CONTENTS. RATIO.... INVERSE RATIO... COMPOUND RATIO SIMPLE EQUATIONS.... EQUATION OF PAYMENTS.... 63 ANNUITIES.. 94 .... ..... The Author cannot too highly recommend to the Teacher the use of the Blackboard described on the following page. Great facility in comprehending the combinations and divisions of numbers will be acquired by this method. 1230 4 5 6 77 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31. 32 33 34 35 36 This page represents a black board with the numbers as high as 72 painted on its margins. There is also a box containing slips which will cover two, three, four, etc., as high as 12, and numbered accordingly; one of these the student will take in his hand and apply it to the painted numbers to perform addition or subtraction; thus, begin at 1 and take a slip marked 2, then 1 and 2 are 3, 3 and 2 are 5, 5 and 2 are 7, 7 and 2 are 9, etc., counting at least the lefthand column; then, to perform subtraction, begin at the bottom of the 1st column; thus, 36 minus 2 equals 34, 34-2=32, 32-2-30, 30-2=28, etc., until the top is reached; then taking a slip marked 3, begin with 1 or 2, or first with 1 and then with 2, and return to the top of the column as before, by subtraction; let this exercise be performed with all the slips, and as the larger numbers are taken, continue the additions to the bottom of the 2d column, and return as before. For multiplication and division first make a chalk mark after every two figures up to 24, and multiply; thus, once 2 are 2, twice 2 are 4, 3 times 2 are 6, 4 times 2 are 8, etc.; then the number of divisions is 12 and each division has 2 numbers; .. 12 is contained twice in 24, or 2 is contained 12 times, 2 is contained once in 2, in 4 twice, in 6 three times, in 8 four times, in 10 five times, in 12 six times, etc. When the student is familiar with multiplication and division by 2, let the numbers be separated into 3's, then 4's, etc., and let each be continued for 12 divisions; when all the divisions have been performed according to the steps, beginning with 2 and ending with 12, a multiplication and division table will be made. REM.-In multiplication the product of any two factors is the same by making either the multiplicand and the other the multiplier; so also in division, the divisor and the quotient may be substituted, as the dividend is the product of the divisor and quotient. REM.-The numbers, continued up to 144, should be painted on the sides of the board, 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 COMPLETE ARITHMETIC. DEFINITIONS. 1. Arithmetic is the science of numbers. 2. A Unit is a single thing; as, a book, one dollar, or simply one. 3. A Number is a unit or a collection of units; as, one, ten, five books, twenty-five dollars. 4. The numbers used in Arithmetic are all formed by combinations of the ten Arabic characters, called Figures; viz., 0, called zero or naught; 1, called one; 2, two; 3, three; 4, four; 5, five; 6, six; 7, seven; 8, eight; 9, nine. 5. Expressing a number either in writing or figures is called Notation, and reading the expression is called Numeration. 6. When numbers are used without reference to any object, they are called Abstract Numbers; as, five, twenty, etc.; but when they are applied to things, they are called Concrete; as, one book, ten men, four dollars, etc. 7. When concrete numbers express values of money, weights, measures, time, etc., they are called Denomi nate Numbers; as, dollars, pounds, shillings, pounds of weight, ounces, hours, minutes, etc. 8. When different denominations of either kind form but one number, it is called a Compound Number; as, £4 3s. 61., 2 lb. 1 oz. 3 pwt. and 2 gr. 9. Numbers of the same order and the same denomination are termed Like Numbers; other numbers are termed Unlike Numbers. REM.-Numbers expressing different species of the same genus are unlike, as horses and cows; while the same numbers expressed in the term of the genus are alike, as animals. MATHEMATICAL TERMS USED IN ARITHMETIC. 1. An affirmative sentence, or anything proposed for consideration, is a Proposition. 2. A self-evident proposition is called an Axiom. 3. A proposition made evident by a demonstration is called a Theorem. 4. When a proposition is used for developing a principle of Arithmetic, it is called a Problem. 5. Propositions given merely for solution, in order to impress the principles on the mind, are called Examples. 6. An obvious consequence of one or more propositions is called a Corollary. 7. An established custom, or an assumption without proof, is called a Postulate. REM. 1 and 1 are 2, 2 and 1 are 3, 3 and 1 are 4, 5 and 2 are 7, 6 and 3 are 9, etc., is the postulate which forms the basis of Arithmetic. |