Proof that holomorphic functions are analytic

In complex analysis, a complex-valued function f of a complex variable

is holomorphic at a point a iff it is differentiable at every point within some open disk centered at a, and
is analytic at a if in some open disk centered at a it can be expanded as a power series

(this implies that the radius of convergence is positive).

One of the most important theorems of complex analysis is that holomorphic functions are analytic. Among the corollaries of this theorem are

the fact that two holomorphic functions that agree at every point in some infinite bounded set agree everywhere in some open set, and
the fact that holomorphic functions are differentiable not just once, but infinitely often, and
the fact that the radius of convergence is always the distance from the center a to the nearest singularity; if there are no singularities (i.e., if f is an entire function), then the radius of convergence is infinite. Strictly speaking, this is not a corollary of the theorem but rather a by-product of the proof.

Table of contents

1 Proof
2 The generalized Cauchy integral formula
3 A by-product of the proof

Proof

Suppose f is differentiable everywhere within some open disk centered at a. Let z be within that open disk. Let C be a positively oriented (i.e., counterclockwise) circle centered at a, lying within that open disk but farther from a than z is. Then, using Cauchy's integral formula, we get

Since the factor (z − a)ⁿ does not depend on the variable of integration w, it can be pulled out:

And now the integral and the factor of 1/(2πi) do not depend on z, i.e., as a function of z, that whole expression is a constant c_n, so we can write:

and that is the desired power series.

The generalized Cauchy integral formula

The fact that the coefficient is given by

is a generalization of Cauchy's integral formula, since the latter is just the case in which n = 0.

The argument works if z is any point that is closer to the center than is any singularity of f. Therefore the radius of convergence of the power series cannot be smaller than the distance from the center to the nearest singularity (nor can it be larger, since power series have no singularities in the interiors of their circles of convergence).