updates
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Zheyuan Wu
@@ -538,26 +538,56 @@
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\section{Geometry of State Space}
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\begin{frame}{Observable Diameter}
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\begin{block}{Definition}
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For a metric-measure space $X$ and $\kappa>0$,
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\begin{frame}{Observable diameter: the inner definition}
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\begin{block}{Partial diameter on $\mathbb{R}$}
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Let $\nu$ be a Borel probability measure on $\mathbb{R}$ and let $\alpha \in (0,1]$.
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The \textbf{partial diameter} of $\nu$ at mass level $\alpha$ is
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$$
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\obdiam_{\mathbb{R}}(X;-\kappa)
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=
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\sup_{f\in \operatorname{Lip}_1(X,\mathbb{R})}
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\diameter(f_*\mu_X;1-\kappa).
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\diameter(\nu;\alpha):=
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\{\diameter(A):A \subseteq \mathcal{B}(\mathbb{R}),
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\nu(A)\ge \alpha
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\},
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$$
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where
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$$
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\diameter(A):=\sup_{x,y\in A}|x-y|.
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$$
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\end{block}
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\vspace{0.4em}
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\begin{itemize}
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\item It asks how concentrated every $1$-Lipschitz real observable must be.
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\item In the thesis, entropy is used as a concrete observable-diameter proxy.
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\item Hopf fibration lets us compare $\mathbb{C}P^n$ with spheres.
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\item This asks for the shortest interval-like region containing at least $\alpha$ of the total mass.
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\item So $\diameter(\nu;1-\kappa)$ measures how tightly we can capture \emph{most} of the distribution, allowing us to discard a set of mass at most $\kappa$.
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\end{itemize}
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\end{frame}
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\begin{frame}{Observable diameter of a metric-measure space}
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\begin{block}{Definition}
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Let $X=(X,d_X,\mu_X)$ be a metric-measure space and let $\kappa>0$.
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The \textbf{observable diameter} of $X$ is
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$$
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\obdiam_{\mathbb{R}}(X;-\kappa)
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:=
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\sup_{f\in \operatorname{Lip}_1(X,\mathbb{R})}
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\diameter(f_*\mu_X;1-\kappa),
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$$
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where $\operatorname{Lip}_1(X,\mathbb{R})$ is the set of all $1$-Lipschitz functions
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$f:X\to\mathbb{R}$, and $f_*\mu_X$ is the pushforward measure on $\mathbb{R}$.
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\end{block}
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\vspace{0.4em}
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\begin{itemize}
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\item Each $1$-Lipschitz function $f$ is viewed as an \textbf{observable} on $X$.
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\item The pushforward measure $f_*\mu_X$ is the distribution of the values of that observable.
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\item If $\obdiam_{\mathbb{R}}(X;-\kappa)$ is small, then \emph{every} $1$-Lipschitz observable is strongly concentrated.
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\end{itemize}
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\end{frame}
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\begin{frame}{A Geometric Consequence}
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In this thesis, entropy functions are used as concrete observables to estimate observable diameter, and the Hopf fibration helps transfer information between $S^{2n+1}$ and $\mathbb{C}P^n$.
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\vspace{0.4em}
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\begin{block}{Projective-space estimate}
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For $0<\kappa<1$,
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$$
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