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.15375 (2250

13500

6.83 gals. Ans.

18750

18000

7500

6750

750

Instead of reducing the divisor to mills or thousandths, we may reduce the dividend to cents or hundredths, thus $15.375 are 1537.5 cents. The question is now, to find how many times 225 cents are contained in 1537.5 cents. This is now the same as the case where there were decimals in the dividend only, the divisor being a whole number.

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If 3.15 bushels of oats will keep a horse 1 week, how many weeks will 37.5764 bushels keep him?

The question is, to find how many times 3.15 is contained in 37.5764. The dividend contains ten thousandths. The divisor is 31500 ten thousandths.

375764 (31500

31500

11.929 weeks. Ans.

60764

31500

292640

283500

91400

63000

284000

283500

500

Instead of reducing the divisor to ten-thousandths, we may reduce the dividend to hundredths. 37.5764 are 3757.64 hundredths of a bushel. The decimal .64 in this, is a fraction of an hundredth.

3.15 are 315 hundredths. Now the question is, to find how many times 315 hundredths are contained in 3757.64 hundredths.

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From the two last examples we derive the following rule for division: When the dividend contains more decimal places than the divisor: Reduce them both to the same denomination, and divide as in whole numbers.

N. B. There are two ways of reducing them to the same denomination. First, the divisor may be reduced to the same denomination as the dividend, by annexing zeros, and taking away the points from both. Secondly, the dividend may be reduced to the same denomination as the divisor, by taking away the point from the divisor, and removing it in the dividend towards the right as many places as there are in the divisor. The second method is preferable.

The same result may be produced by another mode of reasoning. The quotient must be such a number, that being multiplied with the divisor will reproduce the dividend. Now a product must have as many decimal places as there are in the multiplier and multiplicand both. Consequently the decimal places in the divisor and quotient together must be equal to those in the dividend. In the last example there were four decimal places in the dividend and two in the divisor; this would give two places in the quotient. Then a zero was annexed in the course of the division, which made three places in the quotient. The rule may be expressed as follows:

Divide as in whole numbers, and in the result, point off as many places for decimals as those in the dividend exceed those in the divisor. If zeros are annexed to the dividend, count them as so many decimals in the dividend. If there are not so many places in the result as are required, they must be supplied by writing zeros on the left.

Division in decimals, as well as in whole numbers, may be expressed in the form of common fractions.

What part of .5 is .3? Ans.
What part of .08 is .05? Ans. g.
What part of .19 is .43? Ans..

What part of .3 is .07?

To answer this, .3 must be reduced to hundredths. .3 is .30, the answer therefore is 7.

What part of 14.035 is 3.8?

3.8 is 3.800, the answer therefore is 3800

14033

In fine, to express the division of one number by another, when either or both contain decimals, reduce them both to the lowest denomination mentioned in either, and then write the divisor under the dividend, as if they were whole numbers.

Circulating Decimals.

56

333

=

XXIX. There are some common fractions which cannot be expressed exactly in decimals. If we attempt to change to decimals for example, we find .3333, &c. there is always a remainder 1, and the same figure 3 will always be repeated however far we may continue it. At each division we approximate ten times nearer to the true value, and yet we can never obtain it. : .1666, &c.; this begins to repeat at the second figure. T=.545454, &c.; this repeats two figures. In the division the remainders are alternately 6 and 5. .168168, &c.; this repeats three figures, and the remainders are alternately 56, 227, and 272. Some do not begin to repeat until after two or three or more places. It is evident that whenever the same remainder recurs a second time, the quotient figures and the same remainders will repeat over again in the same order. In the last example for instance, the number with which we commenced was 56; we annexed a zero and divided; this gave a quotient 1, and a remainder 227; we annexed another zero, and the quotient was 6, and the remainder 272; we annexed another zero, and the quotient was 8, and the remainder 56, the number we commenced with. If we annex a zero to this, it is evident that we shall obtain the same quotient and the same remainder as at

first, and that it will continue to repeat the same three figures for ever.

It is evident that the number of these remainders, and consequently the number of figures which repeat, must be one less than the number of units in the divisor. If the fraction is, there can be only six different remainders; after this number, one of them must necessarily recur again, and then the figures will be repeated again in the same order.

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Whenever we find that a fraction begins to repeat, we may write out as many places as we wish to retain, without the trouble of dividing.

As it is impossible to express the value of such a fraction by a decimal exactly, rules have been invented by which operations may be performed on them, with nearly as much accuracy as if they could be expressed; but as they are long and tedious, and seldom used, I

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