplier (2),
-multiply it by 3000, and take in the next multiplier (0), multiply the
-result by 3000, and take in the next multiplier (1), and so on to the
-end, as follows:</p>
-
-<p class="f120 no-wrap">2 × 3000 + 0 = 6000;&nbsp; &nbsp; 6000 × 3000 + 1 = 18000001</p>
-
-<p class="f120 no-wrap">18000001 × 3000 - 3 = 54000002997</p>
-
-<p class="f120 no-wrap">54000002997 × 3000 - 416793 = 162000008574207</p>
-
-<p class="no-indent">Now try the value of the above when <i>x</i> = 30. We have then, for
-the steps, 60 (2 × 30 + 0), 1801, 54027, and lastly,</p>
-
-<p class="f120 no-wrap">1620810 - 416793,</p>
-
-<p class="no-indent">or <i>x</i> = 30 makes the first terms greater than 416793. Now try
-<i>x</i> = 20 which gives 40, 801, 16017, and lastly,</p>
-
-<p class="f120 no-wrap">320340 - 416793,</p>
-
-<p class="no-indent">or <i>x</i> = 20 makes the first terms less than 416793. Between 20
-and 30, then, must be a value of <i>x</i> which makes 2<i>x</i>⁴ +
-<i>x</i>²-3x equal to 416793. And this is the preliminary step of the
-process.</p>
-
-<p>Having got thus far, write down the coefficients +2, 0, +1,-3, and
--416793, each with its proper algebraical sign, except the last, in
-which let the sign be changed. This is the most convenient way when the
-last sign is-. But if the last sign be +, it may be more convenient
-to let it stand, and change all which come before. Thus, in solving
-<i>x</i>³-12<i>x</i> + 1 = 0, we might write</p>
-
-<p class="f120 no-wrap">-1&nbsp;&emsp;0&nbsp;&emsp;+12&nbsp;&emsp;1</p>
-
-<p class="no-indent">whereas in the instance before us, we write</p>
-
-<p class="f120 no-wrap">+2&nbsp;&emsp;0&nbsp;&emsp;+1&nbsp;&emsp;-3&nbsp;&emsp;416793</p>
-
-<p class="no-indent">Having done this, take the highest figure of the root, properly
-named, which is 2 tens, or 20. Begin with the first column, multiply by 20,
-<span class="pagenum" id="Page_212">[Pg 212]</span>
-and join it to the number in the next column; multiply that by 20,
-and join it to the number in the next column; and so on. But when you
-come to the last column, subtract the product which comes out of the
-preceding column, or join it to the last column after changing its
-sign. When this has been done, repeat the process with the numbers
-which now stand in the columns, omitting the last, that is, the
-subtracting step; then repeat it again, going only as far as the last
-column but two, and so on, until the columns present a set of rows of
-the following appearance:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="8" summary=" " cellpadding="8" >
- <tbody><tr>
- <td class="tdc"><i>a</i></td>
- <td class="tdc"><i>b</i></td>
- <td class="tdc"><i>c</i></td>
- <td class="tdc"><i>d</i></td>
- <td class="tdc"><i>e</i></td>
- </tr><tr>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc"><i>f</i></td>
- <td class="tdc"><i>g</i></td>
- <td class="tdc"><i>h</i></td>
- <td class="tdc"><i>i</i></td>
- </tr><tr>
- <td class="tdc"><i>k</i></td>
- <td class="tdc"><i>l</i></td>
- <td class="tdc"><i>m</i></td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>n</i></td>
- <td class="tdc"><i>o</i></td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><i>p</i></td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">to the formation of which the following is the key:</p>
-
-<ul class="index fontsize_150 no-wrap">
-<li class="isub2"><i>f</i> = 20<i>a</i> + <i>b</i>,</li>
-<li class="isub2"><i>g</i> = 20<i>f</i> + <i>c</i>,</li>
-<li class="isub2"><i>h</i> = 20<i>g</i> + <i>d</i>,</li>
-<li class="isub2"><i>i</i> = &nbsp;&nbsp;<i>e</i> - 20<i>h</i>,</li>
-<li class="isub2"><i>k</i> = 20<i>a</i> + <i>f</i>,</li>
-<li class="isub2"><i>l</i> = 20<i>k</i> + <i>g</i>,</li>
-<li class="isub2"><i>m</i> = 20<i>l</i> + <i>h</i>,</li>
-<li class="isub2"><i>n</i> = 20<i>a</i> + <i>k</i>,</li>
-<li class="isub2"><i>o</i> = 20<i>n</i> + <i>l</i>,</li>
-<li class="isub2"><i>p</i> = 20<i>a</i> + <i>n</i>.</li>
-</ul>
-
-<p>We call this <i>Horner’s Process</i>, from the name of its inventor. The
-result is as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc">2</td>
- <td class="tdr">0</td>
- <td class="tdr">1</td>
- <td class="tdr">-3</td>
- <td class="tdc">416793</td>
- <td class="tdc">(20</td>
- </tr><tr>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdr">40</td>
- <td class="tdr">801</td>
- <td class="tdc">16017</td>
- <td class="tdc">96453</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdr">80</td>
- <td class="tdc">2401</td>
- <td class="tdc">64037</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc">120</td>
- <td class="tdc">4801</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">160</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">We have now before us the row</p>
-
-<p class="f120">2&nbsp; 160&nbsp; 4801&nbsp; 64037&nbsp; &nbsp; 96453</p>
-
-<p class="no-indent">which furnishes our means of guessing at the next, or units’ figure of
-the root.</p>
-
-<p>Call the last column the <i>dividend</i>, the last but one the
-<i>divisor</i>, and all that come before <i>antecedents</i>. See how
-often the dividend contains the divisor; this gives the guess at the
-<span class="pagenum" id="Page_213">[Pg 213]</span>
-next figure. The guess is a true one,<a id="FNanchor_66" href="#Footnote_66" class="fnanchor">[66]</a>
-if, on applying Horner’s process, the divisor result, augmented as it
-is by the antecedent processes, still go as many times in the dividend.
-For example, in the case before us, 96453 contains 64037 once; let 1 be
-put on its trial. Horner’s process is found to succeed, and we have for
-the second process,</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdc">2</td>
- <td class="tdc">160</td>
- <td class="tdc">4801</td>
- <td class="tdc">64037</td>
- <td class="tdc">96453</td>
- </tr><tr>
- <td class="tdc" rowspan="4">&nbsp;</td>
- <td class="tdc">162</td>
- <td class="tdc">4963</td>
- <td class="tdc">69000</td>
- <td class="tdc">27453</td>
- </tr><tr>
- <td class="tdc">164</td>
- <td class="tdc">5127</td>
- <td class="tdc">74127</td>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc">166</td>
- <td class="tdc">5293</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc">168</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">As soon as we come to the fractional portion of the root,
-the process assumes a more<a id="FNanchor_67" href="#Footnote_67" class="fnanchor">[67]</a>
-methodical form.</p>
-
-<p>The equation being of the <i>fourth</i> degree, annex <i>four</i>
-ciphers to the dividend, <i>three</i> to the divisor, <i>two</i> to
-the antecedent, and <i>one</i> to the previous antecedent, leaving the
-first column as it is; then find the new figure by the dividend and
-divisor, as before,<a id="FNanchor_68" href="#Footnote_68" class="fnanchor">[68]</a>
-and apply Horner’s process. Annex ciphers to the results, as before,
-and proceed in the same way. The annexing of the ciphers prevents our
-having any thing to do with decimal points, and enables us to use the
-quotient-figures without paying any attention to their <i>local</i>
-values. The following exhibits the whole process from the beginning,
-carried as far as it is here intended to go before beginning the
-contraction, which will give more figures, as in the rule for the square
-root. The following, then, is the process as far as one decimal place:
-<span class="pagenum" id="Page_214">[Pg 214]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="4" summary=" " cellpadding="4" >
- <tbody><tr>
- <td class="tdr">2</td>
- <td class="tdr">0</td>
- <td class="tdr">1</td>
- <td class="tdr">-3</td>
- <td class="tdr">416793(213</td>
- </tr><tr>
- <td class="tdr" rowspan="12">&nbsp;</td>
- <td class="tdr">40</td>
- <td class="tdr">801</td>
- <td class="tdr">16017</td>
- <td class="tdl u">&#8199;96453</td>
- </tr><tr>
- <td class="tdr">80</td>
- <td class="tdr">2401</td>
- <td class="tdr u">64037</td>
- <td class="tdr">274530000</td>
- </tr><tr>
- <td class="tdr">120</td>
- <td class="tdr">4801</td>
- <td class="tdr">69000</td>
- <td class="tdr u">47339778</td>
- </tr><tr>
- <td class="tdr">160</td>
- <td class="tdr">4963</td>
- <td class="tdr u">74127000</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr">162</td>
- <td class="tdr">5127</td>
- <td class="tdr">75730074</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr">164</td>
- <td class="tdr u">529300</td>
- <td class="tdr u">77348376</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr">166</td>
- <td class="tdr">534358</td>
- <td class="tdr" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1680</td>
- <td class="tdr">539434</td>
- <td class="tdr" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1686</td>
- <td class="tdr u">544528</td>
- <td class="tdr" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1692</td>
- <td class="tdr" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr">1698</td>
- <td class="tdr" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr u">1704</td>
- <td class="tdr" colspan="3">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p>If we now begin the contraction, it is good to know beforehand on
-what number of additional root-figures we may reckon. We may be
-pretty certain of having nearly as many as there are figures in the
-divisor when we begin to contract&mdash;one less, or at least two less.
-Thus, there being now eight figures in the divisor, we may conclude
-that the contraction will give us at least six more figures. To begin
-the contraction, let the dividend stand, cut off one figure from the
-divisor, two from the column before that, three from the one before
-that, and so on. Thus, our contraction begins with</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">0002&emsp;&nbsp;</td>
- <td class="tdr br">1</td>
- <td class="tdl">704&emsp;&nbsp;</td>
- <td class="tdr br">5445</td>
- <td class="tdl">28&emsp;&nbsp;</td>
- <td class="tdr br">7734837</td>
- <td class="tdl">6&emsp;&nbsp;</td>
- <td class="tdr">47339778</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">The first column is rendered quite useless here.
