w23-logic-3/inputs/tutorial_03.tex

\ctutorial{03}{2023-10-31}{}

% 15 / 16

\begin{remark}
    $F_\sigma$
    stands for ferm\'e sum denumerable.
\end{remark}


\subsection{Exercise 2}

(b)
Let $f(x^{(i)})$ be a sequence in $f(X)$.
Suppose that $f(x^{(i)}) \to y$.
We have that $f^{-1} = \pi_{\text{odd}}$ is continuous.
Then $\pi_{\text{odd}}(f(x^{(i)}) \to \pi_{\text{odd}}(y)$.
Since $\pi_{\text{even}}$ converges, we have $\pi_{\text{odd}}(y) \in X$.


\subsection{Exercise 3}

\begin{example}
    Consider
    \begin{IEEEeqnarray*}{rCl}
        f\colon \R &\longrightarrow & [0,1] \\
        \frac{p}{q} &\longmapsto & \frac{1}{q}\\
        \R \setminus \Q \ni x &\longmapsto & 0
    \end{IEEEeqnarray*}
    Then $\osc_f(\frac{p}{q}) = \frac{1}{q}$
    and $\osc_f(x) = 0$ for $x \not\in \Q$.
\end{example}


\begin{definition}
    We say that $f\colon X \to Y$ is continuous
    at $a \in X$,
    if for $N$ a neighbourhood of $f(a)$ (i.e.~there exists
    $f(a) \in U \overset{\text{open}}{\subseteq}  N$,
    then $f^{-1}(N)$ is a neighbourhood of $a$.
\end{definition}


\begin{theorem}[Kuratowski]
    Let $X$ be metrizable, $Y$ completely metrizable,
    $f\colon S \to Y$ continuous.
    Then $f$ can be extended to a continuous fnuction $f_n$
    on a $G_\delta$ set  $G$ with $S \subseteq  G \subseteq \overline{G}$.
\end{theorem}
\begin{proof}
    Let $G \coloneqq  \overline{S} \cap \{x \in X | \osc_f(x) = 0\}$.
    Clearly $S \subseteq G$ as $f$ is continouos on $f$.
    \begin{claim}
        $G$ is $G_\delta$
    \end{claim}
    \begin{subproof}
        $\overline{S}$ is closed
        and
        \[
        \bigcap_{n \ge 1} \{x : \osc_f(x) <\frac{1}{n}\}
        \]
        is an intersection of open sets.
    \end{subproof}
    is an intersection of open sets.

    For $x \in G$, as $x \in  \overline{S}$,
    there exists $(x_n)_{x_n < \omega}$, $x_n \in S_$
    such that $x_n \to x$.
    We have that $(f(x_n))_n$ is Cauchy,
    as $\osc_f(x) = 0$.
    % TODO

    \todo{Something is missing here}


\end{proof}

\begin{corollary}
    Let $X$ be Polish and $Y \subseteq X$ Polish.
    Then $Y$ is $G_{\delta}$.
\end{corollary}
\begin{proof}
    Consider the identity $f\colon Y \hookrightarrow X$.
    Then $f$ can be extended to a $G_{\delta}$ set.
    $f$ and $\id_G$ agree on $Y$.
    Hence $Y \subseteq G \subseteq  \overline{Y}$.
    $Y$ is dense in $G$ and $\cod(f)$ is ltd.\todo{????}
    So $f = \id_G$, i.e.~$G = Y$.
\end{proof}

\subsection{Exercise 4}

Let $C$ be the subspace of $2^{\omega}$ consisting
of sequences with finitely many $1$s.
We want to show that $C \cong \Q$.

