Complex Analysis/Complex Functions/Continuous Functions

In this section, we

introduce a 'broader class of limits' than known from real analysis (namely limits with respect to a subset of $\mathbb {C}$ ) and
characterise continuity of functions mapping from a subset of the complex numbers to the complex numbers using this 'class of limits'.

Limits of complex functions with respect to subsets of the preimage edit

We shall now define and deal with statements of the form

\lim _{z\to z_{0} \atop z\in B'}f(z)=w

for $B\subseteq \mathbb {C} ,f:B\to \mathbb {C} ,B'\subseteq B,w\in \mathbb {C}$ , and prove two lemmas about these statements.

Definition 2.2.1:

Let $B\subseteq \mathbb {C}$ be a set, let $f:B\to \mathbb {C}$ be a function, let $B'\subseteq B$ , let $z_{0}\in B'$ and let $w\in \mathbb {C}$ . If

\forall \varepsilon >0:\exists \delta >0:{\bigl (}z\in B'\cap B(z_{0},\delta )\Rightarrow |f(z)-w|<\varepsilon {\bigr )}

we define:

\lim _{z\to z_{0} \atop z\in B'}f(z):=w

Lemma 2.2.2:

Let $B\subseteq \mathbb {C}$ be a set, let $f:B\to \mathbb {C}$ be a function, let $B''\subseteq B'\subseteq B$ , let $z_{0}\in B''$ and $w\in \mathbb {C}$ . If

\lim _{z\to z_{0} \atop z\in B'}f(z)=w

then

\lim _{z\to z_{0} \atop z\in B''}f(z)=w

Proof: Let $\varepsilon >0$ be arbitrary. Since

\lim _{z\to z_{0} \atop z\in B'}f(z)=w

there exists a $\delta >0$ such that

z\in B'\cap B(z_{0},\delta )\Rightarrow |f(z)-w|<\varepsilon

But since $B''\subseteq B'$ , we also have $B''\cap B(z_{0},\delta )\subseteq B'\cap B(z_{0},\delta )$ , and thus

z\in B''\cap B(z_{0},\delta )\Rightarrow z\in B'\cap B(z_{0},\delta )\Rightarrow |f(z)-w|<\varepsilon

and therefore

\lim _{z\to z_{0} \atop z\in B''}f(z)=w

\Box

Lemma 2.2.3:

Let $B\subseteq \mathbb {C}$ , $f:B\to \mathbb {C}$ be a function, $O\subseteq B$ be open, $z_{0}\in O$ and $w\in \mathbb {C}$ . If

\lim _{z\to z_{0} \atop z\in O}f(z)=w

then for all $B'\subseteq B$ such that $z_{0}\in B'$ :

\lim _{z\to z_{0} \atop z\in B'}f(z)=w

Proof

Let $B'\subseteq B$ such that $z_{0}\in B'$ .

First, since $O$ is open, we may choose $\delta _{1}>0$ such that $B(z_{0},\delta _{1})\subseteq O$ .

Let now $\varepsilon >0$ be arbitrary. As

\lim _{z\to z_{0} \atop z\in O}f(z)=w

there exists a $\delta _{2}>0$ such that:

z\in B(z_{0},\delta _{2})\cap U\Rightarrow |f(z)-f(z_{0})|<\varepsilon

We define $\delta :=\min\{\delta _{1},\delta _{2}\}$ and obtain:

z\in B(z_{0},\delta )\cap B'\Rightarrow z\in B(z_{0},\delta )\Rightarrow z\in B(z_{0},\delta _{2})\cap U\Rightarrow |f(z)-f(z_{0})|<\varepsilon

\Box

Continuity of complex functions edit

We recall that a function

f:M\to M'

where $M,M'$ are metric spaces, is continuous if and only if

x_{l}\to x,l\to \infty \Rightarrow f(x_{l})\to f(x)

for all convergent sequences $(x_{l})_{l\in \mathbb {N} }$ in $M$ .

Theorem 2.2.4:

Let $B\subseteq \mathbb {C}$ and $f:B\to \mathbb {C}$ be a function. Then $f$ is continuous if and only if

\forall z_{0}\in B:\lim _{z\to z_{0} \atop z\in B}f(z)=f(z_{0})

Proof

Exercises edit

Prove that if we define
$f:\mathbb {C} \to \mathbb {C} ,f(z)={\begin{cases}{\dfrac {z^{2}}{|z|^{2}}}&:z\neq 0\\1&:z=0\end{cases}}$

then $f$ is not continuous at $0$ . Hint: Consider the limit with respect to different lines through $0$ and use theorem 2.2.4.