Home > Research > Publications & Outputs > Particle Metropolis adjusted Langevin algorithm...

Research

Associated organisational units

Electronic data

  • 1402.0694

    Submitted manuscript, 683 KB, PDF document

Keywords

View graph of relations

Particle Metropolis adjusted Langevin algorithms for state space models

Research output: Contribution to Journal/MagazineJournal article

Unpublished

Standard

Particle Metropolis adjusted Langevin algorithms for state space models. / Nemeth, Christopher; Fearnhead, Paul.
In: arxiv.org, 04.02.2014.

Research output: Contribution to Journal/MagazineJournal article

Harvard

Nemeth, C & Fearnhead, P 2014, 'Particle Metropolis adjusted Langevin algorithms for state space models', arxiv.org.

APA

Nemeth, C., & Fearnhead, P. (2014). Particle Metropolis adjusted Langevin algorithms for state space models. Unpublished.

Vancouver

Nemeth C, Fearnhead P. Particle Metropolis adjusted Langevin algorithms for state space models. arxiv.org. 2014 Feb 4.

Author

Nemeth, Christopher ; Fearnhead, Paul. / Particle Metropolis adjusted Langevin algorithms for state space models. In: arxiv.org. 2014.

Bibtex

@article{1caca0ec731e4ac18be313a5de0aa99d,
title = "Particle Metropolis adjusted Langevin algorithms for state space models",
abstract = "Particle MCMC is a class of algorithms that can be used to analyse state-space models. They use MCMC moves to update the parameters of the models, and particle filters to propose values for the path of the state-space model. Currently the default is to use random walk Metropolis to update the parameter values. We show that it is possible to use information from the output of the particle filter to obtain better proposal distributions for the parameters. In particular it is possible to obtain estimates of the gradient of the log posterior from each run of the particle filter, and use these estimates within a Langevin-type proposal. We propose using the recent computationally efficient approach of Nemeth et al. (2013) for obtaining such estimates. We show empirically that for a variety of state-space models this proposal is more efficient than the standard random walk Metropolis proposal in terms of: reducing autocorrelation of the posterior samples, reducing the burn-in time of the MCMC sampler and increasing the squared jump distance between posterior samples.",
keywords = "stat.CO, stat.ML",
author = "Christopher Nemeth and Paul Fearnhead",
note = "20 pages, 3 figures",
year = "2014",
month = feb,
day = "4",
language = "English",
journal = "arxiv.org",

}

RIS

TY - JOUR

T1 - Particle Metropolis adjusted Langevin algorithms for state space models

AU - Nemeth, Christopher

AU - Fearnhead, Paul

N1 - 20 pages, 3 figures

PY - 2014/2/4

Y1 - 2014/2/4

N2 - Particle MCMC is a class of algorithms that can be used to analyse state-space models. They use MCMC moves to update the parameters of the models, and particle filters to propose values for the path of the state-space model. Currently the default is to use random walk Metropolis to update the parameter values. We show that it is possible to use information from the output of the particle filter to obtain better proposal distributions for the parameters. In particular it is possible to obtain estimates of the gradient of the log posterior from each run of the particle filter, and use these estimates within a Langevin-type proposal. We propose using the recent computationally efficient approach of Nemeth et al. (2013) for obtaining such estimates. We show empirically that for a variety of state-space models this proposal is more efficient than the standard random walk Metropolis proposal in terms of: reducing autocorrelation of the posterior samples, reducing the burn-in time of the MCMC sampler and increasing the squared jump distance between posterior samples.

AB - Particle MCMC is a class of algorithms that can be used to analyse state-space models. They use MCMC moves to update the parameters of the models, and particle filters to propose values for the path of the state-space model. Currently the default is to use random walk Metropolis to update the parameter values. We show that it is possible to use information from the output of the particle filter to obtain better proposal distributions for the parameters. In particular it is possible to obtain estimates of the gradient of the log posterior from each run of the particle filter, and use these estimates within a Langevin-type proposal. We propose using the recent computationally efficient approach of Nemeth et al. (2013) for obtaining such estimates. We show empirically that for a variety of state-space models this proposal is more efficient than the standard random walk Metropolis proposal in terms of: reducing autocorrelation of the posterior samples, reducing the burn-in time of the MCMC sampler and increasing the squared jump distance between posterior samples.

KW - stat.CO

KW - stat.ML

M3 - Journal article

JO - arxiv.org

JF - arxiv.org

ER -