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@ -1,4 +1,5 @@
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\lecture{02}{2023-10-19}{Topology on $\R$}
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\gist{%
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\begin{definition}
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A set $O \subseteq \R$ is called \vocab{open} in $\R$ iff it is the union
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of a set of open intervals.
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\begin{remark}+
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$\{O \subseteq \R\} \sim 2^{\aleph_0} < \cP(\R)$.
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\end{remark}
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}{}
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\begin{definition}
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We call $x \in \R$
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there is some $y \in A$, $y \in (a,b)$, $y \neq x$.
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We write \vocab{$A'$} for the set of all accumulation points of $A$.
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\end{definition}
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\gist{%
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\begin{example}
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$\{\frac{1}{n+1} | n \in \N\}' = \{0\}$.
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\end{example}
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}{}
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\begin{lemma}
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\label{lem:closedaccumulation}
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@ -38,9 +42,11 @@
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\end{lemma}
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\begin{refproof}{lem:closedaccumulation}
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``$\implies$''
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\gist{%
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Let $A$ be closed. Suppose that $x \in A' \setminus A$.
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Then there exists $(a,b) \ni x$
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disjoint from $A$. Hence $x \not\in A' \lightning$
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}{trivial.}
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``$\impliedby$''
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Suppose $A' \subseteq A$.
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@ -48,6 +54,7 @@
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$A \subseteq \R$ is closed iff all Cauchy sequences
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in $A$ converge in $A$.
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\end{claim}
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\gist{%
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\begin{subproof}
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Let $A$ be closed and $\langle x_n : n \in \omega \rangle$
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a Cauchy sequence in $A$.
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@ -62,6 +69,7 @@
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we may pick $x_n \in (x - \frac{1}{n+1}, x + \frac{1}{n+1}) \cap A$
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for all $n < \omega$.
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\end{subproof}
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}{}
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Now if $A' \subseteq A$ and $A$ were not closed,
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there would be some Cauchy-sequence $(x_n)$
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@ -92,6 +100,7 @@ We want to prove two things:
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Then $P \sim \R$.
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\end{lemma}
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\begin{proof}
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\gist{%
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It suffices to find an injection $f\colon \R \hookrightarrow P$.
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We have $\underbrace{\{0,1\}^{\omega}}_{\text{infinite 0-1-sequences}} \sim \R$,
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hence it suffices to construct $f\colon \{0,1\}^\omega\hookrightarrow P$.
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@ -132,4 +141,5 @@ We want to prove two things:
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and $f(t') \in [a_{t'\defon{n}}, b_{t'\defon{n}}]$
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which are disjoint.
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Thus $f(t) \neq f(t')$, i.e.~$f$ is injective.
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}{Cantor scheme.}
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\end{proof}
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@ -77,7 +77,7 @@ all condensation points are accumulation points.
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\begin{subproof}
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$P \neq \emptyset$: $\checkmark$
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$P \subseteq P'$ (i.e. $P$ is closed):
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$P \subseteq P'$:
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% \begin{IEEEeqnarray*}{rCl}
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% P &=& \{x \in A | \text{every open neighbourhood of $x$ is uncountable}\}\\
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% &\subseteq & \{x \in A | \text{every open neighbourhood of $x$ is at least countable}\} = P'.
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@ -97,7 +97,7 @@ all condensation points are accumulation points.
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But then $(a,b) \cap A$ is at most countable
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contradicting $ x \in P$.
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$P' \subseteq P$ :
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$P' \subseteq P$ (i.e.~$P$ is closed):
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Let $x \in P'$.
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Then for $a < x < b$ the set
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$(a,b) \cap P$
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@ -12,6 +12,7 @@ $\ZFC$ stands for
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\item \textsc{Fraenkel}'s axioms,
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\item the \yaref{ax:c}.
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\end{itemize}
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\gist{
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\begin{notation}
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We write $x \subseteq y$ as a shorthand
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for $\forall z.~(z \in x \implies z \in y)$.
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\forall u.~((u \in z) \iff (u \in x \land u \not\in y)).
