The ODE method for stability of skip-free markov chains with applications to MCMC

Gersende Fort; Sean Meyn; Eric Moulines; Pierre Priouret

doi:10.1214/07-AAP471

The ODE method for stability of skip-free markov chains with applications to MCMC

Gersende Fort
, Sean Meyn
, Eric Moulines
, Pierre Priouret

Research output: Contribution to journal › Article › peer-review

Abstract

Fluid limit techniques have become a central tool to analyze queueing networks over the last decade, with applications to performance analysis, simulation and optimization. In this paper, some of these techniques are extended to a general class of skip-free Markov chains. As in the case of queueing models, a fluid approximation is obtained by scaling time, space and the initial condition by a large constant. The resulting fluid limit is the solution of an ordinary differential equation (ODE) in "most" of the state space. Stability and finer ergodic properties for the stochastic model then follow from stability of the set of fluid limits. Moreover, similarly to the queueing context where fluid models are routinely used to design control policies, the structure of the limiting ODE in this general setting provides an understanding of the dynamics of the Markov chain. These results are illustrated through application to Markov chain Monte Carlo methods.

Original language	English
Pages (from-to)	664-707
Number of pages	44
Journal	Annals of Applied Probability
Volume	18
Issue number	2
DOIs	https://doi.org/10.1214/07-AAP471
Publication status	Published - 1 Apr 2008

Keywords

Fluid limit
Markov chain
Markov chain monte carlo
Metropolis-hastings algorithms
State-dependent drift criteria
Subgeometric ergodicity

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10.1214/07-AAP471

Cite this

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abstract = "Fluid limit techniques have become a central tool to analyze queueing networks over the last decade, with applications to performance analysis, simulation and optimization. In this paper, some of these techniques are extended to a general class of skip-free Markov chains. As in the case of queueing models, a fluid approximation is obtained by scaling time, space and the initial condition by a large constant. The resulting fluid limit is the solution of an ordinary differential equation (ODE) in {"}most{"} of the state space. Stability and finer ergodic properties for the stochastic model then follow from stability of the set of fluid limits. Moreover, similarly to the queueing context where fluid models are routinely used to design control policies, the structure of the limiting ODE in this general setting provides an understanding of the dynamics of the Markov chain. These results are illustrated through application to Markov chain Monte Carlo methods.",

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AU - Moulines, Eric

AU - Priouret, Pierre

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AB - Fluid limit techniques have become a central tool to analyze queueing networks over the last decade, with applications to performance analysis, simulation and optimization. In this paper, some of these techniques are extended to a general class of skip-free Markov chains. As in the case of queueing models, a fluid approximation is obtained by scaling time, space and the initial condition by a large constant. The resulting fluid limit is the solution of an ordinary differential equation (ODE) in "most" of the state space. Stability and finer ergodic properties for the stochastic model then follow from stability of the set of fluid limits. Moreover, similarly to the queueing context where fluid models are routinely used to design control policies, the structure of the limiting ODE in this general setting provides an understanding of the dynamics of the Markov chain. These results are illustrated through application to Markov chain Monte Carlo methods.

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KW - Markov chain

KW - Markov chain monte carlo

KW - Metropolis-hastings algorithms

KW - State-dependent drift criteria

KW - Subgeometric ergodicity

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DO - 10.1214/07-AAP471

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JO - Annals of Applied Probability

JF - Annals of Applied Probability

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ER -

The ODE method for stability of skip-free markov chains with applications to MCMC

Abstract

Keywords

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