-Conduct the process as before, using only the figures which are not
-cut off. But it will be better to go as far as the first figure cut off,
-carrying from the second figure cut off. We shall then have as follows:</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr br">1</td>
- <td class="tdl">704&emsp;&nbsp;</td>
- <td class="tdr br">5445</td>
- <td class="tdl">28&emsp;&nbsp;</td>
- <td class="tdr br">7734837</td>
- <td class="tdl">6&emsp;&nbsp;</td>
- <td class="tdr">47339778(6</td>
- </tr><tr>
- <td class="tdc br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">5445</td>
- <td class="tdl">5</td>
- <td class="tdr br">7767570</td>
- <td class="tdl">6</td>
- <td class="tdr">734354</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr br">5465</td>
- <td class="tdl">7</td>
- <td class="tdr br">7800364</td>
- <td class="tdl">8</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr br">5475</td>
- <td class="tdl">9</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc" colspan="2">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">At the next contraction the column 1|704 becomes
-|001704, and is quite useless. The next step, separately written (which
-is not, however, necessary in working), is
-<span class="pagenum" id="Page_215">[Pg 215]</span></p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr br">54</td>
- <td class="tdl">759&emsp;&nbsp;</td>
- <td class="tdr br">780036</td>
- <td class="tdl">48&emsp;&nbsp;</td>
- <td class="tdr">734354(0</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">Here the dividend 734354 does not contain the
-divisor 780036, and we, therefore, write 0 as a root figure and make
-another contraction, or begin with</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">54759&emsp;&nbsp;</td>
- <td class="tdr br">78003</td>
- <td class="tdl">648&emsp;&nbsp;</td>
- <td class="tdr">734354(9</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">78008</td>
- <td class="tdl">5&emsp;&nbsp;</td>
- <td class="tdr">32277&#8199;&#8199;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">78013</td>
- <td class="tdl">4</td>
- <td class="tdr">&nbsp;</td>
- </tr><tr>
- <td class="tdr">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">At the next contraction the first column becomes
-|0054759, and is quite useless, so that the remainder of the process is
-the contracted division.</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdr br">7801</td>
- <td class="tdl">34)</td>
- <td class="tdr">32277</td>
- <td class="tdl">(4137</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdr">1072</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr">292</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr">58</td>
- <td class="tdl">&nbsp;</td>
- </tr><tr>
- <td class="tdc" colspan="2">&nbsp;</td>
- <td class="tdr">3</td>
- <td class="tdl">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">and the root required is 21·36094137.</p>
-
-<p>I now write down the complete process for another equation, one
-root of which lies between 3 and 4: it is</p>
-
-<p class="f150 no-wrap"><i>x</i>³ - 10<i>x</i> + 1 = 0</p>
-
-<table class="fontsize_120 no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdr">1&nbsp;&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdl">-10</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdr">-1(3·111039052073099</td>
- <td class="tdl">0796</td>
- </tr><tr>
- <td class="tdr" rowspan="17">&nbsp;</td>
- <td class="tdc">3</td>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdl">-1</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdl">&#8199;2000</td>
- <td class="tdl" rowspan="18">&nbsp;</td>
- </tr><tr>
- <td class="tdc">6</td>
- <td class="tdl" colspan="3">&nbsp;</td>
- <td class="tdl">&nbsp;1700</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdl">&#8199;&#8199;209000</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">0</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;1791</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdl">&#8199;&#8199;&#8199;19769000</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">1</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;188300</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdr">743369000000&#8199;&#8199;&#8199;</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">2</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;189231</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdr">172311710273000</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">30</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;19016300</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdr">991247447681</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">31</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;19025631</td>
- <td class="tdc" colspan="4">&nbsp;</td>
- <td class="tdr">39462875420</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">32</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;1903496300</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">1391491559</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">0</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;1903524299</td>
- <td class="tdc">0</td>
- <td class="tdc">9</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">58993123</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">1</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;1903552298</td>
- <td class="tdc">2</td>
- <td class="tdc">7</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdc">&nbsp;0&nbsp;</td>
- <td class="tdr">1886047</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">2</td>
- <td class="tdl">&nbsp;</td>
- <td class="tdl">&nbsp;1903560698</td>
- <td class="tdc">0</td>
- <td class="tdc br">5</td>
- <td class="tdc br">9</td>
- <td class="tdc">1</td>
- <td class="tdr">172835</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">30</td>
- <td class="tdl">&nbsp;0</td>
- <td class="tdl">&nbsp;1903569097</td>
- <td class="tdc">8</td>
- <td class="tdc br">5</td>
- <td class="tdc br">6</td>
- <td class="tdc">3</td>
- <td class="tdr">1515</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">30</td>
- <td class="tdl">&nbsp;3</td>
- <td class="tdl">&nbsp;1903569144</td>
- <td class="tdc">5</td>
- <td class="tdc br">2</td>
- <td class="tdc br">2</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">183</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">30</td>
- <td class="tdl">&nbsp;6</td>
- <td class="tdl">&nbsp;1903569191</td>
- <td class="tdc br">1</td>
- <td class="tdc br">8</td>
- <td class="tdc">8</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">12</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl">33</td>
- <td class="tdl">30</td>
- <td class="tdl">90</td>
- <td class="tdl">&nbsp;1903569193</td>
- <td class="tdc br">0</td>
- <td class="tdc br">6</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdc">&nbsp;</td>
- <td class="tdr">1</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl br">33</td>
- <td class="tdl br">30</td>
- <td class="tdl">99</td>
- <td class="tdl br">&nbsp;1903569194</td>
- <td class="tdc br">9</td>
- <td class="tdc br">3</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc">9</td>
- <td class="tdl br">33</td>
- <td class="tdl br">31</td>
- <td class="tdl">08</td>
- <td class="tdl br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc" colspan="3">&nbsp;</td>
- </tr><tr>
- <td class="tdc br">&nbsp;</td>
- <td class="tdc br">09&nbsp;</td>
- <td class="tdl br">33</td>
- <td class="tdl br">31</td>
- <td class="tdl">17</td>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr><tr>
- <td class="tdr br">&nbsp;</td>
- <td class="tdl br">&nbsp;</td>
- <td class="tdl br">&nbsp;</td>
- <td class="tdl br">&nbsp;</td>
- <td class="tdc" colspan="6">&nbsp;</td>
- </tr>
- </tbody>
-</table>
-
-<p class="no-indent">The student need not repeat the rows of figures so
-far as they come under one another: thus, it is not necessary to repeat
-190356. But he must use his own discretion as to how much it would be safe
-for him to omit. I have set down the whole process here as a guide.
-<span class="pagenum" id="Page_216">[Pg 216]</span></p>
-
-<p>The following examples will serve for exercise:</p>
-
-<ul class="index fontsize_120 no-wrap">
-<li class="isub1">1. 2<i>x</i>³ - 100<i>x</i> - 7 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 7·10581133.</li>
-
-<li class="isub1">2. <i>x</i>⁴ + <i>x</i>³ + <i>x</i>² + <i>x</i> = 6000</li>
-<li class="isub3"><i>x</i> = 8·531437726.</li>
-
-
-<li class="isub1">3. <i>x</i>³ + 3<i>x</i>² - 4<i>x</i> - 10 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 1·895694916504.</li>
-
-<li class="isub1">4. <i>x</i>³ + 100<i>x</i>² - 5<i>x</i> - 2173 = 0</li>
-<li class="isub3"><i>x</i> = 4·582246071058464.</li>
-
-<li class="isub2">&nbsp;&nbsp;&nbsp;_</li>
-
-<li class="isub1 space-below1">5. ∛2 = 1·259921049894873164767210607278.<a id="FNanchor_69" href="#Footnote_69" class="fnanchor">[69]</a></li>
-
-<li class="isub1">6. <i>x</i>³ - 6<i>x</i> = 100</li>
-<li class="isub3 space-below1"><i>x</i> = 5·071351748731.</li>
-
-<li class="isub1">7. <i>x</i>³ + 2<i>x</i>² + 3<i>x</i> = 300</li>
-<li class="isub3 space-below1"><i>x</i> = 5·95525967122398.</li>
-
-<li class="isub1">8. <i>x</i>³ + <i>x</i> = 1000</li>
-<li class="isub3 space-below1"><i>x</i> = 9·96666679.</li>
-
-<li class="isub1">9. 27000<i>x</i>³ + 27000<i>x</i> = 26999999</li>
-<li class="isub3 space-below1"><i>x</i> = 9·9666666.....</li>
-
-<li class="isub1">10. <i>x</i>³ - 6<i>x</i> = 100</li>
-<li class="isub3 space-below1"><i>x</i> = 5·0713517487.</li>
-
-<li class="isub1">11. <i>x</i>⁵ - 4<i>x</i>⁴ + 7<i>x</i>³ - 863 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 4·5195507.</li>
-
-<li class="isub1">12. <i>x</i>³ - 20<i>x</i> + 8 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 4·66003769300087278.</li>
-
-<li class="isub1">13. <i>x</i>³ + <i>x</i>² + <i>x</i> - 10 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 1·737370233.</li>
-
-<li class="isub1">14. <i>x</i>³ - 46<i>x</i>² - 36<i>x</i> + 18 = 0</li>
-<li class="isub3"><i>x</i> = 46·7616301847,</li>
-<li class="isub2 space-below1">or <i>x</i> = ·3471623192.</li>
-
-<li class="isub1">15. <i>x</i>³ + 46<i>x</i>² - 36<i>x</i> - 18 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 1·1087925037.</li>
-
-<li class="isub1">16. 8991<i>x</i>³ - 162838<i>x</i>² + 746271<i>x</i> - 81000 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = ·111222333444555....</li>
-
-<li class="isub1">17. 729<i>x</i>³ - 486<i>x</i>² + 99<i>x</i> - 6 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = ·1111..., or ·2222..., or ·3333....</li>
-
-<li class="isub1">18. 2<i>x</i>³ + 3<i>x</i>² - 4<i>x</i> = 500</li>
-<li class="isub3 space-below1"><i>x</i> = 5·93481796231515279.</li>
-
-<li class="isub1">19. <i>x</i>³ + 2<i>x</i>² + <i>x</i> - 150 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 4·6684090145541983253742991201705899.</li>
-
-<li class="isub1">20. <i>x</i>³ + <i>x</i> = <i>x</i>² + 500</li>
-<li class="isub3 space-below1"><i>x</i> = 8·240963558144858526963.</li>
-
-<li class="isub1">21. <i>x</i>³ + 2<i>x</i>² + 3<i>x</i> - 10000 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 20·852905526009.</li>
-
-<li class="isub1">22. <i>x</i>⁵ - 4<i>x</i> - 2000 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 4·581400362.</li>
