exercise:5184e6637c: Difference between revisions
(Created page with "<div class="d-none"><math> \newcommand{\NA}{{\rm NA}} \newcommand{\mat}[1]{{\bf#1}} \newcommand{\exref}[1]{\ref{##1}} \newcommand{\secstoprocess}{\all} \newcommand{\NA}{{\rm NA}} \newcommand{\mathds}{\mathbb}</math></div> (Suggested by Peter Doyle) In the proof of Theorem, we assumed the existence of a fixed vector <math>\mat{w}</math>. To avoid this assumption, beef up the coupling argument to show (without assuming the existen...") |
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\newcommand{\mathds}{\mathbb}</math></div> (Suggested by Peter Doyle) In the proof of [[guide:D71bfb6804#thm 11.4.1 |Theorem]], | \newcommand{\mathds}{\mathbb}</math></div> (Suggested by Peter Doyle) In the proof of [[guide:D71bfb6804#thm 11.4.1 |Theorem]], we assumed the existence of a fixed vector <math>\mat{w}</math>. To avoid this assumption, beef up the coupling argument to show (without assuming the existence of a stationary distribution <math>\mat{w}</math>) that for appropriate constants <math>C</math> and <math>r < 1</math>, the distance between <math>\alpha P^n</math> and <math>\beta P^n</math> is at most <math>C r^n</math> for any starting distributions <math>\alpha</math> and <math>\beta</math>. Apply this in the case where <math>\beta = \alpha P</math> to conclude that the sequence <math>\alpha P^n</math> is a Cauchy sequence, and that its limit is a matrix <math>W</math> whose rows are all equal to a probability vector <math>w</math> with <math>wP=w</math>. Note that the distance between <math>\alpha P^n</math> and <math>w</math> is at most <math>C r^n</math>, so in freeing ourselves from the assumption about having a fixed vector we've proved that the convergence to equilibrium takes place exponentially fast. | ||
we assumed the existence of a fixed vector <math>\mat{w}</math>. | |||
To avoid this assumption, beef up the coupling argument to show (without assuming the existence | |||
of a stationary distribution <math>\mat{w}</math>) that for appropriate constants | |||
<math>C</math> and <math>r < 1</math>, the distance between <math>\alpha P^n</math> and <math>\beta P^n</math> is at most | |||
<math>C r^n</math> for any starting distributions <math>\alpha</math> and <math>\beta</math>. | |||
Apply this in the case where <math>\beta = \alpha P</math> to | |||
conclude that the sequence <math>\alpha P^n</math> is a Cauchy sequence, | |||
and that its limit is a matrix <math>W</math> whose rows are all equal to a probability | |||
vector <math>w</math> with <math>wP=w</math>. Note that the distance between <math>\alpha P^n</math> and | |||
<math>w</math> is at most <math>C r^n</math>, so in freeing ourselves from the assumption about | |||
having a fixed vector we've proved that the convergence to equilibrium | |||
takes place exponentially fast. | |||
Latest revision as of 21:28, 15 June 2024
(Suggested by Peter Doyle) In the proof of Theorem, we assumed the existence of a fixed vector [math]\mat{w}[/math]. To avoid this assumption, beef up the coupling argument to show (without assuming the existence of a stationary distribution [math]\mat{w}[/math]) that for appropriate constants [math]C[/math] and [math]r \lt 1[/math], the distance between [math]\alpha P^n[/math] and [math]\beta P^n[/math] is at most [math]C r^n[/math] for any starting distributions [math]\alpha[/math] and [math]\beta[/math]. Apply this in the case where [math]\beta = \alpha P[/math] to conclude that the sequence [math]\alpha P^n[/math] is a Cauchy sequence, and that its limit is a matrix [math]W[/math] whose rows are all equal to a probability vector [math]w[/math] with [math]wP=w[/math]. Note that the distance between [math]\alpha P^n[/math] and [math]w[/math] is at most [math]C r^n[/math], so in freeing ourselves from the assumption about having a fixed vector we've proved that the convergence to equilibrium takes place exponentially fast.