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The two most basic operations of arithmetic are Addition and Subtraction . Multiplication is specialized form of addition where you quickly add identical numbers and Division is a specialized form of subtraction where you quickly remove identical numbers. The use of Subtractive Notation with Roman numerals increased the complexity of performing basic arithmetic operations without conveying the benefits of a full positional notation system. In the Algorithms that follow, the first step is to remove the subtractive notation from the numerals before any arithmetic operations. The subtractive notation is then reapplied to the solution as the end of the operation. The Roman Abacus was a hand-held tool for assisting in the computations using Roman numerals. BASIC OPERATIONS All arithmetic operations can be broken down to combinations of addition and subtraction. Addition Example CXVI + XXIV = ? Solution: CXVI + XXIV = CXL Discussion Step 1 decodes the positional data in the terms and replaces it with primitive counts. Now represented as a pure counting system, the concatenation of the terms in Step 2 gives the correct solution to the problem: CXVIXXIIII represents the same number as CXL - both terms convert to 140 in Arabic numerals. Steps 3 & 4 now reduce the result to the simplest expression possible and Step 5 reintroduces subtractive notation transforming the result back into a positional number. Subtraction Example CXVI − XXIV = ? Solution: CXVI − XXIV = XCII Discussion Step 1 decodes the positional data in the terms and replaces it with primitive counts. In Step 2, like numerals are eliminated from both terms: a count of X and a count of I are each removed from each term, leaving a simplified problem of CV − XIII. Step 3 then expands the first term until it contains a common numeral (X) to the highest numeral in the second term. Step 2 is then repeated, followed by Step 3 until all of the numerals in the second term have been eliminated. Once all of the numerals of have been eliminated, the remaining numerals in the first term represent the solution as a primitive count. Step 5 reintroduces subtractive notation transforming the result back into a positional number. COMPOUND OPERATIONS Having defined the process where by addition and subtraction operations can be performed using only Roman numerals, the other two traditional operations of arithmetic, multiplication and division, can now be accomplished. Multiplication ''multiplicand × multiplicator = product'' Example XIV × VII = ? Solution: XIV × VII = XCVIII Discussion Step 1 decodes the positional data in the terms and replaces it with primitive counts. Step 2 adds the multiplicand to product. Since subtractive notation has been removed in Step 1 and is later encoded in Step 5, there is no longer a requirement to perform the same processes when performing addition or subtraction within the multiplication operation. Step 3 reduces the number if iterations remaining for the addition operation in Step 2 by decreasing the value of the multiplicator. Step 5 reintroduces subtractive notation transforming the result back into a positional number. Division ''dividend / divisor = quotient'' Example CXXI / V = ? Solution: CXXI / V = XXIV remainder I Discussion Step 1 decodes the positional data in the terms and replaces it with primitive counts. Step 2 subtracts the divisor from the dividend. Since subtractive notation has been removed in Step 1 and is later encoded in Step 5, there is no longer a requirement to perform the same processes when performing addition or subtraction within the division operation. Step 3 increases the counter used for the quotient if remaining count of the dividend is greater than the divisor. Step 5 reintroduces subtractive notation transforming the result back into a positional number. |
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