Added duality result for spaces of measures.
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src/measure/vector/fin.tex
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src/measure/vector/fin.tex
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\section{Spaces of Finite Measures}
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\label{section:space-finite-measure}
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\begin{definition}[Space of Finite Measures]
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\label{definition:vector-measure-finite-space}
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Let $(X, \cm)$ be a measurable space, $E$ be a normed vector space over $K \in \RC$, and $M(X, \cm; E)$ be the set of all finite $E$-valued vector measures on $(X, \cm)$. For each $\mu \in M(X, \cm; E)$, let $\norm{\mu}_{\text{var}} = |\mu|(X)$, then:
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\begin{enumerate}
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\item $M(X, \cm; E)$ equipped with $\norm{\cdot}_{\text{var}}$ is a normed vector space over $K$.
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\item If $E$ is a Banach space, then so is $M(X, \cm; E)$.
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\end{enumerate}
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\end{definition}
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\begin{proof}
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(1): For any $\mu, \nu \in M(X, \cm; E)$ and $\seqf{A_j} \subset \cm$ such that $X = \bigsqcup_{j = 1}^n A_j$,
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\[
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|\mu|(X) + |\nu|(X) \ge \sum_{j = 1}^n \norm{\mu(A_j)}_E + \norm{\nu(A_j)}_E \ge \sum_{j = 1}^n \norm{(\mu + \nu)(A_j)}_E
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\]
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As this holds for all choices of $\seqf{A_j}$, $\norm{\mu + \nu}_{\text{var}} \le \norm{\mu}_{\text{var}} + \norm{\nu}_{\text{var}}$.
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(2): Let $\seq{\mu_n} \subset M(X, \cm; E)$ such that $\sum_{n \in \natp}\norm{\mu_n}_{\text{var}} < \infty$. For each $A \in \cm$, since $E$ is complete, let
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\[
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\mu(A) = \sum_{n = 1}^\infty \mu_n(A)
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\]
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then for any $\seq{A_k} \subset \cm$ and $A \in \cm$ with $A = \bigsqcup_{k \in \natp}A_k$,
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\[
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\mu(A) = \sum_{n = 1}^\infty \mu_n(A) = \sum_{n = 1}^\infty \sum_{k = 1}^\infty \mu_n(A_k) = \sum_{k = 1}^\infty \mu(A_k)
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\]
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by \hyperref[Fubini's theorem]{theorem:fubini-tonelli}.
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\end{proof}
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\begin{theorem}
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\label{theorem:hilbert-measures-dual}
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Let $(X, \cm)$ be a measurable space, $H$ be a Hilbert space over $K \in \RC$, and $\mathscr{M} \subset M(X, \cm; H)$ be a closed subspace such that:
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\begin{enumerate}
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\item[(A)] For each $\mu \in \mathscr{M}$ and $\nu \in M(X, \cm; H)$ with $\nu \ll \mu$, $\nu \in \mathscr{M}$.
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\end{enumerate}
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Let $|\mathscr{M}| = \bracsn{|\mu|: \mu \in \mathscr{M}}$, then for any maximal family $\seqi{\mu} \subset |\mathscr{M}|$ of pairwise mutually singular measures,
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\begin{enumerate}
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\item For each $f \in [l^1(I); L^1(\mu_i; H)]$, let
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\[
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\mu_f: \cm \to H \quad A \mapsto \sum_{i \in I} \int_A f_i d\mu_i
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\]
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then the mapping
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\[
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[l^1(I); L^1(\mu_i; H)] \to \mathscr{M} \quad f \mapsto \mu_f
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\]
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is an isometric isomorphism.
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\item $\mathscr{M}^*$ is isometrically isomorphic to $[l^\infty(I); L^\infty(\mu_i; H)]$.
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\end{enumerate}
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In other words,
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\begin{enumerate}[start=2]
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\item There exists a semifinite measure space $(\Omega, \cn, \mu)$ such that $\mathscr{M} \iso L^1(\Omega; H)$ and $\mathscr{M}^* \iso L^\infty(\Omega; H)$.
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\end{enumerate}
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\end{theorem}
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\begin{proof}
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(1): By (A), $\mu_f \in \mathscr{M}$ for all $f \in [l^1(I); L^1(\mu_i; H)]$.