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\]
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\end{notation}
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}{Trivial, boring notation.}
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$\ZFC$ consists of the following axioms:
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\begin{axiom}[\vocab{Extensionality}]
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\yalabel{Axiom of Extensionality}{(Ext)}{ax:ext} % (AoE)
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\begin{axiomschema}[\vocab{Replacement} (Fraenkel)]
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\yalabel{Axiom of Replacement}{(Rep)}{ax:rep}
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Let $\phi$ be some $\cL_{\in }$ formula
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with free variables $x, y$.\todo{Allow more variables}
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with free variables $x, y$.
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Then
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\[
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\forall x \in a.~\exists !y \phi(x,y) \implies \exists b.~\forall x \in a.~\exists y \in b.~\phi(x,y).
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\begin{IEEEeqnarray*}{l}
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\forall v_1 \ldots \forall v_p.~\\
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\left[\left( \forall x \exists! y.~\phi(x,y,\overline{v})\right) \to \forall a .~\exists b .~\forall y.~(y \in b \leftrightarrow \exists x (x \in a \land \phi(x,y, \overline{v}))\right]
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\end{IEEEeqnarray*}
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%\forall x \in a.~\exists !y \phi(x,y) \implies \exists b.~\forall x \in a.~\exists y \in b.~\phi(x,y).
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% \forall v_1 \ldots \forall v_p .~\forall x.~ \exists y'.~\forall y.~(y = y' \iff \phi(x))
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% \implies \forall a.~\exists b.~\forall y.~(y \in b \iff \exists x.~(x \in a \land \phi(x))
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\]
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\end{axiomschema}
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\begin{axiom}[\vocab{Choice}]
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\]
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\end{definition}
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\gist{%
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\begin{definition}
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For sets $x, y$ we write
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$(x,y)$ for $\{\{x\}, \{x,y\}\}$.
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\end{definition}
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\begin{fact}
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Given sets $d, b$ then
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Given sets $d, b$ then
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$\leftindex^d b$ exists.
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\end{fact}
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\begin{proof}
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(In other mathematical fields, this is sometimes
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denoted as $f(a)$. We don't do that here.)
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\end{notation}
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}{[Some boring definitions omitted.]}
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\begin{definition}
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A binary relation $\le $ on a set $a$
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is a \vocab{partial order}
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x \in b \land \forall y \in b.~y \le x.
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\]
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In a similar way we define \vocab[Minimal element]{minimal elements}
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and the \vocab{minimum} of $b$.
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We say that $x $ is an \vocab{upper bound}
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(This does not necessarily exist.)
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Similarly $\text{\vocab{$\inf$}}(b)$ is defined.
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\end{definition}
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\gist{
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\begin{remark}+
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Note that in a partial order,
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a maximal element is not necessarily a maximum.
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We write $(a,\le_a) \cong (b, \le_b)$
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if they are isomorphic.
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\end{definition}
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}{}
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\begin{definition}
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Let $(a,\le)$ be a partial order.
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Then $(a,\le)$ is
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Then $a$ has a maximal element.
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\end{theorem}
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\begin{refproof}{thm:zorn}
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\gist{%
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Fix $(a, \le )$ as in the hypothesis.
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Let $A \coloneqq \{ \{(b,x) : x \in b\} : b \subseteq a, b \neq \emptyset\}$.
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Note that $A$ is a set (use separation on $\cP(\cP(a) \times \bigcup \cP(a))$).
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Then $B = B_{u_0}^{\le^{\ast\ast}}$.
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So $\le^{\ast\ast} \in W$, but now $u_0 \in b$.
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So $b$ must have a maximum.
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\todo{Why does this prove the lemma?}
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}{
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\begin{itemize}
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\item $A \coloneqq \{\{(b,x) : x \in b\}, b \subseteq a, b \neq \emptyset\}$.
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\item \AxC $\leadsto$ choice function on $A$,
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$f\colon \cP(a) \setminus \{\emptyset\} \to a$, $f(b) \in b$.
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\item $\le^\ast$ on $a$:
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\begin{itemize}
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\item $W \coloneqq \{\le' \text{wo on} b \subseteq a : \forall u,b \in b.~u \le' v \implies u \le v, B_u^{\le '} \neq \emptyset, u = f(B^{\le '}_u)\}$ where
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\item $B_u^{\le'} = \{w \in a : w \text{ $\le $-upper bound of } \{v \in b : v <' u\} \}$.
