When (a^(1/n))^m and (a^m)^(1/n)are both defined, then they are equal since each is the principal nth root of a^m In fact (a^m)^(1/n) is the principal nth root of a^m by definition, and (a^(1/n))^m can be shown to be the principal nth root of a^m by examining each of the four cases above. Next for m and n positive integers we have, from law E.3, Thus, a^(1/n) must be an nth root of a and consequently we define a^(1/n) to In this section we extend, by using nth roots, the set of exponents to include all rational numbers in such a way that the laws of exponents E.1-E.5 still hold.įor n, a positive integer, we first define what we mean by a^(1/n). In the last section we enlarged our collection of exponents to include the integers. If a = 0, then for all n,0 is the only nth root of 0, and thus 0 is the principal nth root of 0. If n is odd, then for all a, there is exactly one nth root of a, which is called the principal nth root.Ĥ. If n is even and a is negative, then there are no real nth roots of a.ģ. The positive nth root is called the principal nth root of a.Ģ. If n is even and a is positive, then there are two nth roots and one is the negative of the other. The various cases for nth roots of a real number a are as follows.ġ. However, -9 has no square roots since there is no real number b such that b^2 = -9. For example, 2 and -2 are square roots of 4, since 2^2 = 4 and (-2)^2 = 4. When n = 2 We say that b is a square root, and when n = 3 we say that b is a cube root. If a and b are real numbers, n is a positive integer, and This is called scientific notation.Įxample 6. We can use this idea to write any real number r in decimal form as a number s between 1 and 10, times an integral power of 10 that is, In general if n is a positive integer, then factoring 10^n from a decimal number moves the decimal point n places to the left, and factoring 10^-n moves the decimal point n places to the right. We see that factoring 10^5 from 132,000 moved the decimal point five places to the left, while factoring 10^-5 from 0.0000132 moved the decimal point five places to the right. Integral exponents can be used to write such numbers in a compact form. Large and small numbers in decimal form occur in scientific work. Click on "Solve Similar" button to see more examples. Let’s see how our math solver solves this and similar problems. We use the above definitions to simplify each of the following.Įxample 4. Furthermore, we will rewrite them without zero or negative exponents.Įxample 1. In the following examples we will use the new definitions and laws of exponents to simplify the given expressions. In fact E.5 may be written in the simpler form It is straightforward but tedious to show that all the laws of Section 5.1 hold for integral exponents. Note that in the above definitions, when the exponent is zero or negative, a cannot be zero. ![]() This definition gives us the following helpful rule Since 1/a^n is the only real number such that (1/a^n)a^n=1. ![]() Similarly, if n is a positive integer, then in order For a^-n to satisfy E.1, We would have Since 1 is the only real number such that 1a^n=a^n, we define If a!=0, then in order for a^0 to satisfy E.1, we would have We want laws E.1 through E.5 to hold for this larger set of exponents. In this section we will enlarge our set of exponents to include zero and the negative integers. Let’s see how our math solver simplifies this and similar problems. We use the laws of exponents to compute each of the following.Įxample 3. Each of these factors has n factors of x, so that altogether there are nm factors of x. In E.3 the expression (x^n)^m has m factors of x^n. ![]() Using associativity and commutativity of multiplication we have Since (xy)^n has n factors of xy, there are n factors of x and n factors of y. We will establish E.2 and E.3 below and leave E.4 and the rest of E.5 as exercises for the interested reader. ![]() Law E.1 and the first two parts of E.5 were established in Chapter 2. The justification of these laws involves nothing more than counting the number of factors in a given expression. If x and y are real numbers and m and n are positive integers, then Computations with exponents depend on the following five basic laws. The number x is called the base and n the exponent or power. Where x is any real number and n is a positive integer. In Chapter 3 we introduced the notation that
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