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@ -122,6 +122,13 @@ We have shown (assuming \AxC to choose contained clubs):
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If $\kappa$ is regular and uncountable.
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If $\kappa$ is regular and uncountable.
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Then $\cF_\kappa$ is a $< \kappa$-closed filter.
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Then $\cF_\kappa$ is a $< \kappa$-closed filter.
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\end{theorem}
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\end{theorem}
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\begin{proof}
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Clearly $\emptyset \not\in \cF_\kappa$,
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$\kappa \in \cF_\kappa$,
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and $A \in \cF_{\kappa}, A \subseteq B \in \kappa \implies B \in \cF_\kappa$.
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In \autoref{lem:clubintersection} we are going to show that the intersection
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of $< \kappa$ many clubs is club.
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\end{proof}
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\begin{definition}
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\begin{definition}
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Let $\langle A_\beta : \beta < \alpha \rangle$
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Let $\langle A_\beta : \beta < \alpha \rangle$
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@ -208,6 +215,18 @@ We have shown (assuming \AxC to choose contained clubs):
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in $\gamma$, hence $\delta \in D_{\overline{\gamma}}$.
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in $\gamma$, hence $\delta \in D_{\overline{\gamma}}$.
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\end{subproof}
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\end{subproof}
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\end{proof}
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\end{proof}
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\begin{remark}+
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$\diagi_{\beta < \kappa} D_{\beta}$ actually
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\emph{is} a club:
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It suffices to show that $\diagi_{\beta < \kappa} D_\beta$ is closed.
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Let $\lambda < \kappa$ be a limit ordinal.
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Suppose that $\lambda \not\in \diagi_{\beta < \kappa} D_\beta$.
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Then there exists $\alpha < \lambda$ such that
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$\lambda \not\in D_\alpha$.
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Since $D_\alpha$ is closed,
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we get $\sup(D_{\alpha} \cap \lambda) < \lambda$.
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In particular $\sup (\lambda \cap\diagi_{\beta < \kappa} D_{\beta}) \le \max (\alpha ,\sup(D_\alpha \cap \lambda) < \lambda$.
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\end{remark}
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\begin{definition}
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\begin{definition}
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Let $\kappa$ be regular and uncountable.
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Let $\kappa$ be regular and uncountable.
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@ -35,7 +35,7 @@
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Then for every $\nu$ there exists a club $C_\nu$
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Then for every $\nu$ there exists a club $C_\nu$
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such that $S_\nu \cap C_\nu = \emptyset$.\footnote{Here we use \AxC to choose the $C_\nu$ uniformly.}
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such that $S_\nu \cap C_\nu = \emptyset$.\footnote{Here we use \AxC to choose the $C_\nu$ uniformly.}
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Let $C = \diagi_{\nu < \alpha} C_\nu$.
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Let $C = \diagi_{\nu < \alpha} C_\nu$.
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By \yaref{lem:diagiclub} $C$ is a club.\todo{Show that it \emph{is} a club not just contains one}
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By \yaref{lem:diagiclub} $C$ is a club.
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So we may pick some $\alpha \in C \cap S$.
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So we may pick some $\alpha \in C \cap S$.
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In particular $\alpha \in C_\nu$ for all $\nu < \alpha$.
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In particular $\alpha \in C_\nu$ for all $\nu < \alpha$.
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Hence $f(\alpha) \neq \nu$ for all $\nu < \alpha$,
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Hence $f(\alpha) \neq \nu$ for all $\nu < \alpha$,
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@ -216,7 +216,7 @@ Trivially, if $\kappa \le \lambda$ then $2^{\kappa} \le 2^{\lambda}$.
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This is in some sense the only thing we can prove about successor cardinals.
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This is in some sense the only thing we can prove about successor cardinals.
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However we can say something about singular cardinals:
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However we can say something about singular cardinals:
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\begin{theorem}[Silver]
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\begin{theorem}[Silver]
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\yaref{Silver's Theorem}{Silver}{thm:silver}
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\yalabel{Silver's Theorem}{Silver}{thm:silver}
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Let $\kappa$ be a singular cardinal of uncountable cofinality.
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Let $\kappa$ be a singular cardinal of uncountable cofinality.
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Assume that $2^{\lambda} = \lambda^+$ for all (infinite)
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Assume that $2^{\lambda} = \lambda^+$ for all (infinite)
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34
inputs/tutorial_2024-01-17.tex
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34
inputs/tutorial_2024-01-17.tex
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@ -0,0 +1,34 @@
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\tutorial{}{2024-01-17}{}
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\subsection{Sheet 9}
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\nr 1
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Let $\kappa$ be strongly inaccessible.
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Then $(V_{\kappa}, \in \defon_{V_\kappa}) \models\ZFC$:
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Most axioms are trivial.
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\begin{itemize}
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\item \AxUnion: Let $A \in V_{\kappa}$.
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Then $\rank(x) < \kappa$ for all $x \in A$.
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Since $\kappa$ is regular, we get
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$\bigcup A \in V_{\kappa}$.
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\item \AxPower: This holds since $\kappa$ is strongly inaccessible.
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\item \AxRep: If $A \in V_{\kappa}$ and $f\colon A \to V_\kappa$
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is definable over $V_\kappa$,
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then $f'' A = \{f(a) : a \in A\}$ has bounded rank below $\kappa$.
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\end{itemize}
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\subsection{Exercise during tutorial}
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Let $\kappa$ be uncountable and regular
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Then the club filter $\cF_{\kappa}$ is $< \kappa$-closed.
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