336 Chapter 6 m Differentiable FunctionsAlso, letting t = x in Equation (6), we find
n J(kl(x) (x xr+1
G(x) = f(x) + 2::-k-! -(x - x)k + Rn(x) (x = a)n+l = f(x) + 0 + 0 = f(x).
k=lThus, G(a) = G(x). Hence, G satisfies all the hypotheses of Rolle's theorem
on the closed interval between a and x. Therefore, by Rolle's theorem, 3 c
between a and x such thatG'(c) = 0.
By Equation (7) this meansj(n+ll(c)( _ )n_ (n+l)(x-c)nR ( )=O
n! x c (x - a)n+l n x.Solving for Rn ( x), we have
(x - ar+l J(n+ll(c) n
Rn(x) = · (x-c)
(n + l)(x - c)n n!J(n+ll(c) n+l
( n+ 1. )' (x - a). •APPLICATIONS OF TAYLOR'S THEOREMExample 6.5.12 Use Taylor's theorem to prove that 'v'x > 0,
x2 x3 x2 x3
1 + x + - + - < ex < 1 + x + - + - ex.
2 3! 2 3!Solution: Let x > 0. We use the Taylor polynomial T 2 (x) for ex about 0.
Using the notation of Definition 6.5.9, 'v'n E N,2
That is, ex = 1 + x + ~ + R 2 ( x). By Taylor's theorem, 3 c between 0 and
ec
x such that R2(x) =
3
! x^3. Thus, for some c between 0 and x,
x2 ec
ex = 1 + x + - + - x^3.
2 3!