-
-<li class="isub1">23. 10<i>x</i>³ - 33<i>x</i>² - 11<i>x</i> - 100 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 4·146797808584278785.</li>
-
-<li class="isub1">24. <i>x</i>⁴ + <i>x</i>³ + <i>x</i>² + <i>x</i> = 127694</li>
-<li class="isub3 space-below1"><i>x</i> = 18·64482373095.</li>
-
-<li class="isub1">25. 10<i>x</i>³ + 11<i>x</i>² + 12<i>x</i> = 100000</li>
-<li class="isub3 space-below1"><i>x</i> = 21·1655995554508805.</li>
-
-<li class="isub1">26. <i>x</i>³ + <i>x</i> = 13</li>
-<li class="isub3 space-below1"><i>x</i> = 2·209753301208849.</li>
-
-<li class="isub1">27. <i>x</i>³ + <i>x</i>² - 4<i>x</i> - 1600 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 11·482837157.</li>
-
-<li class="isub1">28. <i>x</i>³ - 2<i>x</i> = 5</li>
-<li class="isub3 space-below1"><i>x</i> = 2·094551481542326591482386540579302963857306105628239.</li>
-
-<li class="isub1">29. <i>x</i>⁴ - 80<i>x</i>³ + 24<i>x</i>² - 6<i>x</i> - 80379639 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 123.<a id="FNanchor_70" href="#Footnote_70" class="fnanchor">[70]</a></li>
-
-<li class="isub1">30. <i>x</i>³ - 242<i>x</i>² - 6315<i>x</i> + 2577096 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 123.<a id="FNanchor_71" href="#Footnote_71" class="fnanchor">[71]</a></li>
-
-<li class="isub1">31. 2<i>x</i>⁴ - 3<i>x</i>³ + 6<i>x</i> - 8 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 1·414213562373095048803.<a id="FNanchor_72" href="#Footnote_72" class="fnanchor">[72]</a></li>
-
-<li class="isub1">32. <i>x</i>⁴ - 19<i>x</i>³ + 132<i>x</i>² - 302<i>x</i> + 200 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = 1·02804, or 4, or 6·57653, or 7·39543<a id="FNanchor_73" href="#Footnote_73" class="fnanchor">[73]</a>.</li>
-
-<li class="isub1">33. 7<i>x</i>⁴ - 11<i>x</i>³ + 6<i>x</i>² + 5<i>x</i> = 215</li>
-<li class="isub3 space-below1"><i>x</i> = 2·70648049385791.<a id="FNanchor_74" href="#Footnote_74" class="fnanchor">[74]</a></li>
-
-<li class="isub1">34. 7<i>x</i>⁵ + 6<i>x</i>⁴ + 5<i>x</i>³ + 4<i>x</i>² + 3<i>x</i> = 11</li>
-<li class="isub3 space-below1"><i>x</i> = ·770768819622658522379296505.<a id="FNanchor_75" href="#Footnote_75" class="fnanchor">[75]</a></li>
-
-<li class="isub1">35. 4<i>x</i>⁶ + 7<i>x</i>⁵ + 9<i>x</i>⁴ + 6<i>x</i>³ + 5<i>x</i>² + 3<i>x</i> = 792</li>
-<li class="isub3 space-below1"><i>x</i> = 2·052042176879605365214043401281201973460275599545541724214.<a id="FNanchor_76" href="#Footnote_76" class="fnanchor">[76]</a></li>
-
-<li class="isub1">36. 2187<i>x</i>⁴ - 2430<i>x</i>³ + 945<i>x</i>² - 150<i>x</i> + 8 = 0</li>
-<li class="isub3 space-below1"><i>x</i> = ·1111...., or ·2222...., or ·3333...., or ·4444....</li>
-</ul>
-
-<p><span class="pagenum" id="Page_217">[Pg 217]</span></p>
-<hr class="chap x-ebookmaker-drop" />
-
-<div class="chapter">
-<h3 class="nobreak" id="APPENDIX_XII">APPENDIX XII.<br />
-<span class="h_subtitle">RULES FOR THE APPLICATION OF<br /> ARITHMETIC TO GEOMETRY.</span></h3>
-</div>
-
-<p>The student should make himself familiar with the most common terms of
-geometry, after which the following rules will present no difficulty.
-In them all, it must be understood, that when we talk of multiplying
-one line by another, we mean the repetition of one line as often as
-there are units of a given kind, as feet or inches, in another. In any
-other sense, it is absurd to talk of multiplying a quantity by another
-quantity. All quantities of the same kind should be represented in
-numbers of the same unit; thus, all the lines should be either feet
-and decimals of a foot, or inches and decimals of an inch, &amp;c. And
-in whatever unit a length is represented, a surface is expressed in
-the corresponding square units, and a solid in the corresponding cubic
-units. This being understood, the rules apply to all sorts of units.</p>
-
-<p><i>To find the area of a rectangle.</i> Multiply together the units in
-<span class="pagenum" id="Page_218">[Pg 218]</span>
-two sides which meet, or multiply together two sides which meet; the
-product is the number of square units in the area. Thus, if 6 feet and
-5 feet be the sides, the area is 6 × 5, or 30 square feet. Similarly,
-the area of a square of 6 feet long is 6 × 6, or 36 square feet (234).</p>
-
-<p><i>To find the area of a parallelogram.</i> Multiply one side by the
-perpendicular distance between it and the opposite side; the product is
-the area required in square units.</p>
-
-<p><i>To find the area of a trapezium.</i><a id="FNanchor_77" href="#Footnote_77" class="fnanchor">[77]</a>
-Multiply either of the two sides which are not parallel by the perpendicular
-let fall upon it from the middle point of the other.</p>
-
-<p><i>To find the area of a triangle.</i> Multiply any side by the
-perpendicular let fall upon it from the opposite vertex, and take half
-the product. Or, halve the sum of the three sides, subtract the three
-sides severally from this half sum, multiply the four results together,
-and find the square root of the product. The result is the number of
-square units in the area; and twice this, divided by either side, is
-the perpendicular distance of that side from its opposite vertex.</p>
-
-<p><i>To find the radius of the internal circle which touches the three
-sides of a triangle.</i> Divide the area, found in the last paragraph,
-by half the sum of the sides.</p>
-
-<p><i>Given the two sides of a right-angled triangle, to find the
-hypothenuse.</i> Add the squares of the sides, and extract the square
-root of the sum.</p>
-
-<p><i>Given the hypothenuse and one of the sides, to find the other
-side.</i> Multiply the sum of the given lines by their difference, and
-extract the square root of the product.</p>
-
-<p><i>To find the circumference of a circle from its radius, very
-nearly.</i> Multiply twice the radius, or the diameter, by 3·1415927,
-taking as many decimal places as may be thought necessary. For a
-rough computation, multiply by 22 and divide by 7. For a very exact
-computation, in which decimals shall be avoided, multiply by 355 and
-divide by 113. See (131), last example.</p>
-
-<p><i>To find the arc of a circular sector, very nearly, knowing the
-<span class="pagenum" id="Page_219">[Pg 219]</span>
-radius and the angle.</i> Turn the angle into seconds,<a id="FNanchor_78" href="#Footnote_78" class="fnanchor">[78]</a>
-multiply by the radius, and divide the product by 206265. The result
-will be the number of units in the arc.</p>
-
-<p><i>To find the area of a circle from its radius, very nearly.</i>
-Multiply the square of the radius by 3·1415927.</p>
-
-<p><i>To find the area of a sector, very nearly, knowing the radius and
-the angle.</i> Turn the angle into seconds, multiply by the square of
-the radius, and divide by 206265 × 2, or 412530.</p>
-
-<p><i>To find the solid content of a rectangular parallelopiped.</i>
-Multiply together three sides which meet: the result is the number of
-cubic units required. If the figure be not rectangular, multiply the
-area of one of its planes by the perpendicular distance between it and
-its opposite plane.</p>
-
-<p><i>To find the solid content of a pyramid.</i> Multiply the area of the
-base by the perpendicular let fall from the vertex upon the base, and
-divide by 3.</p>
-
-<p><i>To find the solid content of a prism.</i> Multiply the area of the
-base by the perpendicular distance between the opposite bases.</p>
-
-<p><i>To find the surface of a sphere.</i> Multiply 4 times the square of
-the radius by 3·1415927.</p>
-
-<p><i>To find the solid content of a sphere.</i> Multiply the cube of the
-radius by 3·1415927 × <big>⁴/₃</big>, or 4·18879.</p>
-
-<p><i>To find the surface of a right cone.</i> Take half the product of
-the circumference of the base and slanting side. <i>To find the solid
-content</i>, take one-third of the product of the base and the altitude.</p>
-
-<p><i>To find the surface of a right cylinder.</i> Multiply the
-circumference of the base by the altitude. <i>To find the solid
-content</i>, multiply the area of the base by the altitude.</p>
-
-<p>The weight of a body may be found, when its solid content is known, if
-the weight of one cubic inch or foot of the body be known. But it is
-<span class="pagenum" id="Page_220">[Pg 220]</span>
-usual to form tables, not of the weights of a cubic unit of different
-bodies, but of the proportion which these weights bear to some one
-amongst them. The one chosen is usually distilled water, and the
-proportion just mentioned is called the <i>specific gravity</i>. Thus,
-the specific gravity of gold is 19·362, or a cubic foot of gold is
-19·362 times as heavy as a cubic foot of distilled water. Suppose now
-the weight of a sphere of gold is required, whose radius is 4 inches.
-The content of this sphere is 4 × 4 × 4 × 4·1888, or 268·0832 cubic
-inches; and since, by (217), each cubic inch of water weighs 252·458
-grains, each cubic inch of gold weighs 252·458 × 19·362, or 4888·091
-grains; so that 268·0832 cubic inches of gold weigh 268·0832 × 4888·091
-grains, or 227½ pounds troy nearly. Tables of specific gravities may be
-found in most works of chemistry and practical mechanics.</p>
-
-<p>The cubic foot of water is 908·8488 troy ounces, 75·7374 troy pounds,
-997·1369691 averdupois ounces, and 62·3210606 averdupois pounds. For
-all rough purposes it will do to consider the cubic foot of water as
-being 1000 common ounces, which reduces tables of specific gravities
-to common terms in an obvious way. Thus, when we read of a substance
-which has the specific gravity 4·1172, we may take it that a cubic foot
-of the substance weighs 4117 ounces. For greater correctness, diminish
-this result by 3 parts out of a thousand.</p>
-
-<p class="f120 space-above1">THE END.</p>
-
-<hr class="chap x-ebookmaker-drop" />
-
-<p class="f150"><b>WALTON AND MABERLY’S</b></p>
-<p class="f120">CATALOGUE OF EDUCATIONAL WORKS,<br />
-AND WORKS IN SCIENCE AND<br />GENERAL LITERATURE.</p>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>ENGLISH</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Dr. R. G.
- Latham.&emsp;The English Language.</i></span> Fourth Edition. 2 vols.
- 8vo. £1 8s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Latham’s Elementary
- English Grammar</i></span>, <i>for the Use of Schools.</i> Eighteenth
- thousand. Small 8vo. 4s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Latham’s Hand-book of
-the English Language</i></span>, <i>for the Use of Students of the Universities and
-higher Classes of Schools.</i> Third Edition. Small 8vo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Latham’s Logic in its Application
-to Language.</i></span> 12mo. 6s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Latham’s First English Grammar</i></span>,
-<i>adapted for general use.</i>By <span class="smcap">Dr. R. G. Latham</span>
-and an Experienced Teacher. Fcap. 8vo.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Latham’s History and Etymology
-of the English Language</i></span>, <i>for the Use of Classical Schools.</i> Second
-Edition, revised. Fcap. 8vo. 1s. 6d. cl.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Mason’s English Grammar</i></span>,
-<i>including the Principles of Grammatical Analysis.</i> 12mo. 3s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Mason’s Cowper’s Task Book I.
