Holomorphic function: Difference between revisions

Revision as of 18:19, 16 April 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 $\mathbb {C}$ . A function $f:U\to \mathbb {C}$ 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 $f':U\to \mathbb {C}$ we obtain as the derivative, is a continuous function.
$f$ is infinitely often complex-differentiable. In other words, we can take the $n^{th}$ 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 $(z-z_{0})$

Definition for functions in several variables

Let $U$ be an open subset (not necessarily connected, though we may restrict attention to connected subsets). A function $f:U\to \mathbb {C}$ 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, and its partial derivatives in all directions are continuous functions
$f$ is infinitely often complex-differentiable. In other words, we can take any sequence of mixed partial derivatives of $f$
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 $z-z_{0}$

Equivalence of definitions

Definitions (1) and (2) are equivalent as a consequence of Morera's theorem.

@@ Line 1: / Line 1: @@
 ==Definition==
-===Definition with symbols===
+===Definition for one-variable function===
-Let <math>\Omega</math> be an open subset of <math>\mathbb{C}</math>. A function <math>f:U \to \mathbb{C}</math> is termed a '''holomorphic function''' if it satisfies the following equivalent conditions:
+Let <math>U</math> be an open subset (not necessarily connected, though we can for practical purposes restrict ourselves to [[domain]]s -- connected open subsets) of <math>\mathbb{C}</math>. A function <math>f:U \to \mathbb{C}</math> is termed a '''holomorphic function''' if it satisfies the following equivalent conditions:
 # <math>f</math> is [[complex-differentiable function|complex-differentiable]] at every point of <math>U</math>
 # <math>f</math> is [[complex-differentiable function|complex-differentiable]] at every point of <math>U</math>, and the function <math>f':U \to \mathbb{C}</math> we obtain as the derivative, is a continuous function.
 # <math>f</math> is infinitely often complex-differentiable. In other words, we can take the <math>n^{th}</math> derivative of <math>f</math> for any <math>n</math>
-# For any point <math>z_0 \in U</math>, and any disc centered at <math>z</math> of radius <math>r</math>, that lies completely inside <math>U</math>, <math>f</math> can be expressed using a power series in <math>(z - z_0)</math>
+# For any point <math>z_0 \in U</math>, and any disc centered at <math>z_0</math> of radius <math>r</math>, that lies completely inside <math>U</math>, <math>f</math> can be expressed using a power series in <math>(z - z_0)</math>
+===Definition for functions in several variables===
+Let <math>U</math> be an open subset (not necessarily connected, though we may restrict attention to connected subsets). A function <math>f:U \to \mathbb{C}</math> is termed a '''holomorphic function''' if it satisfies the following equivalent conditions:
+# <math>f</math> is [[complex-differentiable function|complex-differentiable]] at every point of <math>U</math>
+# <math>f</math> is complex-differentiable, and its partial derivatives in all directions are continuous functions
+# <math>f</math> is infinitely often complex-differentiable. In other words, we can take any sequence of mixed partial derivatives of <math>f</math>
+# For any point <math>z_0 \in U</math>, and any disc centered at <math>z_0</math> of radius <math>r</math>, that lies completely inside <math>U</math>, <math>f</math> can be expressed using a power series in <math>z - z_0</math>
 ===Equivalence of definitions===
 Definitions (1) and (2) are equivalent as a consequence of [[Morera's theorem]].