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\end{itemize}
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\item $\le', \le '' \in W \implies \le' \substack{\subseteq\\\supseteq} \le''$:
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\begin{itemize}
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\item $(b, \le') \overset{g}{\cong} (c, \le'') (\defon{v})$.
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\item $g = \id_b$:
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\begin{itemize}
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\item $u_0$ $\le'$ minimal with $g(u_0) \neq u_0$.
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\item $\{w \in b : w <' u_0\} \overset{g \defon{\ldots}}{=} \{w \in c : w <'' g(u_0)\}$.
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\item $B^{\le '}_{u_0} = B_{g(u_0)}^{\le ''} \neq \emptyset$,
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so $u_0 = f(B^{\le '}_{u_0}) = f(B^{\le ''}_{g(u_0)}) = g(u_0) \lightning$
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\end{itemize}
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\end{itemize}
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\item $\le^\ast \coloneqq \bigcup W$ is wo on $b \subseteq a$.
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\item Suppose $b$ has no maximum. Then $B \cap b = \emptyset$.
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\item $u_0 \coloneqq f(B)$, $\le^{\ast\ast} = \le^\ast \cup \{(u,u_0) | u \in b\} \cup \{(u_0,u_0)\}$.
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\item $B = B_{u_0}^{\le^{\ast\ast}}$, so $\le^{\ast\ast} \in W$,
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but $u_0 \in b \lightning$. ?
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\end{itemize}
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}
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\end{refproof}
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\begin{remark}
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Then $A$ contains a $\subseteq$-maximal element.
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\end{corollary}
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\gist{%
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\begin{remark}[Cultural enrichment]
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Other assertions which are equivalent
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to the \yaref{ax:c}:
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\item Every set can be well-ordered.%\footnote{This is clearly false.}
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\end{itemize}
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\end{remark}
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}{}
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% \begin{remark}
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% The axiom of choice is true.
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% \end{remark}
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\pagebreak
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\subsection{The Ordinals}
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\gist{
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\begin{goal}
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We want to define nice representatives of the equivalence classes
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of well-orders.
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Note that $\omega$ exists, as it is a subset of the inductive
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set given by \AxInf.
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We call $\omega$ the set of \vocab{natural numbers}.
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}{}
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\begin{notation}
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We write $0$ for $\emptyset$,
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and $y + 1$ for $y \cup \{y\}$.
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and for all $y, z \in x$,
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we have that $y = z$, $y \in z$ or $y \ni z$.
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\end{definition}
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\gist{
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Clearly, the $\in$-relation is a well-order on an ordinal $x$.
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\begin{remark}
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This definition is due to \textsc{John von Neumann}.
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\end{remark}
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}{}
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\begin{lemma}
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Each natural number (i.e.~element of $\omega$)
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is an ordinal.
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\end{lemma}
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\begin{proof}
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\gist{
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We use \yaref{lem:induction}.
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Clearly $\emptyset$ is an ordinal.
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Now let $\alpha$ be an ordinal.
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since $\alpha$ is an ordinal.
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Suppose $x = \alpha$.
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Then either $y = x$ or $y \in \alpha = x$.
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}{Induction}
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\end{proof}
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\begin{lemma}
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\end{enumerate}
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\end{lemma}
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\begin{refproof}{lem:7:ordinalfacts}
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\gist{
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We have already proved (a) before.
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(b) Fix $x \in \alpha$. Then $x \subseteq \alpha$.
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But this violates \AxFund,
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as $\alpha_0 \in \beta_0 \in \alpha_0$.
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\end{subproof}
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}{Long and tedious, but not many ideas.}
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\end{refproof}
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\begin{lemma}
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Otherwise $\alpha$ is called
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a \vocab[Ordinal!limit]{limit ordinal}.
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\end{definition}
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\gist{
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\begin{observe}
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Note that $\alpha$ is a limit ordinal iff for all
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$\beta \in \alpha$, $\beta + 1 \in \alpha$:
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then by definition there is some $\beta \in \alpha$,
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with $\beta + 1 = \alpha$, so $\beta + 1 \not\in \alpha$.
