312 Chapter 6 11 Differentiable FunctionsCorollary 6.2. 8 l::/r E Q, the power function f(x) = xr is differentiable every-
where on its domain, and fxxr = rxr-^1.Proof. Exercise 10. •LOGARITHM, EXPONENTIAL, AND POWER FUNCTIONSStudents who skipped Section 5.6 should skip the proofs of
the following theorem and its corollaries. These results will
be derived in the more customary way in Chapter 7.We adopt the conventional notation for the natural logarithm, lnx =loge x.
This function and ex were treated in detail in Section 5 .6.
Theorem 6.2.9 The functions f(x) = lnx and g(x ) = ex are differentiable
everywhere on their domains, and
d 1 d
(a) -lnx=-; (b) -ex=ex.
dx x dx*Proof. (a) Using the properties of logarithms,
lim ln( x + h) - ln x = lim ~ ln ( x + h)
h-+O h h-+O h X1
= lim ln ( x + h) T.:
h-+O X= ln [k~ (1 + ~) *] by Theorem 5.1.14 (b)
= ln e^1 fx by Corollary 5.6.20
1
x(b) The exponential function ex is the inverse of the logarithm function
lnx. That is, for f(x) = lnx we have f-^1 (x) =ex. Thus, by Theorem 6.2.4
with y = lnx,
d 1 1- eY = --= - = x = eY •
dy g dx lnx .!. x ·