Added gluing for measures in terms of scaffoldings.
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\input{./measure.tex}
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\input{./measure.tex}
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\input{./complete.tex}
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\input{./complete.tex}
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\input{./semifinite.tex}
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\input{./semifinite.tex}
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\input{./scaffold.tex}
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\input{./sigma-finite.tex}
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\input{./sigma-finite.tex}
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\input{./localisable.tex}
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\input{./localisable.tex}
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\input{./regular.tex}
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\input{./regular.tex}
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src/measure/measure/scaffold.tex
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93
src/measure/measure/scaffold.tex
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\section{Scaffolds}
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\label{section:scaffold}
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\begin{definition}[Scaffold*]
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\label{definition:measure-scaffold}
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Let $(X, \cm, \mu)$ be a measure space and $\cf \subset \bracs{A \in \cm|\mu(A) < \infty}$ be an ideal, then $\cf$ is a \textbf{scaffold} for $\mu$ if for all $E \in \cm$,
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\[
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\mu(E) = \sup\bracs{\mu(E \cap A)|A \in \cf}
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\]
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and the quadruple $(X, \cm, \cf, \mu)$ is a \textbf{scaffolded measure space}.
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For any semifinite measure space $(X, \cm, \mu)$, $\cf = \bracs{A \in \cm|\mu(A) < \infty}$ is the \textbf{canonical scaffold} for $\mu$, and $(X, \cm, \mu)$ will be equipped with this scaffold unless specified otherwise.
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\end{definition}
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\begin{example}
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Let $X$ be a LCH space, $\mu$ be a Radon measure, and $\mathcal{K}$ be the collection of compact subsets of $X$, then $\mathcal{K}$ is a scaffold for $\mu$.
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\end{example}
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% Omitted
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\begin{lemma}[Gluing Lemma for Measures]
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\label{lemma:gluing-measure}
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Let $(X, \cm)$ be a measurable space, $\cf \subset \cm$ be an ideal, and $\bracsn{\mu_A}_{A \in \cf}$ such that:
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\begin{enumerate}[label=(\alph*)]
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\item For each $A \in \cf$, $\mu_A$ is a finite measure on $A$.
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\item For each $A, B \in \cf$ and $E \in \cm$, $\mu_A(E \cap A \cap B) = \mu_B(E \cap A \cap B)$.
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\end{enumerate}
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Let
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\[
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\mu: \cm \to [0, \infty] \quad E \mapsto \sup\bracsn{\mu_A(E \cap A)|A \in \cf}
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\]
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then:
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\begin{enumerate}
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\item $\mu$ is a measure.
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\item $\cf$ is a \hyperref[scaffold]{definition:measure-scaffold} for $(X, \cm, \mu)$.
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\item For each $E \in \cm$, $\mu(A \cap E) = \mu_A(A \cap E)$.
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\end{enumerate}
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\end{lemma}
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\begin{proof}
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(3): Let $E \in \cm$, then $\mu_A(A \cap E) \le \mu(A \cap E)$ by definition. On the other hand, for any $B \in \cf$,
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\[
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\mu_B(A \cap B \cap E) = \mu_A(A \cap B \cap E) \le \mu_A(A \cap E)
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\]
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Since the above holds for all $B \in \cf$, $\mu(A \cap E) \le \mu_A(A \cap E)$.
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(1): Let $\seq{E_n} \subset \cm$ be pairwise disjoint, then for each $A \in \cm$,
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\[
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\mu\paren{A \cap \bigsqcup_{n \in \natp}E_n} = \sum_{n \in \natp}\mu_A(A \cap E_n) \le \sum_{n \in \natp}\mu(E_n)
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\]
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so $\mu\paren{\bigsqcup_{n \in \natp}E_n} \le \sum_{n \in \natp}\mu(E_n)$.
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On the other hand, let $n \in \natp$, $\seqf{A_k} \subset \cf$, and $A = \bigcup_{k = 1}^n A_k \in \cf$, then
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\begin{align*}
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\sum_{k = 1}^n \mu(A_k \cap E_k) &= \sum_{k = 1}^n \mu_{A_k}(A_k \cap E_k) \\
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&\le \mu_A\paren{A \cap \bigsqcup_{k = 1}^n E_k} \\
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&\le \mu\paren{\bigsqcup_{k \in \natp}E_k}
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\end{align*}
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As this holds for all choice of $\seq{A_k} \subset \cf$,
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\[
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\sum_{k = 1}^n \mu(E_k) \le \mu\paren{\bigsqcup_{k \in \natp}E_k}
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\]
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and as the above holds for all $n \in \natp$, $\sum_{n \in \natp}\mu(E_n) \le \mu\paren{\bigsqcup_{n \in \natp}E_n}$.
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(2): By definition of $\mu$.
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\end{proof}
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\begin{corollary}
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\label{corollary:scaffolded-part}
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Let $(X, \cm, \mu)$ be a measure space, $\cf \subset \bracs{A \in \cm|\mu(A) < \infty}$ be an ideal, and
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\[
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\mu_\cf: \cm \to [0, \infty] \quad E \mapsto \sup\bracs{\mu(A \cap E)|A \in \cf}
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\]
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then
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\begin{enumerate}
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\item $\mu_\cf$ is a measure on $(X, \cm)$.
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\item $\cf$ is a \hyperref[scaffold]{definition:measure-scaffold} for $\mu_\cf$/
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\end{enumerate}
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and $\mu_\cf$ is the \textbf{$\cf$-scaffolded part} of $\mu$.
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\end{corollary}
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\begin{proof}
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For each $A \in \cf$ and $E \in \cm$, let $\mu_A(E) = \mu(E \cap A)$, then $\bracsn{\mu_A}_{A \in \cf}$ is a family of measures satisfying \autoref{lemma:gluing-measure}. Therefore $\mu_\cf$ as defined is a measure, and $\cf$ is a scaffold for $\mu_\cf$.
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\end{proof}
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@@ -60,21 +60,3 @@
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\end{proof}
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\end{proof}
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\begin{definition}[Scaffold*]
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\label{definition:measure-scaffold}
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Let $(X, \cm, \mu)$ be a measure space and $\cf \subset \bracs{A \in \cm|\mu(A) < \infty}$ be an ideal, then $\cf$ is a \textbf{scaffold} for $\mu$ if for all $E \in \cm$,
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\[
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\mu(E) = \sup\bracs{\mu(E \cap A)|A \in \cf}
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\]
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and the quadruple $(X, \cm, \cf, \mu)$ is a \textbf{scaffolded measure space}.
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For any semifinite measure space $(X, \cm, \mu)$, $\cf = \bracs{A \in \cm|\mu(A) < \infty}$ is the \textbf{canonical scaffold} for $\mu$, and $(X, \cm, \mu)$ will be equipped with this scaffold unless specified otherwise.
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\end{definition}
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\begin{example}
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Let $X$ be a LCH space, $\mu$ be a Radon measure, and $\mathcal{K}$ be the collection of compact subsets of $X$, then $\mathcal{K}$ is a scaffold for $\mu$.
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\end{example}
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% Omitted
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