Cauchy's Integral Formula
Cauchy's Integral Formula is a fundamental result in complex analysis. It states that if is a subset of the complex plane containing a simple counterclockwise loop and the region bounded by , and is a complex-differentiable function on , then for any in the interior of the region bounded by ,
Proof
Let denote the interior of the region bounded by . Let denote a simple counterclockwise loop about of radius . Since the interior of the region bounded by is an open set, there is some such that for all . For such values of , by application of Cauchy's Integral Theorem.
Since is differentiable at , for any we may pick an arbitarily small such that whenever . Let us parameterize as , for . Since (again by Cauchy's Integral Theorem), it follows that Since and can simultaneously become arbitrarily small, it follows that which is equivalent to the desired theorem.
Consequences
By induction, we see that the th derivative of at is for . In particular, the th derivative exists at , for all . In other words, if a function is complex-differentiable on some region, then it is infinitely differentiable on the interior of that region.