-(the Sofa)</i></span>, <i>with Notes on the Analysis and Parsing.</i>
-Crown 8vo. 1s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Abbott’s First English Reader.</i></span>
-Third Edition. 12mo., with Illustrations. 1s. cloth, limp.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Abbott’s Second English Reader.</i></span>
-Third Edition. 12mo. 1s. 6d. cloth, limp.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>GREEK</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Greenwood’s Greek Grammar</i>,</span>
-<i>including Accidence, Irregular Verbs, and Principles of Derivation and Composition;
-adapted to the System of Crude Forms.</i> Small 8vo. 5s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Kühner’s New Greek Delectus</i>;</span>
-<i>being Sentences for Translation from Greek into English, and English into
-Greek; arranged in a systematic Progression</i>. Translated and Edited by the late
-<span class="smcap">Dr. Alexander Allen</span>. Fourth Edition, revised. 12mo. 4s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Gillespie’s Greek Testament
-Roots, in a Selection of Texts</i></span>, <i>giving the power of Reading the whole Greek Testament without
-difficulty.</i> With Grammatical Notes, and a Parsing Lexicon associating the Greek
-Primitives with English Derivatives. Post 8vo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Robson’s Constructive Exercises
-for Teaching the Elements</i></span> of the Greek Language, on a system of Analysis
-and Synthesis, with Greek Reading Lessons and copious Vocabularies.
-12mo., pp. 408. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Robson’s First Greek Book</i></span>.
-<i>Exercises and Reading Lessons with Copious Vocabularies.</i> Being the First Part of
-the “Constructive Greek Exercises.” 12mo. 3s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>The London Greek Grammar</i></span>.
-<i>Designed to exhibit, in small Compass, the Elements of the Greek Language.</i>
-Sixth Edition. 12mo. 1s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Hardy and Adams’s Anabasis of Xenophon</i></span>.
-<i>Expressly for Schools.</i> With Notes, Index of Names, and a Map.
-12mo. 4s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Plato.</i></span>
-The Apology of Socrates, The Crito, and part of the Phaedo; with Notes in
-English from Stallbaum, Schleiermacher’s Introductions, and his Essay on the
-Worth of Socrates as a Philosopher. Edited by Dr. <span class="smcap">Wm. Smith</span>,
-Editor of the Dictionary of Greek and Roman Antiquities, &amp;c. Third Edition.
-12mo. 5s. cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>LATIN</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>New Latin Reading Book</i></span>;
-<i>consisting of Short Sentences, Easy Narrations, and Descriptions, selected from
-Caesar’s Gallic War; in Systematic Progression. With a Dictionary.</i>
-Second Edition, revised. 12mo. 2s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Allen’s New Latin Delectus</i></span>;
-<i>being Sentences for Translation from Latin into English, and English into Latin;
-arranged in a systematic Progression.</i> Fourth Edition, revised. 12mo. 4s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>The London Latin Grammar</i>;</span>;
-<i>including the Eton Syntax and Prosody in English, accompanied with Notes.</i>
-Sixteenth Edition. 12mo. 1s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Robson’s Constructive Latin Exercises</i></span>,
-<i>for teaching the Elements of the Language on a System of Analysis and Synthesis;
-with Latin Reading Lessons and Copious Vocabularies.</i> Third and Cheaper Edition,
-thoroughly revised. 12mo. 4s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Robson’s First Latin Reading Lessons</i></span>.
-<i>With Complete Vocabularies</i>. Intended as an Introduction to Caesar.
-12mo. 2s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Tacitus;</i></span> <span class="smcap">Germania,
-Agricola, and First Book of the Annals</span>. With English Notes, original
-and selected, and Bötticher’s remarks on the style of Tacitus. Edited by Dr. <span class="smcap">Wm. Smith</span>,
-Editor of the Dictionary of Greek and Roman Antiquities, etc. Third Edition, greatly improved.
-12mo. 5s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Caesar. Civil War. Book I</i></span>.
-<i>With English Notes for the Use of Students preparing for the Cambridge School
-Examination.</i> 12mo. 1s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Terence. Andria</i></span>.
-<i>With English Notes, Summaries, and Life of Terence.</i> By <span class="smcap">Newenham Travers</span>,
-B.A., Assistant-Master in University College School. Fcap.8vo. 3s. 6d.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>HEBREW</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Hurwitz’s Grammar of the Hebrew Language.</i></span>
-Fourth Edition. 8vo. 13s. cloth. Or in Two Parts, sold separately:&mdash;<span class="smcap">Elements</span>.
-4s. 6d. cloth. <span class="smcap">Etymology and Syntax.</span> 9s. cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>FRENCH</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Merlet’s French Grammar.</i></span>
-By <span class="smcap">P. F. Merlet</span>, Professor of French in University College, London.
-New Edition. 12mo. 5s. 6d. bound. Or sold in Two Parts:&mdash;<span class="smcap">Pronunciation</span>
-and <span class="smcap">Accidence</span>, 3s. 6d.; <span class="smcap">Syntax</span>,
-3s. 6d. (<span class="smcap">Key</span>, 3s. 6d.)</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Merlet’s Le Traducteur;</i></span>
-<i>Selections, Historical, Dramatic, and Miscellaneous</i>, from the best French Writers, on
-a plan calculated to render reading and translation peculiarly serviceable in acquiring the
-French Language; accompanied by Explanatory Notes, a Selection of Idioms, etc.
-Fourteenth Edition. 12mo. 5s. 6d. bound.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Merlet’s Exercises on French Composition</i></span>.
-Consisting of Extracts from English Authors to be turned into French; with Notes indicating the
-Differences in Style between the two Languages. A List of Idioms, with Explanations, Mercantile
-Terms and Correspondence, Essays, etc. 12mo. 3s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Merlet’s French Synonymes</i></span>,
-<i>explained in Alphabetical Order</i>. Copious Examples (from the “Dictionary of
-Difficulties”). 12mo. 2s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Merlet’s Aperçu de la Litterature Française.</i></span>
-12mo. 2s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Merlet’s Stories from French Writers</i></span>;
-<i>in French and English Interlinear (from Merlet’s “Traducteur”).</i>
-Second Edition. 12mo. 2s. cl.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lombard De Luc’s Classiques Français</i></span>,
-à l’Usage de la Jeunesse Protestante; or, Selections from the best French Classical Works,
-preceded by Sketches of the Lives and Times of the Writers. 12mo. 3s. 6d. cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>ITALIAN</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s First Italian Course</i></span>;
-<i>being a Practical and Easy Method of Learning the Elements of the Italian Language.</i>
-Edited from the German of <span class="smcap">Filippi</span>, after the method of
-Dr. <span class="smcap">Ahn</span>. 12mo. 3s. 6d. cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>INTERLINEAR TRANSLATIONS</b>.</p>
-
-<p class="f120"><i>Locke’s System of Classical Instruction.</i></p>
-<p class="center"><span class="smcap">Interlinear Translations</span> 1s. 6d. each.</p>
-
-<ul class="index">
-<li class="isub6"><i>Latin.</i></li>
-<li class="isub2">Phaedrus’s Fables of Æsop.</li>
-<li class="isub2">Virgil’s Æneid. Book I.</li>
-<li class="isub2">Parsing Lessons to Virgil.</li>
-<li class="isub2 space-below1">Caesar’s Invasion of Britain.</li>
-
-<li class="isub6"><i>Greek.</i></li>
-<li class="isub2">Lucian’s Dialogues. Selections.</li>
-<li class="isub2">Homer’s Iliad. Book I.</li>
-<li class="isub2">Xenophon’s Memorabilia. Book I.</li>
-<li class="isub2 space-below1">Herodotus’s Histories. Selections.</li>
-
-<li class="isub6"><i>French.</i></li>
-<li class="isub2 space-below1">Sismondi; the Battles of Cressy and Poictiers.</li>
-
-<li class="isub6"><i>German.</i></li>
-<li class="isub2 space-below1">Stories from German Writers.</li>
-
-<li class="isub2"><i>Also, to accompany the Latin and Greek Series.</i></li>
-<li class="isub2">The London Latin Grammar. 12mo. 1s. 6d.</li>
-<li class="isub2">The London Greek Grammar. 12mo. 1s. 6d.</li>
-</ul></div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>HISTORY, MYTHOLOGY, AND<br /> ANTIQUITIES</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Creasy’s (Professor) History of England</i></span>.
-<i>With Illustrations.</i> One Volume. Small 8vo. Uniform with Schmitz’s “History of Rome,” and Smith’s
-“History of Greece.” (Preparing).</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Schmitz’s History of Rome</i></span>,
-from the Earliest Times to the <span class="smcap">Death of Commodus, a.d.</span> 192.
-Ninth Edition. One Hundred Engravings. 12mo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s History of Greece</i></span>,
-from the Earliest Times to the Roman Conquest. With Supplementary Chapters on the
-History of Literature and Art. New Edition. One Hundred Engravings on Wood.
-Large 12mo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Smaller History of Greece</i></span>.
-With Illustrations. Fcp. 8vo. 3s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Dictionary of Greek and Roman Antiquities.</i></span>
-By various Writers. Second Edition. Illustrated by Several Hundred Engravings on Wood. One thick volume,
-medium 8vo. £2 2s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Smaller Dictionary of Greek and Roman
-Antiquities</i></span>. Abridged from the larger Dictionary. New Edition. Crown 8vo., 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Dictionary of Greek and Roman Biography and
-Mythology.</i></span> By various Writers. Medium 8vo. Illustrated by numerous Engravings on Wood.
-Complete in Three Volumes. 8vo. £5 15s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s New Classical Dictionary of Biography, Mythology,
-and Geography</i></span>. Partly based on the “Dictionary of Greek and Roman Biography and Mythology.”
-Third Edition 750 Illustrations. 8vo. 18s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Smaller Classical Dictionary of Biography,
-Mythology, and Geography</i></span>. Abridged from the larger Dictionary. Illustrated by 200 Engravings
-on Wood. New Edition. Crown 8vo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Smith’s Dictionary of Greek and Roman Geography.</i></span>
-By various Writers. Illustrated with Woodcuts of Coins, Plans of Cities, etc. Two Volumes 8vo. £4. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Niebuhr’s History of Rome</i></span>.
-<i>From the Earliest Times to the First Punic War.</i> Fourth Edition. Translated by
-<span class="smcap">Bishop Thirlwall, Archdeacon Hare, Dr. Smith</span>,
-and <span class="smcap">Dr. Schmitz</span>. Three Vols. 8vo. £1 16s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Niebuhr’s Lectures on the History of Rome.</i></span>
-<i>From the Earliest Times to the First Punic War</i>. Edited by <span class="smcap">Dr. Schmitz</span>.
