Rare event simulation using reversible shaking transformations

E. Gobet; G. Liu

doi:10.1137/14098418X

Rare event simulation using reversible shaking transformations

E. Gobet
, G. Liu

Ecole polytechnique

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

Abstract

We introduce random transformations, called reversible shaking transformations, which we use to design two schemes for estimating rare event probabilities. One is based on interacting particle systems and the other on the time-average of a single Markov path (called POP for parallel one-path) using ergodic theorem. We discuss their convergence rates and provide numerical experiments including continuous stochastic processes and jump processes. Our examples cover important situations related to insurance, queueing systems, and random graphs. Both schemes have good performance, with a seemingly better one for POP.

Original language	English
Pages (from-to)	A2295-A2316
Journal	SIAM Journal on Scientific Computing
Volume	37
Issue number	5
DOIs	https://doi.org/10.1137/14098418X
Publication status	Published - 1 Jan 2015

Keywords

Ergodic properties
Interacting particle systems
Monte Carlo simulations
Rare event

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10.1137/14098418X

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AB - We introduce random transformations, called reversible shaking transformations, which we use to design two schemes for estimating rare event probabilities. One is based on interacting particle systems and the other on the time-average of a single Markov path (called POP for parallel one-path) using ergodic theorem. We discuss their convergence rates and provide numerical experiments including continuous stochastic processes and jump processes. Our examples cover important situations related to insurance, queueing systems, and random graphs. Both schemes have good performance, with a seemingly better one for POP.

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KW - Monte Carlo simulations

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Rare event simulation using reversible shaking transformations

Abstract

Keywords

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