Go to the right in the even digits, go to the left for the odd digits,
i.e.~let $C = (1,-1,1,-1, \ldots)$
and set $x < y$ iff $C \cdot  x <_{\text{lex}} C \cdot y$.
tutorial 03 2023-10-31 20:15:15 +01:00			`\ctutorial{03}{2023-10-31}{}`

			`% 15 / 16`

			`\begin{remark}`
			$F_\sigma$
			`stands for ferm\'e sum denumerable.`
			`\end{remark}`


			`\subsection{Exercise 2}`

			`(b)`
			`Let $f(x^{(i)})$ be a sequence in $f(X)$.`
			`Suppose that $f(x^{(i)}) \to y$.`
			`We have that $f^{-1} = \pi_{\text{odd}}$ is continuous.`
			`Then $\pi_{\text{odd}}(f(x^{(i)}) \to \pi_{\text{odd}}(y)$.`
			`Since $\pi_{\text{even}}$ converges, we have $\pi_{\text{odd}}(y) \in X$.`


			`\subsection{Exercise 3}`

			`\begin{example}`
			`Consider`
			`\begin{IEEEeqnarray*}{rCl}`
			`f\colon \R &\longrightarrow & [0,1] \\`
			`\frac{p}{q} &\longmapsto & \frac{1}{q}\\`
			`\R \setminus \Q \ni x &\longmapsto & 0`
			`\end{IEEEeqnarray*}`
			`Then $\osc_f(\frac{p}{q}) = \frac{1}{q}$`
			`and $\osc_f(x) = 0$ for $x \not\in \Q$.`
			`\end{example}`


			`\begin{definition}`
			`We say that $f\colon X \to Y$ is continuous`
			`at $a \in X$,`
			`if for $N$ a neighbourhood of $f(a)$ (i.e.~there exists`
			`$f(a) \in U \overset{\text{open}}{\subseteq} N$,`
			`then $f^{-1}(N)$ is a neighbourhood of $a$.`
			`\end{definition}`



			`\begin{theorem}[Kuratowski]`
			`Let $X$ be metrizable, $Y$ completely metrizable,`
			`$f\colon S \to Y$ continuous.`
			`Then $f$ can be extended to a continuous fnuction $f_n$`
			`on a $G_\delta$ set $G$ with $S \subseteq G \subseteq \overline{G}$.`
			`\end{theorem}`
			`\begin{proof}`
			`Let $G \coloneqq \overline{S} \cap \{x \in X \| \osc_f(x) = 0\}$.`
			`Clearly $S \subseteq G$ as $f$ is continouos on $f$.`
			`\begin{claim}`
			`$G$ is $G_\delta$`
			`\end{claim}`
			`\begin{subproof}`
			`$\overline{S}$ is closed`
			`and`
			`\[`
			`\bigcap_{n \ge 1} \{x : \osc_f(x) <\frac{1}{n}\}`
			`\]`
			`is an intersection of open sets.`
			`\end{subproof}`
			`is an intersection of open sets.`

			`For $x \in G$, as $x \in \overline{S}$,`
			`there exists $(x_n)_{x_n < \omega}$, $x_n \in S_$`
			`such that $x_n \to x$.`
			`We have that $(f(x_n))_n$ is Cauchy,`
			`as $\osc_f(x) = 0$.`
			`% TODO`

			`\todo{Something is missing here}`


			`\end{proof}`

			`\begin{corollary}`
			`Let $X$ be Polish and $Y \subseteq X$ Polish.`
			`Then $Y$ is $G_{\delta}$.`
			`\end{corollary}`
			`\begin{proof}`
			`Consider the identity $f\colon Y \hookrightarrow X$.`
			`Then $f$ can be extended to a $G_{\delta}$ set.`
			`$f$ and $\id_G$ agree on $Y$.`
			`Hence $Y \subseteq G \subseteq \overline{Y}$.`
			`$Y$ is dense in $G$ and $\cod(f)$ is ltd.\todo{????}`
			`So $f = \id_G$, i.e.~$G = Y$.`
			`\end{proof}`

			`\subsection{Exercise 4}`

			`Let $C$ be the subspace of $2^{\omega}$ consisting`
			`of sequences with finitely many $1$s.`
			`We want to show that $C \cong \Q$.`

			`Go to the right in the even digits, go to the left for the odd digits,`
			`i.e.~let $C = (1,-1,1,-1, \ldots)$`
			`and set $x < y$ iff $C \cdot x <_{\text{lex}} C \cdot y$.`