-Third Edition. 8vo. 8s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Newman (F. W.) The Odes of Horace.</i></span>
-Translated into Unrhymed Metres, with Introduction and Notes. Crown 8vo. 5s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Newman (F. W.) The Iliad of Homer</i></span>,
-Faithfully translated into Unrhymed Metre. 1 vol. crown 8vo 6s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Akerman’s Numismatic Manual</i></span>, or
-<i>Guide to the Collection and Study of Greek, Roman, and English Coins.</i>
-Many Engravings. 8vo. £1 1s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Ramsay’s (George) Principles of Psychology.</i></span>
-8vo. 1Os. 6d.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>PURE MATHEMATICS</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>De Morgan’s Elements of Arithmetic.</i></span>
-Fifteenth Thousand. Royal 12mo. 5s. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>De Morgan’s Trigonometry and Double Algebra.</i></span>
-Royal 12mo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Ellenberger’s Course of Arithmetic</i></span>,
-as taught in the Pestalozzian School, Worksop. Post 8vo. 5s. cloth.<br />
-⁂ <i>The Answers to the Questions in this Volume are now ready</i>, price 1s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Mason’s First Book of Euclid</i></span>.
-<i>Explained to Beginners.</i> Fcap. 8vo. 1s. 9d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Reiner’s Lessons on Form</i></span>; or,
-<span class="fontsize_120"><i>An Introduction to Geometry</i></span>, as given in a Pestalozzian
-School, Cheam, Surrey. 12mo. 3s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Reiner’s Lessons on Number</i></span>,
-as given in a Pestalozzian School, Cheam, Surrey. Master’s Manual, 5s.<br />
-Scholar’s Praxis, 2s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Tables of Logarithms Common and Trigonometrical</i></span>
-to Five Places. Under the Superintendence of the Society for the Diffusion of Useful Knowledge.
-Fcap. 8vo. 1s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Four Figure Logarithms and Anti-Logarithms.</i></span>
-On a Card. Price 1s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Barlow’s Tables of Squares, Cubes, Square Roots, Cube
-Roots, and Reciprocals</i></span> of all Integer Numbers, up to 10,000. Royal 12mo. 8s.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>MIXED MATHEMATICS</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Potter’s Treatise on Mechanics</i></span>,
-<i>for Junior University Students.</i> By <span class="smcap">Richard Potter</span>, M.A.,
-Professor of Natural Philosophy in University College, London. Third Edition. 8vo. 8s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Potter’s Treatise on Optics. Part I.</i></span>
-All the requisite Propositions carried to First Approximations, with the construction of Optical
-Instruments, for Junior University Students. Second Edition. 8vo. 9s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Potter’s Treatise on Optics. Part II.</i></span>
-The Higher Propositions, with their application to the more perfect forms of Instruments.
-8vo. 12s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Potter’s Physical Optics</i></span>;
-or, the <span class="fontsize_120"><i>Nature and Properties of Light.</i></span>
-A Descriptive and Experimental Treatise. 100 Illustrations. 8vo. 6s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Newth’s Mathematical Examples</i></span>.
-<i>A graduated series of Elementary Examples, in Arithmetic, Algebra, Logarithms,
-Trigonometry, and Mechanics.</i> Crown 8vo.<br />
-With Answers. 8s. 6d. cloth.</p>
-
-<p class="center space-above1"><i>Sold also in separate Parts, without Answers</i>:&mdash;</p>
-
-<ul class="index">
-<li class="isub2">Arithmetic, 2s. 6d.</li>
-<li class="isub2">Algebra, 2s. 6d.</li>
-<li class="isub2">Trigonometry and Logarithms, 2s. 6d.</li>
-<li class="isub2">Mechanics, 2s. 6d.</li>
-</ul>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Newth’s Elements of Mechanics, including Hydrostatics,</i></span>
-with numerous Examples. By <span class="smcap">Samuel Newth</span>, M.A., Fellow of University College,
-London. Second Edition. Large 12mo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Newth’s First Book of Natural Philosophy</i></span>;
-or an <span class="fontsize_120"><i>Introduction to the Study of Statics, Dynamics, Hydrostatics,
-and Optics</i></span>, with numerous Examples. 12mo. 3s. 6d. cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>NATURAL PHILOSOPHY, ASTRONOMY, Etc</b>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Museum of Science and Art.</i></span>
-Complete in 12 Single Volumes, 18s., ornamental boards; or 6 Double Ones, £1 1s., cl. lettered.</p>
-
-<p class="center">⁂ <i>Also, handsomely half-bound morocco, 6 volumes</i>, £1 11s. 6d.</p>
-
-<ul class="index no-wrap">
-<li class="isub3"><span class="smcap">Contents</span>:&mdash;The Planets; are they inhabited Worlds?</li>
-<li class="isub2">Weather Prognostics. Popular Fallacies in Questions</li>
-<li class="isub2">of Physical Science. Latitudes and Longitudes. Lunar</li>
-<li class="isub2">Influences. Meteoric Stones and Shooting Stars. Railway</li>
-<li class="isub2">Accidents. Light. Common Things.&mdash;Air. Locomotion</li>
-<li class="isub2">in the United States. Cometary Influences. Common</li>
-<li class="isub2">Things.&mdash;Water. The Potter’s Art. Common Things.&mdash;Fire.</li>
-<li class="isub2">Locomotion and Transport, their Influence and Progress.</li>
-<li class="isub2">The Moon. Common Things.&mdash;The Earth. The Electric</li>
-<li class="isub2">Telegraph. Terrestrial Heat. The Sun. Earthquakes and</li>
-<li class="isub2">Volcanoes. Barometer, Safety Lamp, and Whitworth’s</li>
-<li class="isub2">Micrometric Apparatus. Steam. The Steam Engine. The</li>
-<li class="isub2">Eye. The Atmosphere. Time. Common Things.&mdash;Pumps.</li>
-<li class="isub2">Common Things.&mdash;Spectacles&mdash;The Kaleidoscope. Clocks</li>
-<li class="isub2">and Watches. Microscopic Drawing and Engraving. The</li>
-<li class="isub2">Locomotive. Thermometer. New Planets.&mdash;Leverrier and</li>
-<li class="isub2">Adams’s Planet. Magnitude and Minuteness. Common</li>
-<li class="isub2">Things.&mdash;The Almanack. Optical Images. How to Observe</li>
-<li class="isub2">the Heavens. Common Things.&mdash;The Looking Glass. Stellar</li>
-<li class="isub2">Universe. The Tides. Colour. Common Things.&mdash;Man.</li>
-<li class="isub2">Magnifying Glasses. Instinct and Intelligence. The Solar</li>
-<li class="isub2">Microscope. The Camera Lucida. The Magic Lantern. The</li>
-<li class="isub2">Camera Obscura. The Microscope. The White Ants; their</li>
-<li class="isub2">Manners and Habits. The Surface of the Earth, or First</li>
-<li class="isub2">Notions of Geography. Science and Poetry. The Bee. Steam</li>
-<li class="isub2">Navigation. Electro-Motive Power. Thunder, Lightning,</li>
-<li class="isub2">and the Aurora Borealis. The Printing Press. The Crust</li>
-<li class="isub2">of the Earth. Comets. The Stereoscope. The Pre-Adamite</li>
-<li class="isub2">Earth. Eclipses. Sound.</li>
-</ul>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Animal Physics</i></span>,
-or <span class="fontsize_120"><i>the Body and its Functions</i></span>
-familiarly Explained. 520 Illustrations. 1 vol., small 8vo. 12s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Animal Physiology for Schools</i></span>
-(<i>chiefly taken from the “Animal Physics”</i>). 190 Illustrations. 12mo. 3s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Hand-Book of Mechanics</i></span>.
-357 Illustrations. 1 vol., small 8vo., 5s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Hand-Book of Hydrostatics,
-Pneumatics, and Heat.</i></span> 292 Illustrations. 1 vol., small 8vo., 5s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Hand-Book of Optics.</i></span>
-290 Illustrations. 1 vol., small 8vo., 5s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Hand-Book of Electricity,
-Magnetism, and Acoustics.</i></span> 395 Illustrations. 1 vol., small 8vo. 5s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Hand-Book of Astronomy and
-Meteorology</i></span>, forming a companion work to the “Hand-Book of Natural
-Philosophy.” 37 Plates, and upwards of 200 Illustrations on Wood. 2 vols.,
-each 5s., cloth lettered.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Natural Philosophy for Schools.</i></span>
-328 Illustrations. 1 vol., large 12mo., 3s. 6d. cloth.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Chemistry for Schools.</i></span>
-170 Illustrations. 1 vol., large 12mo. 3s. 6d. cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-
-<p class="f120"><i>Pictorial Illustrations of Science and Art</i>.</p>
-<p class="f110"><i>Large Printed Sheets</i>,</p>
-<p class="center">each containing from 50 to 100 Engraved Figures.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdc"><big><b>Part I. 1s. 6d.</b></big></td>
- </tr><tr>
- <td class="tdl">1. Mechanic Powers.</td>
- </tr><tr>
- <td class="tdl">2. Machinery.</td>
- </tr><tr>
- <td class="tdl">3. Watch and Clock Work.</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><big><b>Part II. 1s. 6d.</b></big></td>
- </tr><tr>
- <td class="tdl">4. Elements of Machinery.</td>
- </tr><tr>
- <td class="tdl">5. Motion and Force.</td>
- </tr><tr>
- <td class="tdl">6. Steam Engine.</td>
- </tr><tr>
- <td class="tdc">&nbsp;</td>
- </tr><tr>
- <td class="tdc"><big><b>Part III. 1s. 6d.</b></big></td>
- </tr><tr>
- <td class="tdl">7. Hydrostatics.</td>
- </tr><tr>
- <td class="tdl">8. Hydraulics.</td>
- </tr><tr>
- <td class="tdl">9. Pneumatics.</td>
- </tr>
- </tbody>
-</table>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Popular Geology</i></span>.
-(<i>From “The Museum of Science and Art.”</i>) 201 Illustrations. 2s. 6d.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Common Things
-Explained. Containing:</i></span></p>
-
-<p class="center">Air&mdash;Earth&mdash;Fire&mdash;Water&mdash;Time&mdash;The
-Almanack&mdash;Clocks and Watches&mdash;Spectacles&mdash;Colour&mdash;Kaleidoscope&mdash;
-Pumps&mdash;Man&mdash;The Eye&mdash;The Printing Press&mdash;The
-Potter’s Art&mdash;Locomotion and Transport&mdash;The Surface of the
-Earth, or First Notions of Geography. (From “The Museum of Science and
-Art.”) With 233 Illustrations. Complete, 5s., cloth lettered.</p>
-
-<p class="center">⁂ <i>Sold also in Two Series</i>, 2s. 6d. <i>each</i>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Popular Physics. Containing</i>:</span></p>
-<p class="center">Magnitude and Minuteness&mdash;Atmosphere&mdash;Thunder and
-Lightning&mdash;Terrestrial Heat&mdash;Meteoric Stones&mdash;Popular Fallacies&mdash;
-Weather Prognostics&mdash;Thermometer&mdash;Barometer&mdash;Safety
-Lamp&mdash;Whitworth’s Micrometric Apparatus&mdash;Electro-Motive
-Power&mdash;Sound&mdash;Magic Lantern&mdash;Camera Obscura&mdash;Camera
-Lucida&mdash;Looking Glass&mdash;Stereoscope&mdash;Science and Poetry.
