Product rule for complex differentiation

Statement

Complex-differentiable at a point

Suppose ${\displaystyle U\subset \mathbb{C}}$ is an open subset and ${\displaystyle f,g:U\to \mathbb{C}}$ are functions. Suppose ${\displaystyle z_0\in U}$ is a point such that ${\displaystyle f,g}$ are both complex-differentiable at ${\displaystyle z_0}$. Define ${\displaystyle fg:U\to \mathbb{C}}$ as:

${\displaystyle fg:=z\mapsto f(z)g(z)}$

Then ${\displaystyle fg}$ is complex-differentiable at ${\displaystyle z_0}$ and:

${\displaystyle (fg{)}^{\prime }(z_0)=f^{\prime }(z_0)g(z_0)+f(z_0)g^{\prime }(z_0)}$

For holomorphic functions

Suppose ${\displaystyle U\subset \mathbb{C}}$ is an open subset and ${\displaystyle f,g:U\to \mathbb{C}}$ are holomorphic functions. Then the function ${\displaystyle fg:U\to \mathbb{C}}$ given by:

${\displaystyle fg:=z\mapsto f(z)g(z)}$

is also a holomorphic function, and for any ${\displaystyle z\in U}$, we have:

${\displaystyle (fg{)}^{\prime }(z)=f^{\prime }(z)g(z)+f(z)g^{\prime }(z)}$