Divisibility of Numbers. 2. Tell which of the following are exactly divisible by 25, and why: 37625, 34836, 27950, 38575. 3. Every number, integral or mixed, is exactly divisible by 33, if that part of the number expressed by the figures to the right of the hundreds' figure is exactly divisible by 331. 4. Show why the statement made in No. 3 is correct, employing the thought process given in the "Explanatory Note" under No. 1 on the preceding page. 5. Tell which of the following are exactly divisible by 33, and why: 364663, 2375, 468331, 38900, 46820. 6. Any number, integral or mixed, is exactly divisible by 12, if the part of the number expressed by the figures to the right of the hundreds' figure, is exactly divisible by 12. Show why. 7. Tell which of the following are exactly divisible by 12, and why: 375, 837, 6450, 4329, 74671, 34871, 3425. 8. Any number, integral or mixed, is exactly divisible by 16, if........ 9. Tell which of the following are exactly divisible by 16, and why: 4633, 5460, 2350, 37400, 27583, 25416. 10. Any integral number is exactly divisible by 20 if the number expressed by its two right-hand figures is exactly divisible by 20. Show why. 11. Tell which of the following are exactly divisible by 20, and why: 3740, 2650, 3860, 29480, 3470. 12. Tell which of the following are exactly divisible by 50, and why: 2460, 3450, 6800, 27380, 25450. Divisibility of Numbers. 164. PROBLEMS. 1. How many times is 25 contained in 2450?* 165. Numbers exactly divisible by 9. 1. Any number is exactly divisible by 9 if the sum of its digits is exactly divisible by 9. EXPLANATORY NOTE.-Any number more than nine is a certain number of nines and as many over as the number indicated by the sum of its digits. Thus, 20 is two nines and 2 over; 41 is four nines and 4+1 over; 42 is four nines and 4 + 2 over; 200 is twenty-two nines and 2 over; 300 is thirty-three nines and 3 over; 320 is a certain number of nines and 3 + 2 over; 321 is a certain number of nines and 3+2+1 over. 326 is a certain number of nines and 3 + 2 + 6 over; but 3+2+ 6 11, or another nine and 2 over. = 2. Read the "Explanatory Note" carefully, and tell which of the following are exactly divisible by 9: 3256, 4266, 2314, 2574. Divisibility of Numbers. 167. PRIME FACTORS AND EXACT DIVISORS. 1. Any integral number is exactly divisible by each of its prime factors and by the product of any two or more of its prime factors. Thus, 30, (2 × 3 × 5), is exactly divisible by 2, by 3, by 5, and by (2 × 3), 6, and by (2 x 5), 10, and by (3 × 5), 15. 2. The exact integral divisors of 36, (2 × 2 × 3 × 3), are 2, 3, and 168. PRIME FACTORS, COMMON DIVISORS, AND GREATEST COMMON DIVISORS. 1. Any prime factor or any product of two or more prime factors common to two or more numbers is a common divisor of the numbers. Thus, the numbers 30, (2 × 3 × 5), and 40, (2 × 2 × 2 × 5), have the factors 2 and 5 in common. So the common divisors of 30 and 40 are 2, 5, and 10, and the greatest common divisor is 10. RULE.-To find the greatest common divisor of two or more numbers, find the product of the prime factors common to the numbers. 2. Find the g. c. d. of 50, 75, and 125.* 3. Find the g. c. d. of 80, 100, 140. 4. Find the g. c. d. of 48, 60, 72. 5. Find the g. c. d. of 64, 96, 256. The letters g. c. d. are sometimes used instead of the words greatest common divisor. Divisibility of Numbers. 6. Find the g. c. d. of 640 and 760. Operation. 640)760(1 640 120)640(5 600 Explanation. The number 760 is an integral number of times the g. c. d., whatever that may be; so is the number 640. We make an incomplete division of 760 by 640 and have as a remainder the number 120. Since 640 and 760 are each an integral number of times the g. c. d., their difference, 120, must be an integral number of times the g. c. d.: for, taking an integral number of times a thing from an integral number of times a thing, must leave an integral number of times the thing. Therefore, no number greater than 120 can be the g.c.d. But if 120 is an exact divisor of 640, it is also an exact divisor of 760, for it will be contained one more time in 760 than in 640. We make the trial and find that 120 is not an exact divisor of 640; there is a remainder of 40. Since 600, (120 × 5), and 640 are each an integral number of times the g. c. d., 40 must be an integral number of times the g. c. d. But if 40 is an exact divisor of 120 it is an exact divisor of 600, (120 × 5), and 640, (40 more than 600), and 760, (120 more than 640). We make the trial and find that it is an exact divisor of 120, and is therefore the g. c. d. of 640 and 760. From the foregoing learn that any number that is an exact divisor of two numbers is an exact divisor of their difference. 169. From the foregoing make a rule for finding the g. c. d. of two numbers and apply it to the following 5. Of 650 and 175. 10. Of 450 and 600. (a) Find the sum of the ten results. Algebra-Equations. 170. An equation is the expression of the equality of two pumbers or combinations of numbers. EQUATIONS. (1) 2+4+6=3+5+4 (3) 2x + x + 4 = 10 +9 1. Every equation is made up of two members. The part of the equation which is on the left of the sign of equality is called the first member; the part on the right of the sign of equality, the second member. 2. The first member of equation No. 1 (above) is 3. If the same number be added to each member of an equation, the equality will not be destroyed. 4. If the same number be subtracted from each member of an equation, the equality will not be destroyed. If x = 8, then x 3 8-3. = If a + b 16, then a + b = 16- c. 5. If each member of an equation be multiplied by the same number, the equality will not be destroyed. 6. If each member of an equation be divided by the same number, the equality will not be destroyed. |