Topology and Continuous functions

Topological spaces and Continuous functions

Arun Ram
Department of Mathematics and Statistics
University of Melbourne
Parkville, VIC 3010 Australia
aram@unimelb.edu.au

Last updates: 4 March 2014

Topological spaces

A topological space is a set $X$ with a specification of the open subsets of $X$ where it is required that

(a)

\emptyset

is open and

X

is open,

(b) Unions of open sets are open,

In other words, a topology on

X

is a set

𝒯

of subsets of

X

such that

(a)

\emptyset \in 𝒯

and

X \in 𝒯

(b) If

𝒮 \subseteq 𝒯

then

(⋃_{U \in 𝒮} U) \in 𝒯

n \in ℤ_{\geq 0}

and

U_{1} U_{2} \dots U_{n} \in 𝒯

then

U_{1} \cap U_{2} \cap \dots \cap U_{n} \in 𝒯 .

A topological space is a set $X$ with a topology $𝒯$ on $X$ .

Let $X$ be a set and let $𝒯$ be a topology on $X$ .

An open set is a set in $𝒯$ .
A closed set is a subset $E$ of $X$ such that the complement $E^{c}$ of $E$ is open.
A connected set is a subset $E \subseteq X$ such that there do not exist open sets $A$ and $B$ with $A \cap E \neq \emptyset, B \cap E \neq \emptyset, A \cup B \supseteq E, and (A \cap B) \cap E = \emptyset .$
A compact set is a subset $E \subseteq X$ such that every open cover of $E$ contains a finite subcover.
More precisely, a compact set is a subset $E \subseteq X$ such that

if $𝒮 \subseteq 𝒯$ and $⋃_{U \in 𝒮} U \supseteq E$

then there exists $n \in ℤ_{> 0}$ and $U_{1}, \dots, U_{n} \in 𝒮$ such that $(U_{1} \cup U_{2} \cup \dots \cup U_{n}) \supseteq E .$

HW: Let $X$ be a topological space. Let $𝒞$ be the collection of closed sets of $X .$ Show that $𝒞$ satisfies:

(Ca)	If $𝒮 \subseteq 𝒞$ then $⋂_{C \in 𝒮} C \in 𝒞 .$
(Cb)	If $ℓ \in ℤ_{> 0}$ and $C_{1}, C_{2}, \dots, C_{ℓ} \in 𝒞$ then $C_{1} \cup \dots \cup C_{ℓ} \in 𝒞 .$

HW: Let $X$ be a set and let $𝒞$ be a collection of subsets of $X$ which satisfies (Ca) and (Cb).

(a)	Show that $𝒯 = {A \subseteq X \| A^{c} \in 𝒞}$ is a topology on $X$ such that $𝒞$ is the set of closed sets in $X .$
(b)	Show that $𝒯$ is the unique topology on $X$ such that $𝒞$ is the set of closed sets in $X .$

Continuous Functions

Continuous functions are for comparing topological spaces.

Let $X$ and $Y$ be topological spaces.

A function $f : X \to Y$ is continuous if it satisfies the condition
if $V$ is an open subset of $Y$ then $f^{- 1} (V)$ is an open subset of $X$ .
Let $X$ and $Y$ be topological spaces. An isomorphism, or homeomorphism, is a continuous function $f : X \to Y$ such that the inverse function $f^{- 1} : Y \to X$ exists and is continuous.
A subspace of $X$ is a subset $E$ of $X$ with the topology given by making the open sets be the sets $ι^{- 1} (V) such that V is an open subset of X,$ where $ι : E \to X$ is the inclusion.

Let $f : X \to Y$ be a continuous function and let $E \subseteq X$ .

(a) If

E

is connected then

f (E)

is connected.

(b) If

E

is compact then

f (E)

is compact.

		Proof of (a):
	Proof by contradiction. Assume $f (E)$ is not connected. Let $A$ and $B$ be open in $f (E)$ such that $A \neq \emptyset$ and $B \neq \emptyset$ and $A \cup B \supseteq f (E)$ and $A \cap B = \emptyset$ . Then let $C = f^{- 1} (A)$ and $D = f^{- 1} (B)$ . Then $C \cup D = f^{- 1} (A) \cup f^{- 1} (B) = f^{- 1} (A \cup B) \supseteq f^{- 1} (f (E)) \supseteq E$ , and $C \cap D = f^{- 1} (A) \cap f^{- 1} (B) = f^{- 1} (A \cap B) = f^{- 1} (\emptyset) = \emptyset$ . Now $C \neq \emptyset$ since $A \neq \emptyset$ and $A \subseteq f (E)$ , and $D \neq \emptyset$ since $B \neq \emptyset$ and $B \subseteq f (E)$ . So $E$ is not connected. This is a contradiction. So $f (E)$ is connected. $□$

		Proof of (b):
	Assume $f : X \to Y$ is continuous and $E$ is compact. To show: If $𝒮$ is an open cover of $f (E)$ then it has a finite subcover. To show: If $𝒴$ is the topology on $Y$ , $𝒮 \subseteq 𝒴$ , and $(⋃_{V \in 𝒮} V) \supseteq f (E)$ then there exists $n \in ℤ_{> 0}$ and $V_{1}, \dots, V_{n} \in 𝒮$ such that $V_{1} \cup \dots \cup V_{n} \supseteq f (E)$ . Assume $𝒴$ is the topology on $Y$ and $𝒮 \subseteq 𝒴$ and $(⋃_{V \in 𝒮} V) \supseteq f (E)$ . Then $(⋃_{V \in 𝒮} f^{- 1} (V)) \supseteq E$ . Let $𝒯 = {f^{- 1} (V) \| V \in 𝒮}$ . Since $f$ is continuous, $f^{- 1} (V)$ is open. Thus $𝒯 \subseteq 𝒳$ where $𝒳$ is the topology of $X$ , and also $(⋃_{f^{- 1} (V) \in 𝒯} f^{- 1} (V)) \supseteq E$ . Since $E$ is compact there exists $n \in ℤ_{> 0}$ and $f^{- 1} (V_{1}), \dots, f^{- 1} (V_{n}) \in 𝒯$ such that $(f^{- 1} (V_{1}) \cup \dots \cup f^{- 1} (V_{n})) \supseteq E$ . So $(V_{1} \cup \dots \cup V_{n}) \supseteq f (E)$ . Thus $𝒮$ contains a finite subcover of $f (E)$ . $□$

Let $Y$ be a topological space. Let $y \in Y$ .

A neighbourhood of $y$ is a subset $N \subseteq Y$ such that there exists an open set $U$ of $Y$ with $y \in U \subseteq N$ .
The neighbourhood filter of $y$ is
$𝒩 (y) = {neighborhoods of y}$ .

Let $X$ and $Y$ be topological spaces. Let $a \in X$ .

A function $f : X \to Y$ is continuous at $a$ if it satisfies the condition
if $V$ is a neighborhood of $f (a)$ in $Y$ then $f^{- 1} (V)$ is a neighborhood of $a$ in $X$ .
Here $f^{- 1} (V) = {x \in X | f (x) \in V} .$

HW: Let $X$ and $Y$ be topological spaces and let $f : X \to Y$ be a function. Show that $f : X \to Y$ is continuous if and only if $f satisfies: if a \in X then f is continuous at a .$

HW: Let $X$ be a topological space. For $x \in X$ let $𝒩 (x)$ be the set of neighborhoods of $x .$ Show that the collections $𝒩 (X)$ satisfy:

$(V_{I})$	If $A \subseteq X$ and there exists $N \in 𝒩 (x)$ such that $A \supseteq N$ then $A \in 𝒩 (x) .$
$(V_{II})$	If $ℓ \in ℤ_{> 0}$ and $N_{1}, N_{2}, \dots, N_{ℓ} \in 𝒩 (x)$ then $N_{1} \cap N_{2} \cap \dots \cap N_{ℓ} \in 𝒩 (x) .$
$(V_{III})$	If $N \in 𝒩 (x)$ then $x \in N .$
$(V_{IV})$	If $N \in 𝒩 (x)$ then there exists $W \in 𝒩 (x)$ such that if $y \in W$ then $N \in 𝒩 (y) .$

HW: Let $X$ be a set with a collection of subsets of $X,$ $𝒩 (x)$ for each $x \in X,$ such that the $𝒩 (x)$ satisfy $(V_{I}), (V_{II}), (V_{III}), (V_{IV}) .$ Let $𝒯 = {A \subseteq X | if x \in A then A \in 𝒩 (x)} .$

(a)	Show that $𝒯$ is a topology on $X .$
(b)	Show that the $𝒩 (x),$ $x \in X,$ are the neighborhood filters for the topology $𝒯 .$
(c)	Show that $𝒯$ is the unique topology on $X$ such that $𝒩 (x),$ $x \in X,$ are the neighborhood filters for $𝒯 .$

Let $I$ be a set and let $X_{i},$ $i \in I,$ be topological spaces.

The product space $\prod_{i \in I} X_{i}$ is the set $\prod_{i \in I} X_{i}$ with topology generated by the sets ${pr}_{i} (U_{i}) with U_{i} open in X_{i},$ where ${pr}_{i} : \prod_{i \in I} X_{i} \to X_{i}$ is the projection (onto the $i^{th}$ coordinate).

HW: Show that the topology on $\prod_{i \in I} X_{i}$ is the weakest topology such that the projections ${pr}_{i} : \prod_{i \in I} X_{i} \to X_{i},$ for $i \in I,$ are continuous.

Examples

(1) Let $X$ be a set. The discrete topology on $X$ is the topology such that every subset of $X$ is open.

(2) A metric space is a set $X$ with a function $d : X \times X \to ℝ_{\geq 0}$ such that

(a) If

x \in X

then

d (x, x) = 0

(b) If

x, y \in X

and

d (x, y) = 0

, then

x = y

x, y, z \in X

then

d (x, z) \leq d (x, y) + d (y, z)

Let $X$ be a metric space. Let $x \in X$ and let $ε \in ℝ_{> 0}$ . The ball of radius $ε$ at $x$ is the set $B_{ε} (x) = {p \in X | d (x, y) < ε} .$ Let $X$ be a metric space. The metric space topology on $X$ is the topology generated by the sets $B_{ε} (x), for x \in X and ε \in ℝ_{> 0} .$

HW: Show that the metric space topology is a topology on $X$ .

HW: Let $X = {0, 1}$ and let $𝒯 = {\emptyset, {0}, X}$ . Show that $𝒯$ is a topology on $X$ and that there does not exist a metric $d : X \times X \to ℝ_{\geq 0}$ on $X$ such that $𝒯$ is the metric space topology on $X$ .

Generating topologies

Let $X$ be a topological space. Let $x \in X .$

A base of the topology on $X$ is a collection $ℬ$ of open sets of $X$ such that if $U$ is open in $X$ then there exists $𝒮 \subseteq ℬ$ such that $U = ⋃_{A \in ℬ} A .$
A fundamental system of neighborhoods of $X$ is a set $𝒮$ of neighborhoods of $X$ such that if $N \in 𝒩 (x)$ then there exists $W \in 𝒮$ such that $W \subseteq N .$

HW: Show that $ℬ$ is a base of the topology on $X$ if and only if $ℬ$ satisfies if $x \in X$ then ${V \in ℬ | x \in V}$ is a fundamental system of neighborhoods of $x .$

This is found in [Bou, Ch I §1.3 Proposition 3].

HW: Show that the topology on $\prod_{i \in I} X_{i}$ has base ${\prod_{i \in I} A_{i} | \begin{matrix} A_{i} is open in X_{i}, \\ A_{i} = X_{i} for all but a finite number of i \in I \end{matrix}} .$

HW: Let $x \in \prod_{i \in I} X_{i} .$ Show that ${\prod_{i \in I} A_{i} | \begin{matrix} A_{i} is open in X_{i}, \\ A_{i} = X_{i} for all but a finite number of i \in I, \\ x \in \prod_{i \in I} A_{i} \end{matrix}}$ is a fundamental system of neighborhoods of $x .$

Homework

$f^{- 1} (C \cup D) = f^{- 1} (C) \cup f^{- 1} (D)$ .
$f^{- 1} (C \cap D) = f^{- 1} (C) \cap f^{- 1} (D)$ .
$f^{- 1} (f (E)) \supseteq E$ .
Give an example where $f^{- 1} (f (E)) \neq E$ .
If $E$ is compact then $E$ is closed.

Notes and References

This material is found in almost every textbook on introductory topology or mathematical analysis. One comprehensive reference is Bourbaki -- see [Bou, Ch I § 1 nos. 1,2,4] for open sets, closed sets and neighborhoods, [Bou, Ch I § 3 no. 1] for subspaces, [Bou Ch I § 4 no. 1] for products, [Bou Ch I § 9 no. 1 Axiom C'''] and [Bou, Ch. I § 9 no. 4] for compact sets, [Bou, Ch. I § 11 nos. 1,2] for connected sets, and [Bou, Ch. I § 2 no. 1] for continuous functions.

The most important theorem in the theory of continuous functions is the following. This theorem will be proved in the section on Limits in Topological spaces.

Let $X$ and $Y$ be topological spaces and let $a \in X$ . A function

f : X \to Y

is continuous at

a

if and only if

lim_{x \to a} f (x) = f (a).

References

[Bou] N. Bourbaki, General Topology, Springer-Verlag, 1989. MR1726779.

[BR] W. Rudin, Principles of mathematical analysis, Third edition, International Series in Pure and Applied Mathematics, McGraw-Hill 1976. MR0385023.

[Ru] W. Rudin, Real and complex analysis, Third edition, McGraw-Hill, 1987. MR0924157.

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