Secondary special education of the republic of uzbekistan
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- Bu səhifədəki naviqasiya:
- Addition and multiplication
| Natural numbers
In a collection (or set) of objects (or elements), the act of determining the number of objects present is called counting. The numbers thus obtained are called the counting numbers or natural numbers (1, 2, 3, …). For an empty set, no object is present, and the count yields the number 0, which, appended to the natural numbers, produces what are known as the whole numbers. If objects from two sets can be matched in such a way that every element from each set is uniquely paired with an element from the other set, the sets are said to be equal or equivalent. The concept of equivalent sets is basic to the foundations of modern mathematics and has been introduced into primary education, notably as part of the “new math” (see the figure) that has been alternately acclaimed and decried since it appeared in the 1960s. Addition and multiplication Combining two sets of objects together, which contain a and b elements, a new set is formed that contains a + b = c objects. The number c is called the sum of a and b; and each of the latter is called a summand. The operation of forming the sum is called addition, the symbol + being read as “plus.” This is the simplest binary operation, where binary refers to the process of combining two objects. From the definition of counting it is evident that the order of the summands can be changed and the order of the operation of addition can be changed, when applied to three summands, without affecting the sum. These are called the commutative law of addition and the associative law of addition, respectively. If there exists a natural number k such that a = b + k, it is said that a is greater than b (written a > b) and that b is less than a (written b < a). If a and b are any two natural numbers, then it is the case that either a = b or a > b or a < b (the tracheotomy law). From the above laws, it is evident that a repeated sum such as 5 + 5 + 5 is independent of the way in which the summands are grouped; it can be written 3 × 5. Thus, a second binary operation called multiplication is defined. The number 5 is called the multiplicand; the number 3, which denotes the number of summands, is called the multiplier; and the result 3 × 5 is called the product. The symbol × of this operation is read “times.” If such letters as a and b are used to denote the numbers, the product a × b is often written a∙b or simply ab. If three rows of five dots each are written, as illustrated below, it is clear that the total number of dots in the array is 3 × 5, or 15. This same number of dots can evidently be written in five rows of three dots each, whence 5 × 3 = 15. The argument is general, leading to the law that the order of the multiplicands does not affect the product, called the commutative law of multiplication. But it is notable that this law does not apply to all mathematical entities. Indeed, much of the mathematical formulation of modern physics, for example, depends crucially on the fact that some entities do not commute. By the use of a three-dimensional array of dots, it becomes evident that the order of multiplication when applied to three numbers does not affect the product. Such a law is called the associative law of multiplication. If the 15 dots written above are separated into two sets, as shown, then the first set consists of three columns of three dots each, or 3 × 3 dots; the second set consists of two columns of three dots each, or 2 × 3 dots; the sum (3 × 3) + (2 × 3) consists of 3 + 2 = 5 columns of three dots each, or (3 + 2) × 3 dots. In general, one may prove that the multiplication of a sum by a number is the same as the sum of two appropriate products. Such a law is called the distributive law. Yüklə 416,26 Kb. Dostları ilə paylaş:
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