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On the other hand, let $\nu \in \mathscr{M}$. For each $i \in I$, let $\nu = \nu_a^{(i)} + \nu_s^{(i)}$ be the Lebesgue decomposition of $\nu$ with respect to $\mu_i$, then by the \hyperref[Radon-Nikodym theorem]{theorem:lebesgue-radon-nikodym}, there exists $f_i \in L^1(\mu_i; H)$ such that $\nu_a^{(i)}(dx) = f_i \mu_i(dx)$.
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For each countable $J \subset I$, define
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\[
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\nu_J: \cm \to H \quad A \mapsto \sum_{j \in J}\int_A f_j d\mu_j
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\]
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Let $M = \sup\bracs{\norm{\nu_J}_{\text{var}}| J \subset I \text{ countable}}$, then there exists $J \subset I$ countable such that $\norm{\nu_J}_{\text{var}} = M$. For each $i \in I \setminus J$,
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\[
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\norm{\nu_J}_{\text{var}} + \normn{\nu_a^{(i)}}_{\text{var}}
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= \norm{\nu_{J} + \nu_a^{(i)}}_{\text{var}} = \normn{\nu_{J \cup \bracs{i}}}_{\text{var}} \le M
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\]
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By maximality of $M$, $\normn{\nu_a^{(i)}}_{\text{var}} = 0$, and by maximality of $\seqi{\mu}$, $\nu - \nu_J = 0$. Let $g \in [l^1(I); L^1(\mu_i; H)]$ be defined by $g_i = f_i$ for each $i \in I$, then $\nu = \nu_J = \mu_g$, and the mapping is surjective.
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(2): By \autoref{theorem:lp-sum-dual} and \autoref{theorem:lp-duality},
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\[
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[l^1(I); L^1(\mu_i; H)]^* \iso [l^\infty(I); L^1(\mu_i; H)^*] \iso [l^\infty(I); L^\infty(\mu_i; H)]
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\]
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\end{proof}
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@@ -7,4 +7,5 @@
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\input{./ac.tex}
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\input{./ms.tex}
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\input{./rn.tex}
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\input{./fin.tex}
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@@ -90,34 +90,3 @@
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Let $(X, \cm)$ be a measurable space and $\mu$ be a signed/vector measure, then $\mu$ is \textbf{finite} if $|\mu|$ is finite.
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\end{definition}
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\begin{definition}[Space of Finite Measures]
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\label{definition:vector-measure-finite-space}
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Let $(X, \cm)$ be a measurable space, $E$ be a normed vector space over $K \in \RC$, and $M(X, \cm; E)$ be the set of all finite $E$-valued vector measures on $(X, \cm)$. For each $\mu \in M(X, \cm; E)$, let $\norm{\mu}_{\text{var}} = |\mu|(X)$, then:
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\begin{enumerate}
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\item $M(X, \cm; E)$ equipped with $\norm{\cdot}_{\text{var}}$ is a normed vector space over $K$.
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\item If $E$ is a Banach space, then so is $M(X, \cm; E)$.
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\end{enumerate}
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\end{definition}
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\begin{proof}
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(1): For any $\mu, \nu \in M(X, \cm; E)$ and $\seqf{A_j} \subset \cm$ such that $X = \bigsqcup_{j = 1}^n A_j$,
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\[
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|\mu|(X) + |\nu|(X) \ge \sum_{j = 1}^n \norm{\mu(A_j)}_E + \norm{\nu(A_j)}_E \ge \sum_{j = 1}^n \norm{(\mu + \nu)(A_j)}_E
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\]
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As this holds for all choices of $\seqf{A_j}$, $\norm{\mu + \nu}_{\text{var}} \le \norm{\mu}_{\text{var}} + \norm{\nu}_{\text{var}}$.
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(2): Let $\seq{\mu_n} \subset M(X, \cm; E)$ such that $\sum_{n \in \natp}\norm{\mu_n}_{\text{var}} < \infty$. For each $A \in \cm$, since $E$ is complete, let
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\[
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\mu(A) = \sum_{n = 1}^\infty \mu_n(A)
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\]
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then for any $\seq{A_k} \subset \cm$ and $A \in \cm$ with $A = \bigsqcup_{k \in \natp}A_k$,
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\[
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\mu(A) = \sum_{n = 1}^\infty \mu_n(A) = \sum_{n = 1}^\infty \sum_{k = 1}^\infty \mu_n(A_k) = \sum_{k = 1}^\infty \mu(A_k)
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\]
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by \hyperref[Fubini's theorem]{theorem:fubini-tonelli}.
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\end{proof}
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