Red Light Green Light Method for Solving Large Markov Chains

Konstantin Avrachenkov; Patrick Brown; Nelly Litvak

doi:10.1007/s10915-022-01976-8

Red Light Green Light Method for Solving Large Markov Chains

Konstantin Avrachenkov (Corresponding author), Patrick Brown, Nelly Litvak

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

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Abstract

Discrete-time discrete-state finite Markov chains are versatile mathematical models for a wide range of real-life stochastic processes. One of most common tasks in studies of Markov chains is computation of the stationary distribution. We propose a new general controlled, easily distributed algorithm for this task. The algorithm includes as special cases a wide range of known, very different, and previously disconnected methods including power iterations, versions of Gauss-Southwell formerly restricted to substochastic matrices, and online distributed algorithms. We prove exponential convergence of our method, demonstrate its high efficiency, and derive straightforward control strategies that achieve convergence rates faster than state-of-the-art algorithms.

Original language	English
Article number	18
Number of pages	43
Journal	Journal of Scientific Computing
Volume	93
Issue number	1
DOIs	https://doi.org/10.1007/s10915-022-01976-8
Publication status	Published - Oct 2022

Funding

Funders	Funder number
European Cooperation in Science and Technology (COST)	CA15109
Nederlandse Organisatie voor Wetenschappelijk Onderzoek	024.002.003

Keywords

Coupling
Gauss-Southwell methods
Markov Chains
Numerical methods

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title = "Red Light Green Light Method for Solving Large Markov Chains",

abstract = "Discrete-time discrete-state finite Markov chains are versatile mathematical models for a wide range of real-life stochastic processes. One of most common tasks in studies of Markov chains is computation of the stationary distribution. We propose a new general controlled, easily distributed algorithm for this task. The algorithm includes as special cases a wide range of known, very different, and previously disconnected methods including power iterations, versions of Gauss-Southwell formerly restricted to substochastic matrices, and online distributed algorithms. We prove exponential convergence of our method, demonstrate its high efficiency, and derive straightforward control strategies that achieve convergence rates faster than state-of-the-art algorithms.",

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AU - Brown, Patrick

AU - Litvak, Nelly

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N2 - Discrete-time discrete-state finite Markov chains are versatile mathematical models for a wide range of real-life stochastic processes. One of most common tasks in studies of Markov chains is computation of the stationary distribution. We propose a new general controlled, easily distributed algorithm for this task. The algorithm includes as special cases a wide range of known, very different, and previously disconnected methods including power iterations, versions of Gauss-Southwell formerly restricted to substochastic matrices, and online distributed algorithms. We prove exponential convergence of our method, demonstrate its high efficiency, and derive straightforward control strategies that achieve convergence rates faster than state-of-the-art algorithms.

AB - Discrete-time discrete-state finite Markov chains are versatile mathematical models for a wide range of real-life stochastic processes. One of most common tasks in studies of Markov chains is computation of the stationary distribution. We propose a new general controlled, easily distributed algorithm for this task. The algorithm includes as special cases a wide range of known, very different, and previously disconnected methods including power iterations, versions of Gauss-Southwell formerly restricted to substochastic matrices, and online distributed algorithms. We prove exponential convergence of our method, demonstrate its high efficiency, and derive straightforward control strategies that achieve convergence rates faster than state-of-the-art algorithms.

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KW - Gauss-Southwell methods

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KW - Numerical methods

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Red Light Green Light Method for Solving Large Markov Chains

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