Power Series is Termwise Differentiable within Radius of Convergence

Theorem
Let $\ds \map f x := \sum_{n \mathop = 0}^\infty a_n \paren {x - \xi}^n$ be a power series about a point $\xi$.

Let $R$ be the radius of convergence of the series.

Then:
 * $\ds \frac \d {\d x} \map f x = \sum_{n \mathop = 0}^\infty \frac \d {\d x} a_n \paren {x - \xi}^n = \sum_{n \mathop = 1}^\infty n a_n \paren {x - \xi}^{n - 1}$

for $|x - \xi| < R$.

Proof
Let $\rho \in \R$ such that $0 \le \rho < R$.

From Power Series Converges Uniformly within Radius of Convergence, $\map f x$ is uniformly convergent on $\set {x: \size {x - \xi} \le \rho}$.

From Real Polynomial Function is Continuous, each of $\map {f_n} x = a_n \paren {x-\xi}^n$ is a continuous function of $x$.

From Power Rule for Derivatives:
 * $\dfrac \d {\d x} \paren {x-\xi}^n = n \paren {x-\xi}^{n - 1}$

and again from Real Polynomial Function is Continuous, each of $\dfrac \d {\d x} \map {f_n} x = n a_n \paren {x-\xi}^{n - 1}$ is a continuous function of $x$.

Then from Derivative of Uniformly Convergent Series of Continuously Differentiable Functions: