Metric and Hilbert Spaces

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

Last updated: 4 November 2014

Lecture 10: Convergence, continuity and uniform continuity

Let $(X, d)$ and $(C, ρ)$ be metric spaces.

Let $f : X \to C$ be a function.

The function $f : X \to C$ is continuous if $f$ satisfies: if $x \in X$ and $ε \in ℝ_{> 0}$ then there exists $δ \in ℝ_{> 0}$ such that
if $y \in X$ and $d (x, y) < δ$ then $d (f (x), f (y)) < ε .$

The function $f : X \to C$ is uniformly continuous if $f$ satisfies: if $ε \in ℝ_{> 0}$ then there exists $δ \in ℝ_{> 0}$ such that
if $x \in X$ and $y \in X$ and $d (x, y) < δ$ then $d (f (x), f (y)) < ε .$

HW: Second definition The function $f : X \to C$ is continuous if and only if $f$ satisfies if $x \in X$ then $lim_{y \to x} f (y) = f (x) .$

HW: Third definition The function $f : X \to C$ is continuous if and only if $f$ satisfies if $x \in X$ and $\begin{matrix} \overset{⇀}{x} : & ℤ_{> 0} & ⟶ & X \\ n & ⟼ & x_{n} \end{matrix}$ and $lim_{n \to \infty} x_{n} = x$
then $lim_{n \to \infty} f (x_{n}) = f (x) .$

HW: Fourth definition The function $f : X \to C$ is continuous if and only if $f$ is continuous as a function between topological spaces i.e., if $f$ satisfies if $V$ is open in $C$ then $f^{- 1} (V)$ is open in $X .$

Examples

HW Let $f : X \to Y$ and $g : Y \to Z$ be continuous. Show that $g \circ f$ is continuous.

HW Let $A \subseteq X$ and let $f : X \to Y$ be continuous. Show that $\begin{matrix} g : & A & ⟶ & Y \\ a & ⟼ & f (a) \end{matrix}$ is continuous.

HW: Let $f_{1} : X_{1} \to Y_{1}$ and $f_{2} : X_{2} \to Y_{2}$ be continuous. Show that $\begin{matrix} f : & X_{1} \times X_{2} & ⟶ & Y_{1} \times Y_{2} \\ (x_{1}, x_{2}) & ⟼ & (f_{1} (x_{1}), f_{2} (x_{2})) \end{matrix}$ is continuous.

HW: Show that $\begin{matrix} ℝ \times ℝ & ⟶ & ℝ \\ (x, y) & ⟼ & x + y \end{matrix}$ is continuous.

HW: Show that $\begin{matrix} ℝ & ⟶ & ℝ \\ x & ⟼ & - x \end{matrix}$ is continuous.

HW: Show that $\begin{matrix} ℝ \times ℝ & ⟶ & ℝ \\ (x, y) & ⟼ & x y \end{matrix}$ is continuous.

HW: Show that $\begin{matrix} ℝ & ⟶ & ℝ \\ x & ⟼ & \frac{x}{1 + x^{2}} \end{matrix}$ is uniformly continuous.

HW: Show that if $f : X \to Y$ is uniformly continuous then $f : X \to Y$ is continuous.

HW: Show that $\begin{matrix} ℝ & ⟶ & ℝ \\ x & ⟼ & x^{2} \end{matrix}$ is not uniformly continuous.

Sequences of functions

$f_{1}, f_{2}, \dots$ defined by $\begin{matrix} f_{n} : & [0, 1) & ⟶ & [0, 1) \\ x & ⟼ & x^{n} \end{matrix} .$

$f_{1}, f_{2}, \dots$ defined by $\begin{matrix} f_{n} : & [0, 1] & ⟶ & [0, 1] \\ x & ⟼ & x^{n} \end{matrix} .$

$f_{1}, f_{2}, \dots$ defined by $\begin{matrix} f_{n} : & ℝ_{\geq 0} & ⟶ & ℝ_{\geq 0} \\ x & ⟼ & x^{n} \end{matrix} .$

Let $(X, d)$ and $(C, ρ)$ be metric spaces.

Let $F = {functions f : X \to C}$ and define $d : F \times F \to ℝ_{\geq 0} \cup {\infty}$ by $d (f, g) = sup {ρ (f (x), g (x)) | x \in X}$ (warning $d : F \times F \to ℝ_{\geq 0} \cup {\infty}$ is not quite a metric).

Let $\begin{matrix} \overset{⇀}{f} : & ℤ_{> 0} & ⟶ & F \\ n & ⟼ & f_{n} \end{matrix}$ be a sequence of functions from $X$ to $C$ and let $f : X \to C$ be a function.

The sequence $\begin{matrix} \overset{⇀}{f} : & ℤ_{> 0} & ⟶ & F \\ n & ⟼ & f_{n} \end{matrix}$ converges pointwise to $f$ is $\overset{⇀}{f}$ satisfies if $x \in X$ and $ε \in ℝ_{> 0}$ then there exists $N \in ℤ_{> 0}$ such that
if $n \in ℤ_{> 0}$ and $n > N$ then $d (f_{n} (x), f (x)) < ε .$

The sequence $\begin{matrix} \overset{⇀}{f} : & ℤ_{> 0} & ⟶ & F \\ n & ⟼ & f_{n} \end{matrix}$ converges uniformly to $f$ is $\overset{⇀}{f}$ satisfies if $ε \in ℝ_{> 0}$ then there exists $N \in ℤ_{> 0}$ such that
if $x \in X$ and $n \in ℤ_{> 0}$ and $n > N$ then $d (f_{n} (x), f (x)) < ε .$

HW Second definition

The sequence $\begin{matrix} \overset{⇀}{f} : & ℤ_{> 0} & ⟶ & F \\ n & ⟼ & f_{n} \end{matrix}$ converges pointwise to $f$ is $\overset{⇀}{f}$ satisfies if $x \in X$ then $lim_{n \to \infty} d (f_{n} (x), f (x)) = 0 .$

The sequence $\begin{matrix} \overset{⇀}{f} : & ℤ_{> 0} & ⟶ & F \\ n & ⟼ & f_{n} \end{matrix}$ converges uniformly to $f$ if $lim_{n \to \infty} d (f_{n}, f) = 0 .$

Notes and References

These are a typed copy of Lecture 10 from a series of handwritten lecture notes for the class Metric and Hilbert Spaces given on August 13, 2014.

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