278 Chapter 5 • Continuous Functionsexponent) to derive an important property of the function f(x) =ax (constant
base). Thus, the developments of these two functions are interrelated.
The disadvantage of this "early" approach to exponential and logarithm
functions is that it requires a rather difficult and tedious, "brute-force" ap-
proach. On the other hand, it puts to use many of the concepts and techniques
we have developed so far. You will see.EXPONENTIAL FUNCTIONSLet a be any positive real number. In Exercise 5.5.15(b ), we showed that
Vr E Q, ar is defined and positive. We now extend this definition to obtain a
function f(x) =ax defined for all x ER First, we need a few technical lemmas.Lemma 5.6.1 For each a > 1 the exponential function f : Q __, JR given by
f(r) = ar (as defined in Exercise 5.5.15) is positive and strictly increasing on
Q. For each 0 <a< 1 the exponential function f: Q __,JR given by f(r) = ar
(as defined in Exercise 5.5.15) is positive and strictly decreasing on Q.Proof. Suppose a > 1. Let r < sin Q. Then 3 m , n E Zand 3p EN 3
r = m/p, s = n/p and m < n. Then an-m ~ a > 1. Thus,By Exercise 5.5.14, x^1 1P is strictly increasing on [O, +oo), so(am)I/p < (an)I/p
ar = amfp < anfp =as.Thus, f is strictly increasing on Q.
1
For 0 <a< 1, f(r) = ar = (~r, and the desired result follows from theabove argument, since ~ > 1. •
Lemma 5.6.2 Given any x E JR, there exists a monotone increasing sequence
{rn} of rational numbers converging to x.Proof. Exercise 1. •Lemma 5.6.3 Let a ~ 1 and x E R If {rn} is any monotone increasing
sequence of rational numbers converging to x, then { arn } converges.Proof. Let a ~ 1 and x E R Suppose {rn} is any monotone increasing
sequence of rational numbers converging to x. Since the function f : Q __, JR
given by f ( r) = ar is strictly increasing, { arn } is monotone increasing. If r is