-(From “The Museum of Science and Art.”) With 85 Illustrations. 2s. 6d.
-cloth lettered.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner’s Popular Astronomy. Containing</i>:</span></p>
-<p class="center">How to Observe the Heavens&mdash;Latitudes and
-Longitudes &mdash;TheEarth&mdash;The Sun&mdash;The Moon&mdash;The
-Planets: are they Inhabited?&mdash;The New Planets&mdash;Leverrier
-and Adams’s Planet&mdash;The Tides&mdash;Lunar Influences&mdash;and
-the Stellar Universe&mdash;Light&mdash;Comets&mdash;Cometary
-Influences&mdash;Eclipses&mdash;Terrestrial Rotation&mdash;Lunar
-Rotation&mdash;Astronomical Instruments. (From “The Museum of Science
-and Art.”) 182 Illustrations. Complete, 4s. 6d. cloth lettered.</p>
-
-<p class="center">⁂ <i>Sold also in Two Series</i>, 2s. 6d. <i>and</i> 2s.<i>each</i>.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner on the Microscope</i>.</span>
-(From “The Museum of Science and Art.”) 1 vol. 147 Engravings. 2s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner on the Bee and White Ants;
-their Manners and Habits</i></span>; with Illustrations of Animal Instinct and Intelligence.
-(From “The Museum of Science and&nbsp; Art.”) 1 vol. 135 Illustrations. 2s., cloth lettered.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner on Steam and its Uses</i>;</span>
-including the Steam Engine and Locomotive, and Steam Navigation. (From “The Museum of
-Science and Art.”) 1 vol., with 89 Illustrations. 2s.</p>
-
-<p class="neg-indent"><span class="fontsize_120"><i>Lardner on the Electric Telegraph, Popularised</i>.</span>
-With 100 Illustrations. (From “The Museum of Science and Art.”) 12mo., 250 pages. 2s.,
-cloth lettered.</p>
-
-<p class="center space-above2">⁂ <i>The following Works from “Lardner’s Museum of Science
-and Art</i>,” may also be had arranged as described, handsomely half bound morocco,
-cloth sides.</p>
-
-<table class="no-wrap" border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl">Common Things. Two series in one vol.</td>
- <td class="tdr">7s. 6d.</td>
- </tr><tr>
- <td class="tdl">Popular Astronomy. Two series in one vol.</td>
- <td class="tdr">7s. 0d.</td>
- </tr><tr>
- <td class="tdl">Electric Telegraph, with Steam and its Uses. In one vol.&emsp;&nbsp;</td>
- <td class="tdr">7s. 0d.</td>
- </tr><tr>
- <td class="tdl">Microscope and Popular Physics. In one vol.</td>
- <td class="tdr">7s. 0d.</td>
- </tr><tr>
- <td class="tdl">Popular Geology, and Bee and White Ants. In one vol.</td>
- <td class="tdr">7s. 6d.</td>
- </tr>
- </tbody>
-</table>
-
-<p class="neg-indent space-above2"><span class="fontsize_120"><i>Lardner on the Steam Engine,
-Steam Navigation, Roads, and Railways</i>.</span> Explained and Illustrated. Eighth Edition.
-With numerous Illustrations. 1 vol. large 12mo. 8s. 6d.</p>
-
-<p class="neg-indent space-above2"><span class="fontsize_120"><i>A Guide to the Stars for
-every Night in the Year</i></span>. In Eight Planispheres. With an Introduction.
-8vo. 5s., cloth.</p>
-
-<p class="neg-indent space-above2"><span class="fontsize_120"><i>Minasi’s Mechanical Diagrams</i></span>.
-For the Use of Lecturers and Schools. 15 Sheets of Diagrams, coloured, 15s., illustrating
-the following subjects: 1 and 2. Composition of Forces.&mdash;3. Equilibrium.&mdash;4 and 5.
-Levers.&mdash;6. Steelyard, Brady Balance, and Danish Balance.&mdash;7. Wheel and Axle.&mdash;8.
-Inclined Plane.&mdash;9, 10, 11. Pulleys.&mdash;12. Hunter’s Screw.&mdash;13 and 14. Toothed
-Wheels.&mdash;15. Combination of the Mechanical Powers.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>LOGIC</b>.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>De Morgan’s Formal Logic</i></span>;
-or, <span class="fontsize_120"><i>The Calculus of Inference</i>,</span>
-Necessary and Probable. 8vo. 6s. 6d.</p>
-
-<p class="neg-indent space-above2"><span class="fontsize_120"><i>Neil’s Art of Reasoning:</i></span>
-a Popular Exposition of the Principles of Logic, Inductive and Deductive; with an
-Introductory Outline of the History of Logic, and an Appendix on recent Logical Developments,
-with Notes. Crown 8vo. 4s. 6d., cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>ENGLISH COMPOSITION</b>.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Neil’s Elements of Rhetoric</i></span>;
-a Manual of the Laws of Taste, including the Theory and Practice of Composition.
-Crown 8vo. 4s. 6d., cl.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>DRAWING</b>.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Lineal Drawing Copies for the
-earliest Instruction</i>.</span>Comprising upwards of 200 subjects on 24 sheets, mounted
-on 12 pieces of thick pasteboard, in a Portfolio. By the Author of “Drawing for Young Children.”
-5s. 6d.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Easy Drawing Copies for
-Elementary Instruction.</i></span> Simple Outlines without Perspective. 67 subjects,
-in a Portfolio. By the Author of “Drawing for Young Children.” 6s. 6d.</p>
-
-<p class="f120 space-above2"><b><i>Sold also in Two Sets.</i></b></p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><span class="smcap">Set I.</span></span>
-Twenty-six Subjects mounted on thick pasteboard, in a Portfolio. 3s. 6d.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><span class="smcap">Set II.</span></span>
-Forty-one Subjects mounted on thick pasteboard, in a Portfolio. 3s. 6d.</p>
-
-<p class="f110">The copies are sufficiently large and bold to be drawn from
-by forty or fifty children at the same time.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>SINGING</b>.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>A Musical Gift from an Old Friend</i></span>,
-containing Twenty-four New Songs for the Young. By <span class="smcap">W. E Hickson</span>,
-author of the Moral Songs of “The Singing Master.” 8vo. 2s. 6d.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>The Singing Master</i></span>.
-<i>Containing First Lessons in Singing, and the Notation of Music</i>; Rudiments of the Science
-of Harmony; The First Class Tune Book; The Second Class Tune Book; and the Hymn Tune Book.
-Sixth Edition. 8vo. 6s., cloth lettered.<br />
-<i>Sold also in Five Parts, any of which may be had separately.</i></p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120">I.&mdash;<i>First Lessons in Singing
-and the Notation of Music.</i></span> Containing Nineteen Lessons in the Notation
-and Art of Reading Music, as adapted for the Instruction of Children, and especially
-for Class Teaching, with Sixteen Vocal Exercises, arranged as simple two-part
-harmonies. 8vo. 1s., sewed.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120">II.&mdash;<i>Rudiments of
-the Science of Harmony</i></span> or <span class="fontsize_120"><i>Thorough Bass.</i></span>
-Containing a general view of the principles of Musical Composition, the Nature of Chords
-and Discords, mode of applying them, and an Explanation of Musical Terms connected with
-this branch of Science. 8vo. 1s., sewed.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120">III.&mdash;<i>The First
-Class Tune Book</i></span>. A Selection of Thirty Single and Pleasing Airs, arranged
-with suitable words for young children. 8vo. 1s., sewed.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120">IV.&mdash;<i>The Second
-Class Tune Book</i>.</span> A Selection of Vocal Music adapted for youth of different
-ages, and arranged (with suitable words) as two or three-part harmonies.
-8vo, 1s. 6d.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120">V.&mdash;<i>The Hymn Tune Book</i>.</span>
-A Selection of Seventy popular Hymn and Psalm Tunes, arranged with a view of
-facilitating the progress of Children learning to sing in parts.
-8vo. 1s. 6d.</p>
-
-<p class="f110 space-above1">⁂ The Vocal Exercises, Moral Songs, and Hymns, with the
-Music, may also be had, printed on Cards, price Twopence
-each Card, or Twenty-five for Three Shillings.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>CHEMISTRY</b>.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Gregory’s Hand-Book of Chemistry</i>.</span>
-For the use of Students. By <span class="smcap">William Gregory</span>, M.D., late
-Professor of Chemistry in the University of Edinburgh. Fourth Edition, revised and
-enlarged. Illustrated by Engravings on Wood. Complete in One Volume. Large 12mo.
-18s. cloth.</p>
-
-<p class="f110">⁂ <i>The Work may also be had in two Volumes, as under.</i></p>
-
-<p class="neg-indent"><b><span class="smcap">Inorganic Chemistry.</span></b> Fourth Edition,
-revised and enlarged. 6s. 6d. cloth.</p>
-
-<p class="neg-indent"><b><span class="smcap">Organic Chemistry.</span></b> Fourth Edition,
-very carefully revised, and greatly enlarged. 12s., cloth.(Sold separately.)</p>
-
-<p class="neg-indent space-above2"><span class="fontsize_120"><i>Chemistry for Schools</i>.</span>
-By <span class="smcap">Dr. Lardner</span>.190 Illustrations. Large 12mo. 3s. 6d. cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Liebig’s Familiar Letters
-on Chemistry</i></span>, <i>in its Relations to Physiology, Dietetics, Agriculture, Commerce,
-and Political Economy.</i> Fourth Edition, revised and enlarged, with additional Letters.
-Edited by <span class="smcap">Dr. Blyth</span>. Small 8vo. 7s. 6d. cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Liebig’s Letters on Modern
-Agriculture.</i></span> Small 8vo. 6s.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Liebig’s Principles of
-Agricultural Chemistry</i></span>; <i>with Special Reference to the late Researches made
-in England.</i> Small 8vo. 3s. 6d., cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Liebig’s Chemistry in
-its Applications to Agriculture and Physiology.</i></span> Fourth Edition, revised.
