MA 3972-MA-Book April 11, 2018 17:21
Graphs of Functions and Derivatives 139(c, f(c))(a, f(a))(b, f(b))c xy
f0f′(c) = f(bb )^ – – f a(a)Figure 8.1-2Example 1
If f(x)=x^2 + 4 x−5, show that the hypotheses of Rolle’s Theorem are satisfied on the
interval [−4, 0] and find all values ofcthat satisfy the conclusion of the theorem. Check the
three conditions in the hypotheses of Rolle’s Theorem:
(1) f(x)=x^2 + 4 x−5 is continuous everywhere since it is polynomial.
(2) The derivativef′(x)= 2 x+4 is defined for all numbers and thus is differentiable on
(−4, 0).
(3) f(0)= f(−4)=−5. Therefore, there exists acin (−4, 0) such that f′(c)=0. To find
c, set f′(x)=0. Thus, 2x+ 4 = 0 ⇒x=−2, i.e.,f′(−2)=0. (See Figure 8.1-3.)
[–5, 3] by [–15, 10]
Figure 8.1-3Example 2
Letf(x)=
x^3
3
−
x^2
2
− 2 x+2. Using Rolle’s Theorem, show that there exists a numbercinthe domain off such that f′(c)=0. Find all values ofc.
Note f(x) is a polynomial and thus f(x) is continuous and differentiable everywhere.
Entery 1 =
x^3
3
−
x^2
2
− 2 x+2. The zeros ofy1 are approximately− 2 .3, 0.9, and 2.9i.e., f(− 2 .3)= f(0.9)= f(2.9)=0. Therefore, there exists at least onecin the interval
(− 2 .3, 0.9) and at least one c in the interval (0.9, 2.9) such that f′(c)=0. Use