Fixed typos in the gluing lemma.
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@@ -38,6 +38,7 @@
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\begin{enumerate}
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\begin{enumerate}
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\item $\seq{I_n}$ is an $\mathcal{A}$-admissible \hyperref[approximation of the identity]{definition:approximation-id-measure}.
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\item $\seq{I_n}$ is an $\mathcal{A}$-admissible \hyperref[approximation of the identity]{definition:approximation-id-measure}.
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\item For each $N \in \natp$, $I_N$ is Borel measurable with $I_N(X) \subset \bracsn{x_n|1 \le n \le N}$.
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\item For each $N \in \natp$, $I_N$ is Borel measurable with $I_N(X) \subset \bracsn{x_n|1 \le n \le N}$.
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\item For each $n \in \natp$ and $x \in X$, $d(x, I_{n+1}(x)) \le d(x, I_n(x))$.
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\end{enumerate}
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\end{enumerate}
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\end{lemma}
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\end{lemma}
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\begin{proof}
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\begin{proof}
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@@ -83,7 +84,7 @@
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Finally, for each $x \in X$ and $\eps > 0$, since $x \in \ol{\mathcal{A}(x)^o}$, there exists $N_0 \in \natp$ such that $x_{N_0} \in \mathcal{A}(x)$ and $d(x, x_{N_0}) < \eps$. In which case, for any $N \ge N_0$, $N_0 \in C_N(x)$ and $d(x, I_N(x)) \le d(x, x_{N_0}) < \eps$. Thus $I_N(x) \to x$ as $N \to \infty$, and $\seq{I_N}$ satisfies (AI1).
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Finally, for each $x \in X$ and $\eps > 0$, since $x \in \ol{\mathcal{A}(x)^o}$, there exists $N_0 \in \natp$ such that $x_{N_0} \in \mathcal{A}(x)$ and $d(x, x_{N_0}) < \eps$. In which case, for any $N \ge N_0$, $N_0 \in C_N(x)$ and $d(x, I_N(x)) \le d(x, x_{N_0}) < \eps$. Thus $I_N(x) \to x$ as $N \to \infty$, and $\seq{I_N}$ satisfies (AI1).
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Therefore $\seq{I_N}$ is an approximation of the identity satisfying (1) and (2).
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Therefore $\seq{I_N}$ is an approximation of the identity satisfying (1)-(3).
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\end{proof}
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\end{proof}
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@@ -121,7 +121,7 @@
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(1): Let $A, B \in \cf$, then
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(1): Let $A, B \in \cf$, then
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\begin{align*}
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\begin{align*}
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\mu(E_A \setminus F_B^c) &= \mu(E_A \cap F_B) = \mu(E_A \cap F_B \cap A \cap B) \\
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\mu(E_A \setminus F_B^c) &= \mu(E_A \cap F_B) = \mu(E_A \cap F_B \cap A \cap B) \\
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&\le \mu(E_A \cap F_A) + \mu((F_A \cap B) \Delta F_B \cap A \cap B) = 0
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&\le \mu(E_A \cap F_A) + \mu((F_A \cap B) \Delta (F_B \cap A)) = 0
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\end{align*}
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\end{align*}
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so $F_B^c$ is an essential upper bound of $\bracs{E_A}_{A \in \cf}$. Since $E$ is an essential supremum of $\bracs{E_A}_{A \in \cf}$, $\mu(E \setminus F_B^c) = \mu(E \cap F_B) = 0$.
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so $F_B^c$ is an essential upper bound of $\bracs{E_A}_{A \in \cf}$. Since $E$ is an essential supremum of $\bracs{E_A}_{A \in \cf}$, $\mu(E \setminus F_B^c) = \mu(E \cap F_B) = 0$.
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@@ -182,15 +182,15 @@
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\item For each $A \in \cf$, $f_n|_A = f_{A, n}$ almost everywhere.
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\item For each $A \in \cf$, $f_n|_A = f_{A, n}$ almost everywhere.
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\end{enumerate}
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\end{enumerate}
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Since $Y$ is Polish, \autoref{proposition:metric-measurable-limit} implies that $\bracsn{\limv{n}f_n \text{ exists}} \in \cm$. For each $A \in \cf$,
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Since $Y$ is Polish, \autoref{proposition:metric-measurable-limit} implies that $\bracsn{\limv{n}f_n \text{ exists}} \in \cm$. For each $A \in \cf$, since $\limv{n}f_{A, n}$ and $\limv{n}f_{n}|_A$ exist and are equal almost everywhere on $A$,
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\[
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\[
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\mu\paren{\bracs{\limv{n}f_n \text{ does not exist}} \cap A} = \mu\bracs{\limv{n}f_{A, n} \ne f_A} = 0
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\mu\paren{\bracs{\limv{n}f_n \text{ does not exist}} \cap A} \le \mu\bracs{\limv{n}f_{A, n} \text{ does not exist}} = 0
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\]
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\]
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As $\mu$ is semifinite, $\mu\bracsn{\limv{n}f_n \text{ does not exist}} = 0$, so there exists $f \in \mathcal{L}^0(X; Y)$ such that $f = \limv{n}f_n$ almost everywhere. In which case,
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As $\mu$ is semifinite, $\mu\bracsn{\limv{n}f_n \text{ does not exist}} = 0$, so there exists $f \in \mathcal{L}^0(X; Y)$ such that $f = \limv{n}f_n$ almost everywhere. In which case,
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\begin{enumerate}
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\begin{enumerate}
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\item $f \in \mathcal{L}^0(X; Y)$.
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\item $f \in \mathcal{L}^0(X; Y)$.
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\item For each $A \in \cf$, $f|_A = \limv{n}f_n|A = \limv{n}f_{A, n} = f_A$ almost everywhere.
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\item For each $A \in \cf$, $f|_A = \limv{n}f_n|_A = \limv{n}f_{A, n} = f_A$ almost everywhere.
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\item[(U)] For all $A \in \cf$, $f|_A = g|_A$ almost everywhere. Since $\mu$ is semifinite, $f = g$ almost everywhere.
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\item[(U)] For all $A \in \cf$, $f|_A = g|_A$ almost everywhere. Since $\mu$ is semifinite, $f = g$ almost everywhere.
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\end{enumerate}
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\end{enumerate}
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\end{proof}
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\end{proof}
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