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inputs/tutorial_14.tex
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inputs/tutorial_14.tex
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\tutorial{14}{2024-01-30}{}
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\subsection{Sheet 12}
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\nr 1
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% Examinable
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% TODO (there is a more direct way to do it, not using analytic / coanalytic)
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\nr 2
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% Examinable
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\nr 3
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% somewhat examinable (for 1.0)
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\nr 4
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% Examinable!
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% RECAP
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Let $X$ be a metrizable topological space.
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Let $K(X) \coloneqq \{ K \subseteq X : \text{ compact}\}$.
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The Vietoris topology has a basis given by
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$\{K \subseteq U\}$, $U$ open (type 1)
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and $\{K : K \cap U \neq \emptyset\}$, $U$ open (type 2).
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The Hausdorff metric on $K(X)$,
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$d_H(K,L)$ is the smallest $\epsilon$
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such that $K \subseteq B_{\epsilon}(L) \land L \subseteq B_\epsilon(K)$.
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This is equal to the maximal point to set distance,
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$\max_{a \in A} d(a,B)$.
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On previous sheets, we checked that $d_H$ is a metric.
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If $X$ is separable, then so is $K(X)$.
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% END RECAP
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\begin{fact}
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Let $(X,d)$ be a complete metric space.
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Then so is $(K(X), d_H)$.
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\end{fact}
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\begin{proof}
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We need to show that $(K(X), d_H)$ is complete.
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Let $(K_n)_{ n< \omega}$ be Cauchy in $(K(X), d_H)$.
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Wlog.~$K_n \neq \emptyset$ for all $n$.
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Let $K = \{ x \in X : \forall x \in U \overset{\text{open}}{\subseteq} X.~
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\text{ $X$ intersects $K_n$ for infinitely many $n$}\}$.
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Equivalently,
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$K = \{x : x \text{ is a cluster point of some subsequence $(x_n)$ with $x_n \in K_n$ for all $K_n$}\}$.
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(A cluster point is a limit of some subsequence).
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\begin{claim}
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$K_n \to K$.
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\end{claim}
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\begin{subproof}
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Note that $K$ is closed (the complement is open).
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\begin{claim}
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$K \neq \emptyset$.
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\end{claim}
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\begin{subproof}
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As $(K_n)$ is Cauchy,
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there exists a sequence $(x_n)$ with $x_n \in K_n$
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such that there exists a subsequence $(x_{n_i})$
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with $d(x_{n_i}, x_{n_{i+1}}) < \frac{1}{2^{i+1}}$.
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Let $n_0,n_1,\ldots$
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be such that $d_H(K_a, K_b) < 2^{-i-1}$
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for $a,b \ge n_i$.
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Pick $x_{n_0} \in K_{n_0}$.
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Then let $x_{n_{i+1}} \in K_{n_{i+1}}$ be such that
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$d(x_{n_i}, x_{n_{i+1}})$ is minimal.
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Then $x_{n_i} \xrightarrow{i \to \infty} x$
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and we have $x \in K$.
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\end{subproof}
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\begin{claim}
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$K$ is compact.
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\end{claim}
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\begin{subproof}
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We show that $K$ is complete and totally bounded.
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Since $K$ is a closed subset of a complete
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space, it is complete.
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So it suffices to show that $K$ is totally bounded.
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Let $\epsilon > 0$
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Take $N$ such that $d_H(K_i,K_j) < \epsilon$
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for all $i,j \ge N$.
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Cover $K_N$ with finitely many $\epsilon$-balls
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with centers $z_i$.
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Take $x \in K$.
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Then the $\epsilon$-ball around $x$ intersects $K_j$
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for some $j \ge N$, so
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there exists $z_i$ such that $d(x,z_i) < 3\epsilon$.
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Note that a subset of a bigger space is totally
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bounded iff it is totally bounded in itself.
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\end{subproof}
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Now we show that $K_n \to K$
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in $K(X)$.
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Let $\epsilon > 0$.
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Take $N$ such that for all $m,n \ge N$,
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$d_H(K_m,K_n) < \frac{\epsilon}{2}$.
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We'll first show that $\delta(K, K_n) < \epsilon$ for all $n > N$.
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Let $x \in K$.
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Take $(x_{n_i})$ with $x_{n_i} \in K_{n_i}, x_{n_i} \to x$.
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Then for large $i$,
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we have $n_i \ge N$ and $d(x_{n_i}, x) < \frac{\epsilon}{2}$.
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Take $n \ge N$.
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Then there exists $y_n \in K_n$
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with $d(y_n, x_{n_i}) < \frac{\epsilon}{2}$.
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So $d(x,y_n) < \epsilon$.
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Now show that $\delta(K_n, K) < \epsilon$ for all $n \ge N$.
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Take $y \in K_n$.
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Show that $d(y,K) < \epsilon$.
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To do this, construct a sequence of $y_{n_i} \in K_{n_i}$
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starting with $y$ such that $d(y_{n_i}, y_{n_{i+1}}) < \frac{\epsilon}{2^{i+2}}$.
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(same trick as before).
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\end{subproof}
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\end{proof}
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\begin{fact}
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If $X$ is compact metrisable,
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then so is $K(X)$.
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\end{fact}
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\begin{proof}
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We have just shown that $X$ is complete.
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So it suffices to show that it is totally bounded.
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Let $\epsilon > 0$.
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Cover $X$ with finitely many $\epsilon$-balls.
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Let $F$ be the set of the centers of these balls.
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Consider $\cP(F) \setminus \{\emptyset\}$.
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Clearly $\{B_x^{d_H} : x \in \cP(F) \setminus \{\emptyset\} \}$
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is a finite cover of $K(X)$.
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\end{proof}
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% TODO complete and totally bounded Sutherland metric and topological spaces
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@ -73,6 +73,7 @@
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\input{inputs/tutorial_11}
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\input{inputs/tutorial_11}
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\input{inputs/tutorial_12b}
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\input{inputs/tutorial_12b}
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\input{inputs/tutorial_12}
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\input{inputs/tutorial_12}
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\input{inputs/tutorial_14}
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\section{Facts}
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\section{Facts}
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\input{inputs/facts}
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\input{inputs/facts}
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