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2 changed files with 14 additions and 20 deletions
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@ -151,16 +151,17 @@ By Zorn's lemma, this will follow from
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& {(Z,T)}
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& {(Z,T)}
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\arrow[from=1-1, to=1-3]
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\arrow[from=1-1, to=1-3]
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\arrow[from=2-2, to=1-3]
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\arrow[from=2-2, to=1-3]
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\arrow["{\text{isometric extension}}"{description}, from=1-1, to=2-2]
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\arrow["{\text{isometric extension}}"{description}, from=1-1, to=2-2]
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\end{tikzcd}\]
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\end{tikzcd}\]
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\end{theorem}
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\end{theorem}
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\yaref{thm:furstenberg} allows us to talk about ranks of distal minimal flows:
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\yaref{thm:furstenberg} allows us to talk about ranks of distal minimal flows:
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\begin{definition}
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\begin{definition}[{\cite[{}13.1]{Furstenberg}}]
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Let $(X, \Z)$ be distal minimal.
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Let $(X,T)$ be a quasi-isometric flow,
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Then $\rank((X,\Z)) \coloneqq \min \{\eta : (X, \Z) \cong (X_\eta, \Z)\}$
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and let $\eta$ be the smallest ordinal
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where $(X_{\eta}, \Z)$ is as from the definition of quasi-isometric flows,
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such that there exists a quasi-isometric system $\{(X_\xi, T), \xi \le \eta\}$
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i.e.~$\rank((X,\Z))$ is the minimal height such
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with $(X,T) = (X_\xi, T)$.
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that a tower as in the definition exists.
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Then $\eta$ is called the \vocab{rank} or \vocab{order} of the flow
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and is denoted by $\rank((X,T))$.
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\end{definition}
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\end{definition}
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\begin{definition}+
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\begin{definition}+
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@ -35,20 +35,13 @@ equicontinuity coincide.
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By equicontinuity of $T$ we get that $\tilde{d}$ and $d$
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By equicontinuity of $T$ we get that $\tilde{d}$ and $d$
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induce the same topology on $X$.
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induce the same topology on $X$.
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\end{proof}
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\end{proof}
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\gist{
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Recall that we defined the order of a quasi-isometric flow
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to be the minimal number of steps required when building the tower
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to reach the flow with a quasi-isometric system (cf.~\yaref{thm:l16:3},
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\yaref{def:floworder}).
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}{}
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\begin{question}
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What is the minimal number of steps required
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when building the tower to reach the flow
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as in \yaref{thm:l16:3}?
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\end{question}
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\begin{definition}[{\cite[{}13.1]{Furstenberg}}]
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Let $(X,T)$ be a quasi isometric flow,
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and let $\eta$ be the smallest ordinal
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such that there exists a quasi-isometric system $\{(X_\xi, T), \xi \le \eta\}$
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with $(X,T) = (X_\xi, T)$.
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Then $\eta$ is called the \vocab{order} of the flow.
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\end{definition}
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\begin{theorem}[Maximal isometric factor]
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\begin{theorem}[Maximal isometric factor]
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\label{thm:maxisomfactor}
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\label{thm:maxisomfactor}
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For every flow $(X,T)$ there is a maximal factor $(Y,T)$, $\pi\colon X\to Y$,
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For every flow $(X,T)$ there is a maximal factor $(Y,T)$, $\pi\colon X\to Y$,
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