-8vo. 6s. 6d., cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Liebig’s Animal Chemistry</i></span>;
-or, <span class="fontsize_120"><i>Chemistry in its Application to Physiology and Pathology.</i></span>
-Third Edition. Part I. (the first half of the work). 8vo. 6s. 6d., cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Liebig’s Hand-Book of Organic
-Analysis;</i></span> containing a detailed Account of the various Methods used in
-determining the Elementary Composition of Organic Substances. Illustrated by 85 Woodcuts.
-12mo. 5s., cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Bunsen’s Gasometry</i></span>;
-comprising the Leading Physical and Chemical Properties of Gases, together with the
-Methods of Gas Analysis. Fifty-nine Illustrations. 8vo. 8s. 6d., cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Wöhler’s Hand-Book of
-Inorganic Analysis;</i></span> One Hundred and Twenty-two Examples, illustrating the
-most important processes for determining the Elementary composition of Mineral substances.
-Edited by <span class="smcap">Dr. A. W. Hofmann</span>, Professor in the Royal
-College of Chemistry. Large 12mo.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Parnell on Dyeing and
-Calico Printing</i></span>. (Reprinted from Parnell’s “Applied Chemistry in Manufactures,
-Arts, and Domestic Economy, 1844.”) With Illustrations. 8vo. 7s., cloth.</p>
-</div>
-
-<hr class="r25" />
-<div class="blockquot">
-<p class="f120"><b>GENERAL LITERATURE</b>.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>De Morgans Book of Almanacs</i>.</span>
-With an Index of Reference by which the Almanac may be found for every Year, whether in
-Old Style or New, from any Epoch, Ancient or Modern, up to <span class="smcap">a.d.</span> 2000.
-With means of finding the Day of New or Full Moon, from <span class="smcap">b.c.</span> 2000
-to <span class="smcap">a.d.</span> 2000. 5s., cloth lettered.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Guesses at Truth. By Two Brothers</i></span>.
-New Edition. With an Index. Complete 1 vol. Small 8vo. Handsomely bound in cloth with
-red edges. 10s. 6d.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Rudall’s Memoir of the
-Rev. James Crabb; late of Southampton</i></span>. With Portrait. Large 12mo., 6s., cloth.</p>
-
-<p class="neg-indent space-above1"><span class="fontsize_120"><i>Herschell (R. H.) The Jews;</i></span>
-a brief Sketch of their Present State and Future Expectations.
-Fcap. 8vo. 1s. 6d., cloth.</p>
-</div>
-
-<hr class="chap" />
-
-<div class="footnotes">
-<p class="f150 u"><b>Footnotes:</b></p>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_1" href="#FNanchor_1" class="label">[1]</a>
-Some separate copies of these Appendixes are printed, for
-those who may desire to add them to the former editions.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_2" href="#FNanchor_2" class="label">[2]</a>
-It has been supposed that <i>eleven</i> and <i>twelve</i>
-are derived from the Saxon for <i>one left</i> and <i>two left</i>
-(meaning, after ten is removed); but there seems better reason to
-think that <i>leven</i> is a word meaning ten, and connected with <i>decem</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_3" href="#FNanchor_3" class="label">[3]</a>
-The references are to the preceding articles.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_4" href="#FNanchor_4" class="label">[4]</a>
-Any little computations which occur in the rest of this
-section may be made on the fingers, or with counters.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_5" href="#FNanchor_5" class="label">[5]</a>
-This should be (23) <i>a</i> × <i>a</i>, but the sign ×
-is unnecessary here. It is used with numbers, as in 2 × 7, to
-prevent confounding this, which is 14, with 27.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_6" href="#FNanchor_6" class="label">[6]</a>
-In this and all other processes, the student is strongly
-recommended to look at and follow the <a href="#APPENDIX_I">first Appendix</a>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_7" href="#FNanchor_7" class="label">[7]</a>
-Those numbers which have been altered are put in italics.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_8" href="#FNanchor_8" class="label">[8]</a>
-As it is usual to learn the product of numbers up to 12 times 12, I
-have extended the table thus far. In my opinion, all pupils who shew a
-tolerable capacity should slowly commit the products to memory as far
-as 20 times 20, in the course of their progress through this work.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_9" href="#FNanchor_9" class="label">[9]</a>
-To speak always in the same way, instead of saying that
-6 does not contain 13, I say that it contains it 0 times and 6 over,
-which is merely saying that 6 is 6 more than nothing.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_10" href="#FNanchor_10" class="label">[10]</a> If you
-have any doubt as to this expression, recollect that it means “contains
-more than two eighteens, but not so much as three.”</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_11" href="#FNanchor_11" class="label">[11]</a>
-Among the even figures we include 0.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_12" href="#FNanchor_12" class="label">[12]</a>
-Including both ciphers and others.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_13" href="#FNanchor_13" class="label">[13]</a>
-For shortness, I abbreviate the words <i>greatest common
-measure</i> into their initial letters, g. c. m.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_14" href="#FNanchor_14" class="label">[14]</a>
-Numbers which contain an exact number of units, such as 5,
-7, 100, &amp;c., are called <i>whole numbers</i> or <i>integers</i>,
-when we wish to distinguish them from fractions.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_15" href="#FNanchor_15" class="label">[15]</a>
-A factor of a number is a number which divides it without
-remainder: thus, 4, 6, 8, are factors of 24, and 6 × 4, 8 × 3,
-2 × 2 × 2 × 3, are several ways of decomposing 24 into factors.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_16" href="#FNanchor_16" class="label">[16]</a>
-The method of solving this and the following question may be shewn
-thus: If the number of days in which each could reap the field is
-given, the part which each could do in a day by himself can be found,
-and thence the part which all could do together; this being known, the
-number of days which it would take all to do the whole can be found.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_17" href="#FNanchor_17" class="label">[17]</a>
-A formula is a name given to any algebraical expression
-which is commonly used.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_18" href="#FNanchor_18" class="label">[18]</a>
-Or remove ciphers from the divisor; or make up the number
-of ciphers partly by removing from the divisor and annexing to the
-dividend, if there be not a sufficient number in the divisor.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_19" href="#FNanchor_19" class="label">[19]</a>
-These are not quite correct, but sufficiently so for every
-practical purpose.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_20" href="#FNanchor_20" class="label">[20]</a>
-The 1′ here means that the 1 is in the multiplier.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_21" href="#FNanchor_21" class="label">[21]</a>
-This is written 7 instead of 6, because the figure which
-is abandoned in the dividend is 9 (151).</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_22" href="#FNanchor_22" class="label">[22]</a>
-Meaning, of course, a really fractional number, such as
-⅞ or ¹⁵/₁₁, not one which, though fractional in form, is whole in
-reality, such as ¹⁰/₅ or ²⁷/₃.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_23" href="#FNanchor_23" class="label">[23]</a>
-By square number I mean, a number which has a square root.
-Thus, 25 is a square number, but 26 is not.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_24" href="#FNanchor_24" class="label">[24]</a>
-The term ‘root’ is frequently used as an abbreviation of square root.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_25" href="#FNanchor_25" class="label">[25]</a>
-Or, more simply, add the second figure of the root to the first divisor.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_26" href="#FNanchor_26" class="label">[26]</a>
-This is a very incorrect name, since the term ‘arithmetical’ applies
-equally to every notion in this book. It is necessary, however, that
-the pupil should use words in the sense in which they will be used in
-his succeeding studies.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_27" href="#FNanchor_27" class="label">[27]</a>
-The same remark may be made here as was made in the note
-on the term ‘arithmetical proportion,’ page 101. The word ‘geometrical’
-is, generally speaking, dropped, except when we wish to distinguish
-between this kind of proportion and that which has been called arithmetical.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_28" href="#FNanchor_28" class="label">[28]</a>
-A theorem is a general mathematical fact: thus, that every
-number is divisible by four when its last two figures are divisible
-by four, is a theorem; that in every proportion the product of the
-extremes is equal to the product of the means, is another.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_29" href="#FNanchor_29" class="label">[29]</a>
-If <i>bx</i> be substituted for <i>a</i> in any expression
-which is homogeneous with respect to <i>a</i> and <i>b</i>, the pupil
-may easily see that <i>b</i> must occur in every term as often as
-there are units in the degree of the expression: thus, <i>aa</i> +
-<i>ab</i> becomes <i>bxbx</i> + <i>bxb</i> or <i>bb</i>(<i>xx</i> +
-<i>x</i>); <i>aaa</i> + <i>bbb</i> becomes <i>bxbxbx</i> + <i>bbb</i>
-or <i>bbb</i>(<i>xxx</i> + 1); and so on.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_30" href="#FNanchor_30" class="label">[30]</a>
-The difference between this problem and the last is left
-to the ingenuity of the pupil.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_31" href="#FNanchor_31" class="label">[31]</a>
-It is not true, that if we choose any quantity as a
-unit, <i>any</i> other quantity of the same kind can be exactly
-represented either by a certain number of units, or of parts of a
-unit. To understand how this is proved, the pupil would require more
-knowledge than he can be supposed to have; but we can shew him that,
-for any thing he knows to the contrary, there may be quantities which
-are neither units nor parts of the unit. Take a mathematical line of
-one foot in length, divide it into ten parts, each of those parts into
-ten parts, and so on continually. If a point A be taken at hazard in
-the line, it does not appear self-evident that if the decimal division
-be continued ever so far, one of the points of division must at last
-fall exactly on A: neither would the same appear necessarily true if
-the division were made into sevenths, or elevenths, or in any other
-way. There may then possibly be a part of a foot which is no exact
-numerical fraction whatever of the foot; and this, in a higher branch
-of mathematics, is found to be the case times without number. What is
-meant in the words on which this note is written, is, that any part
-of a foot can be represented as nearly as we please by a numerical
-fraction of it; and this is sufficient for practical purposes.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_32" href="#FNanchor_32" class="label">[32]</a>
-Since this was first written, the accident has happened.
