Holomorphic function: Difference between revisions

Revision as of 22:03, 3 May 2008

Definition

Definition for one-variable function

Let $U$ be an open subset (not necessarily connected, though we can for practical purposes restrict ourselves to domains -- connected open subsets) of $C$ . A function $f : U \to C$ is termed a holomorphic function if it satisfies the following equivalent conditions:

$f$ is complex-differentiable at every point of $U$
$f$ is complex-differentiable at every point of $U$ , and the function $f^{'} : U \to C$ we obtain as the derivative, is a continuous function.
$f$ is infinitely often complex-differentiable. In other words, we can take the $n^{t h}$ derivative of $f$ for any $n$
For any point $z_{0} \in U$ , and any disc centered at $z_{0}$ of radius $r$ , that lies completely inside $U$ , $f$ can be expressed using a power series in $(z - z_{0})$
$f$ is a continuous function and satisfies the Cauchy-Riemann differential equations at every point in $U$
$f$ is a continuous function and its integral along the boundary of any triangle contained completely inside $U$ is zero.

Equivalence of definitions

For equivalence of (2), (3), (4), refer complex-analytic implies holomorphic and holomorphic implies complex-analytic
Goursat's lemma and Morera's theorem establish the equivalence of (1), (2) and (6)
Looman-Menchoff theorem establishes the equivalence with (5).

Definition on Riemann surfaces

Let $M$ be a Riemann surface. A holomorphic function on $M$ is a map from $M$ to $C$ whose restriction to any coordinate chart is a holomorphic function in the usual sense.

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 * [[Goursat's lemma]] and [[Morera's theorem]] establish the equivalence of (1), (2) and (6)
 * [[Looman-Menchoff theorem]] establishes the equivalence with (5).
+===Definition on Riemann surfaces===
+Let <math>M</math> be a [[Riemann surface]]. A '''holomorphic function''' on <math>M</math> is a map from <math>M</math> to <math>\mathbb{C}</math> whose restriction to any coordinate chart is a [[holomorphic function]] in the usual sense.