6.2 Rules for Differentiation 311By the sequential criterion for derivatives, (f-^1 )' (J(x 0 )) = -(
1
)' •
f' XoExample 6.2.5 Consider the function f(x) = 3x + 5.
The inverse function is f-^1 (x) = x;
5. The derivatives off and f-^1 are
f'(x) = 3 and (f-^1 )' (x) = ~· D
Example 6.2.6 Consider the function f(x) = x^2 on the interval [O, +oo).
This function is 1-1 on [O, +oo) and the inverse function for this inter-val is f-^1 (x) = y'x. Theorem 6.2.4 says that (f-^1 )' (J(x)) = f'~x); that is,
(f-^1 )' (x^2 ) =_!_or (f-^1 )' (y) = -
1-. This is consistent with the formula you
2x 2,jfj
d 1
remember from elementary calculus: -d y'x = r,;· (See Example 6.1.5.) D
x 2vx
DERIVATIVES OF RATIONAL POWER FUNCTIONSHaving proved Theorem 6.2.4, we are now able to extend the power rule
d~xn = nxn-l to rational exponents. Up to this point we have proved this rule
only for integers n. In fact, until Section 5.5 (Exercise 5.5.15) we did not even
have a definition of xr for general r E Q. Our proof will be in two steps.
Theorem 6.2. 7 Let n E N, n =f-0. The function x:!. is differentiable every-
where on its domain, except at 0, and d~ x:!. = ~ x:!.-^1 if x =f-0.
Proof. Let n E N, n =f-0. Everywhere on its domain, the function x:!. is
1-1 and continuous, and is the inverse of the function xn (see E xercise 5.5.15).
Thus, letting y = f(x) = xn (restricting the domain to [O, oo) if n is even) we
have x = f-^1 (y) = y:!. and by Theorem 6.2.4,
By substituting y = xn (x = y:!.) into this equation, we have
u-1)' (y) = nx:-1
1In summary, if g(y) = y:!., then g'(y) = ~ y:!.-^1. •