-The <i>standard yard</i> was so injured as to be rendered useless by
-the fire at the Houses of Parliament.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_33" href="#FNanchor_33" class="label">[33]</a>
-The minute and second are often marked thus, 1′, 1″: but
-this notation is now almost entirely appropriated to the minute and
-second of <i>angular</i> measure.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_34" href="#FNanchor_34" class="label">[34]</a>
-The measures in italics are those which it is most
-necessary that the student should learn by heart.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_35" href="#FNanchor_35" class="label">[35]</a>
-The lengths of the pendulums which will vibrate in one
-second are slightly different in different latitudes. Greenwich is
-chosen as the station of the Royal Observatory. We may add, that much
-doubt is now entertained as to the system of standards derived from
-nature being capable of that extreme accuracy which was once attributed
-to it.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_36" href="#FNanchor_36" class="label">[36]</a>
-The inch is said to have been originally obtained by
-putting together three grains of barley.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_37" href="#FNanchor_37" class="label">[37]</a>
-‘Capacity’ is a term which cannot be better explained than
-by its use. When one measure holds more than another, it is said to be
-more capacious, or to have a greater capacity.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_38" href="#FNanchor_38" class="label">[38]</a>
-This measure, and those which follow, are used for dry goods only.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_39" href="#FNanchor_39" class="label">[39]</a>
-Since the publication of the third edition, the <i>heaped</i> measure,
-which was part of the new system, has been abolished. The following
-paragraph from the third edition will serve for reference to it:</p>
-
-<p>“The other imperial measure is applied to goods which it is customary
-to sell by <i>heaped measure</i>, and is as follows:</p>
-
-<table border="0" cellspacing="0" summary=" " cellpadding="0" >
- <tbody><tr>
- <td class="tdl">2 gallons</td>
- <td class="tdl_ws1">1 peck</td>
- </tr><tr>
- <td class="tdl">4 pecks</td>
- <td class="tdl_ws1">1 bushel</td>
- </tr><tr>
- <td class="tdl">3 bushels</td>
- <td class="tdl_ws1">1 sack</td>
- </tr><tr>
- <td class="tdl">12 sacks</td>
- <td class="tdl_ws1">1 chaldron.</td>
- </tr>
- </tbody>
-</table>
-
-<p>The gallon and bushel in this measure hold the same when only just
-filled, as in the last. The bushel, however, heaped up as directed by the
-act of parliament, is a little more than one-fourth greater than before.”</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_40" href="#FNanchor_40" class="label">[40]</a>
-Pure water, cleared from foreign substances by
-distillation, at a temperature of 62° Fahr.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_41" href="#FNanchor_41" class="label">[41]</a>
-It is more common to divide the ounce into four quarters
-than into sixteen drams.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_42" href="#FNanchor_42" class="label">[42]</a>
-The English pound is generally called a <i>pound sterling</i>, which
-distinguishes it from the weight called a pound, and also from foreign coins.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_43" href="#FNanchor_43" class="label">[43]</a>
-The coin called a guinea is now no longer in use, but the
-name is still given, from custom, to 21 shillings. The pound, which was
-not a coin, but a note promising to pay 20 shillings to the bearer, is
-also disused for the present, and the sovereign supplies its place; but
-the name pound is still given to 20 shillings.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_44" href="#FNanchor_44" class="label">[44]</a>
-Farthings are never written but as parts of a penny.
-Thus, three farthings being &frac34; of a penny, is written &frac34;, or ¾. One
-halfpenny may be written either as 2/4 or ½; the latter is most common.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_45" href="#FNanchor_45" class="label">[45]</a>
-When a decimal follows a whole number, the decimal is
-always of the same unit as the whole number. Thus, 5ᔆ·5 is five
-<i>seconds</i> and five-tenths of a <i>second</i>. Thus, 0ᔆ·5 means
-five-tenths of a second; 0ʰ·3, three-tenths of an hour.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_46" href="#FNanchor_46" class="label">[46]</a>
-Before reading this article and the next, articles (29)
-and (42) should be read again carefully.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_47" href="#FNanchor_47" class="label">[47]</a>
-Any fraction of a unit, whose numerator is unity, is
-generally called an <i>aliquot part</i> of that unit. Thus, 2<i>s.</i>
-and 10<i>s.</i> are both aliquot parts of a pound, being £⅒ and £½.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_48" href="#FNanchor_48" class="label">[48]</a>
-A parallelepiped, or more properly, a <i>rectangular</i>
-parallelepiped, is a figure of the form of a brick; its sides, however,
-may be of any length; thus, the figure of a plank has the same name. A
-cube is a parallelepiped with equal sides, such as is a die.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_49" href="#FNanchor_49" class="label">[49]</a>
-This generally comes in the same member of the sentence.
-In some cases the ingenuity of the student must be employed in
-detecting it. The reasoning of (238) is the best guide. The following
-may be very often applied. If it be evident that the answer must be
-less than the given quantity of its kind, multiply that given quantity
-by the less of the other two; if greater, by the greater. Thus, in the
-first question, 156 yards must cost more than 22; multiply, therefore, by 156.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_50" href="#FNanchor_50" class="label">[50]</a>
-It is usual to place points, in the manner here shewn,
-between the quantities. Those who have read Section VIII. will see that
-the Rule of Three is no more than the process for finding the fourth
-term of a proportion from the other three.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_51" href="#FNanchor_51" class="label">[51]</a>
-Commission is what is allowed by one merchant to another
-for buying or selling goods for him, and is usually a per-centage
-on the whole sum employed. Brokerage is an allowance similar to
-commission, under a different name, principally used in the buying and
-selling of stock in the funds.</p>
-
-<p>Insurance is a per-centage paid to those who engage to make good to the
-payers any loss they may sustain by accidents from fire, or storms,
-according to the agreement, up to a certain amount which is named,
-and is a per-centage upon this amount. Tare, tret, and cloff, are
-allowances made in selling goods by wholesale, for the weight of the
-boxes or barrels which contain them, waste, &amp;c.; and are usually either
-the price of a certain number of pounds of the goods for each box or
-barrel, or a certain allowance on each cwt.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_52" href="#FNanchor_52" class="label">[52]</a>
-Here the 4<i>s.</i> from the dividend is taken in.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_53" href="#FNanchor_53" class="label">[53]</a>
-Here the 3<i>d.</i> from the dividend is taken in.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_54" href="#FNanchor_54" class="label">[54]</a>
-Sufficient tables for all common purposes are contained in the article
-on Interest in the Penny Cyclopædia; and ample ones in the Treatise on
-Annuities and Reversions, in the Library of Useful Knowledge.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_55" href="#FNanchor_55" class="label">[55]</a>
-This rule is obsolete in business. When a bill, for instance, of £100
-having a year to run, is <i>discounted</i> (as people now say) at 5 per
-cent, this means that 5 per cent of £100, or £5, is struck off.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_56" href="#FNanchor_56" class="label">[56]</a>
-This question does not at first appear to fall under the
-rule. A little thought will serve to shew that what probably will be
-the first idea of the proper method of solution is erroneous.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_57" href="#FNanchor_57" class="label">[57]</a>
-The teacher will find further remarks on this subject in
-the <i>Companion to the Almanac</i> for 1844, and in the <i>Supplement
-to the Penny Cyclopædia</i>, article <i>Computation</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_58" href="#FNanchor_58" class="label">[58]</a>
-And at discretion one hundredth more for a large fraction
-of three inches.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_59" href="#FNanchor_59" class="label">[59]</a>
-The student should remember all the multiples of 4 up to 4
-× 25, or 100.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_60" href="#FNanchor_60" class="label">[60]</a>
-The treatises on book-keeping have described this difference in
-as peculiar a manner. They call these accounts the <i>fictitious
-accounts</i>. Now they represent the merchant himself; their credits
-are gain to the business, their debits losses or liabilities. If
-the terms real and fictitious are to be used at all, they are the
-<i>real</i> accounts, end all the others are as <i>fictitious</i> as
-the clerks whom we have supposed to keep them.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_61" href="#FNanchor_61" class="label">[61]</a>
-This theorem shews that what is <i>called</i> reducing
-a fraction to its lowest terms (namely, dividing numerator and
-denominator by their greatest common measure), is correctly so called.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_62" href="#FNanchor_62" class="label">[62]</a>
-For that which measures a measure is itself a measure; so that if a
-measure of <i>a</i> could have a measure in common with <i>b</i>,
-<i>a</i> itself would have a common measure with <i>b</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_63" href="#FNanchor_63" class="label">[63]</a>
-A prime number is one which is prime to all numbers except
-its own multiples, or has no divisors except 1 and itself.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_64" href="#FNanchor_64" class="label">[64]</a>
-Expand (<i>a</i>-1)ᵇ by the binomial theorem; shew that
-<i>when b is a prime number</i> every coefficient which is not unity is
-divisible by <i>b</i>; and the proposition follows.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_65" href="#FNanchor_65" class="label">[65]</a>
-The principle of this mode of demonstration of Horner’s
-method was stated in Young’s Algebra (1823), being the earliest
-elementary work in which that method was given.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_66" href="#FNanchor_66" class="label">[66]</a>
-Various exceptions may arise when an equation has
-two nearly equal roots. But I do not here introduce algebraical
-difficulties; and a student might give himself a hundred examples,
-taken at hazard, without much chance of lighting upon one which gives
-any difficulty.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_67" href="#FNanchor_67" class="label">[67]</a>
-This form might be also applied to the integer portions;
-but it is hardly needed in such instances as usually occur. See the
-article <i>Involution and Evolution</i> in the <i>Supplement</i> to the
-<i>Penny Cyclopædia</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_68" href="#FNanchor_68" class="label">[68]</a>
-After the second step, the trial will rarely fail to give
-the true figure.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_69" href="#FNanchor_69" class="label">[69]</a>
-The solution of <i>x</i>³ + 0<i>x</i>² + 0<i>x</i>-2 = 0.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_70" href="#FNanchor_70" class="label">[70]</a>
-Taken from a paper on the subject, by Mr. Peter Gray, in the <i>Mechanics’ Magazine</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_71" href="#FNanchor_71" class="label">[71]</a>
-Taken from a paper on the subject, by Mr. Peter Gray, in the <i>Mechanics’ Magazine</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_72" href="#FNanchor_72" class="label">[72]</a>
-Taken from a paper on the subject, by Mr. Peter Gray, in the <i>Mechanics’ Magazine</i>.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_73" href="#FNanchor_73" class="label">[73]</a>
-Taken from the late Mr. Peter Nicholson’s Essay on Involution and Evolution.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_74" href="#FNanchor_74" class="label">[74]</a>
-Taken from the late Mr. Peter Nicholson’s Essay on Involution and Evolution.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_75" href="#FNanchor_75" class="label">[75]</a>
-Taken from the late Mr. Peter Nicholson’s Essay on Involution and Evolution.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_76" href="#FNanchor_76" class="label">[76]</a>
-Taken from the late Mr. Peter Nicholson’s Essay on Involution and Evolution.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_77" href="#FNanchor_77" class="label">[77]</a>
-A four-sided figure, which has two sides parallel, and two
-sides not parallel.</p>
-</div>
-
-<div class="footnote"><p class="no-indent">
-<a id="Footnote_78" href="#FNanchor_78" class="label">[78]</a>
-The right angle is divided into 90 equal parts called
-<i>degrees</i>, each degree into 60 equal parts called <i>minutes</i>,
-and each minute into 60 equal parts called <i>seconds</i>. Thus, 2° 15′
-40″ means 2 degrees, 15 minutes, and 40 seconds.</p>
-</div>
-</div>
-
-<div class="chapter">
-<div class="transnote bbox space-above2">
-<p class="f120 space-above1">Transcriber’s Notes:</p>
-<hr class="r5" />
-<p class="indent">The cover image was created by the transcriber, and is in the public domain.</p>
-<p class="indent">The illustrations have been moved so that they do not break up
- paragraphs and so that they are next to the text they illustrate.</p>
-<p class="indent">Typographical and punctuation errors have been silently corrected.</p>
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