Taylor Series

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au
and

Department of Mathematics
University of Wisconsin, Madison
Madison, WI 53706 USA
ram@math.wisc.edu

Last updates: 1 December 2009

Taylor series

Taylor's theorem.

If $f (x) = a_{0} + a_{1} x + a_{2} x^{2} + \dots$ then $a_{l} = \frac{1}{l!} ({\frac{d^{l} f}{d x^{l}} |}_{x = 0}) .$
If $f : [a, b] \to ℝ$ and $N \in ℤ_{> 0}$ and $f^{(N)} : [a, b] \to ℝ$ is continuous and $f^{(N + 1)} : (a, b) \to ℝ$ exists then there exists $c \in (a, b)$ such that $f (b) = f (a) + f' (a) (b - a) + \frac{1}{2!} f ″ (a) {(b - a)}^{2} + \dots + \frac{1}{N!} f^{(N)} (a) {(b - a)}^{N} + \frac{1}{(N + 1)!} f^{(N + 1)} (c) {(b - a)}^{N + 1} .$

Remark. The following results follow from (a) after a tiny bit of algebra. $If f (a + x) = a_{0} + a_{1} x + a_{2} x^{2} + \dots then a_{l} = \frac{1}{l!} ({\frac{d^{l} f}{d x^{l}} |}_{x = 0}) .$ $If f (z) = a_{0} + a_{1} (z - a) + a_{2} {(z - a)}^{2} + \dots then a_{l} = \frac{1}{l!} ({\frac{d^{l} f}{d z^{l}} |}_{z = a}) .$

Remark. The special case $N = 1$ is the mean value theorem. The special case $N = 1$ and $f (a) = f (b)$ is Rolle's theorem. The last term in $f (a) + f' (a) (b - a) + \frac{1}{2!} f ″ (a) {(b - a)}^{2} + \dots + \frac{1}{N!} f^{(N)} (a) {(b - a)}^{N} + \frac{1}{(N + 1)!} f^{(N + 1)} (c) {(b - a)}^{N + 1}$ is Lagrange's form of the remainder.

		Proof of Taylor's theorem, part (a).
	Assume $f (x) = a_{0} + a_{1} x + a_{2} x^{2} + \dots = \sum_{i = 0}^{\infty} a_{i} x^{i}$ To show: $a_{l} = ({\frac{d^{l} f}{d x^{l}} \|}_{x = 0})$ for $l \in ℤ_{> 0}$ . We have $\begin{array}{rcl} \frac{d^{l} f}{d x^{l}} & = & \frac{d^{l}}{d x^{l}} \sum_{i = 0}^{\infty} a_{i} x^{i} \\ = & \sum_{i = l}^{\infty} (i - (l - 1)) (i - (l - 2)) \dots (i - 1) i a_{i} x^{i - l} \\ = & \sum_{i = l}^{\infty} (\prod_{j = 1}^{l} (i - (l - j))) a_{i} x^{i - l}, \end{array}$ by repeated differentiation. So $\begin{array}{rcl} {\frac{d^{l} f}{d x^{l}} \|}_{x = 0} & = & {\sum_{i = l}^{\infty} (\prod_{j = 1}^{l} (i - (l - j))) a_{i} x^{i - l} \|}_{x = 0} \\ = & (\prod_{j = 1}^{l} (l - (l - j))) a_{l} \\ = & l! a_{l} . \end{array}$ Solving for $a_{l}$ givs the required result.proof changed

		Proof of the mean value theorem.
	To show: there exists $c \in (a, b)$ such that $f (b) = f (a) + f' (c) (b - a) .$ First do the case: $f (a) = f (b)$ . Then, since $[a, b]$ is compact and connected and $f : [a, b] \to ℝ$ is continuous, $f ([a, b]) is compact and connected.$ So $f ([a, b])$ is a closed interval. So $f ([a, b]) = [\min, \max]$ for some $\min, \max \in ℝ$ . So there exists $c \in (a, b)$ such that $f (c) = \max$ . Then, if $ε \in ℝ_{> 0}$ is small enough $f (c + ε) \leq f (c)$ and $f (c - ε) \leq f (c)$ . So $f' (c) \geq 0$ and $f' (c) \leq 0$ . So $f' (c) = 0$ . Next do the case $f (a) \neq f (b)$ . Let $g (x) = - (\frac{f (b) - f (a)}{b - a}) (x - a) + f (x)$ . So $g (a) = f (a)$ and $g (b) = f (a)$ and $g' (x) = - (\frac{f (b) - f (a)}{b - a}) + f' (x) .$ So by the first case, there exists $c \in (a, b)$ with $g' (c) = 0$ . So $f' (c) - (\frac{f (b) - f (a)}{b - a}) = 0$ . So $f' (c) = \frac{f (b) - f (a)}{b - a}$ and $f (b) = f (a) + f' (c) (b - a)$ .

References [PLACEHOLDER]

[BG] A. Braverman and D. Gaitsgory, Crystals via the affine Grassmanian, Duke Math. J. 107 no. 3, (2001), 561-575; arXiv:math/9909077v2, MR1828302 (2002e:20083)