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\end{observe}
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}{}
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\gist{
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\begin{notation}
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If $\alpha, \beta$ are ordinals,
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we write $\alpha < \beta$ for $\alpha \in \beta$
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\item $\omega +1 = \omega \cup \{\omega\} , \omega + 2, \ldots$,
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\end{itemize}
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\end{example}
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}{}
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\lecture{08}{2023-11-13}{Induction and recursion}
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\subsection{Classes}
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\gist{
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It is often very handy to work in a class theory rather than
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in set theory.
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and classes (denoted by capital letters),
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as well as one binary relation symbol $\in$
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for membership.
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}{}
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\vocab{Bernays-Gödel class theory} (\vocab{BG})
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has the following axioms:
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\gist{
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\begin{axiom}[Extensionality]
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\yalabel{Axiom of Extensionality}{(Ext)}{ax:bg:ext}
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\[
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\exists x .~(\emptyset \in x \land \left( \forall y \in x .~y \cup \{y\} \in x \right)).
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\]
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\end{axiom}
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}{\AxExt, \AxFund, \AxPair, \AxUnion, \AxPow, \AxInf as from $\ZF$.}
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Together with the following axioms for classes:
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and $S_1 \coloneqq \{\xi < \kappa : \cf(\xi) = \omega_1\}$.
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Clearly these are disjoint.
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They are both stationary:
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Let $c \subseteq \kappa$ be a club.
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Let $C \subseteq \kappa$ be a club.
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Let $(\xi_i : i \le \omega_1)$
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be defined as follows:
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$\xi_0 \coloneqq \min C$,
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\item $\forall Y \in A$ define $h_Y\colon S^\ast \to \omega_1, \alpha \mapsto \min \{\beta < \alpha : \overline{f}_Y(\alpha) < \aleph_\beta\}$.
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\item Apply \yaref{thm:fodor} to $h_Y, S^\ast$ to get $T_Y \subseteq S^\ast$ stationary with $h_Y\defon{T_Y}$ constant.
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\item $\exists T.~|\underbrace{\{Y \in A_S : T_Y = T\}}_{A_{S,T}}| = \aleph_{ \omega_1 + 1}$.
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\item Let $\{\beta\} = g_Y''T$, i.e.~$\overline{f}_Y(\alpha) < \aleph_{\beta}$ for $Y\in A_{S,T}, \alpha \in T$.
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\item Let $\{\beta\} = h_Y''T$, i.e.~$\overline{f}_Y(\alpha) < \aleph_{\beta}$ for $Y\in A_{S,T}, \alpha \in T$.
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\item $\leftindex^T \aleph_\beta \le 2^{\aleph_\beta \cdot \aleph_1} = \aleph_{\beta+1} \aleph_2 < \aleph_{ \omega_1}$.
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\item $\exists \tilde{f}\colon T \to \aleph_\beta .~ |\underbrace{\{Y \in A_{S,T} : \overline{f}_Y\defon{T} = \tilde{f}\} }_{A_{S,T,\tilde{f}}}| = \aleph_{ \omega_1 + 1}$.
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\item $Y,Y' \in A_{S,T,\tilde{f}} \implies \forall \alpha \in T.~f_Y(\alpha) = f_{Y'}\left( \alpha \right) \overset{T \text{ unbounded}}{\implies} Y = Y'$
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\item $P \coloneqq \{Y \subseteq \aleph_{ \omega_1} : \exists i < \aleph_{ \omega_1 + 1}.~Y \le X_i\}$
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\end{itemize}
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\item $|P| \overset{\text{in fact } =}{\le} \aleph_{ \omega_1 + 1} \aleph_{ \omega_1} = \aleph_{ \omega_1 + 1}$ by (3).
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\item $X \in \cP(\aleph_{ \omega_1}) \setminus M \implies \forall i < \aleph_{ \omega_1 + 1}.~X_i \le X$
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\item $X \in \cP(\aleph_{ \omega_1}) \setminus P \implies \forall i < \aleph_{ \omega_1 + 1}.~X_i \le X$
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$\lightning$ (3).
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Thus $P = \cP(\aleph_{ \omega_1})$.
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\end{itemize}
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