OpenLB
Open Library of Bioscience
Advanced Search
The American statistician
2024;78 (4): 379-390.

Proximal MCMC for Bayesian Inference of Constrained and Regularized Estimation.

Xinkai Zhou, Qiang Heng, Eric C Chi, Hua Zhou
Author Information
  1. Xinkai Zhou: Department of Biostatistics, UCLA.
  2. Qiang Heng: Department of Computational Medicine, UCLA.
  3. Eric C Chi: Department of Statistics, Rice University.
  4. Hua Zhou: Department of Biostatistics, UCLA.
PMID: 39726826 DOI: 10.1080/00031305.2024.2308821

Abstract

This paper advocates proximal Markov Chain Monte Carlo (ProxMCMC) as a flexible and general Bayesian inference framework for constrained or regularized estimation. Originally introduced in the Bayesian imaging literature, ProxMCMC employs the Moreau-Yosida envelope for a smooth approximation of the total-variation regularization term, fixes variance and regularization strength parameters as constants, and uses the Langevin algorithm for the posterior sampling. We extend ProxMCMC to be fully Bayesian by providing data-adaptive estimation of all parameters including the regularization strength parameter. More powerful sampling algorithms such as Hamiltonian Monte Carlo are employed to scale ProxMCMC to high-dimensional problems. Analogous to the proximal algorithms in optimization, ProxMCMC offers a versatile and modularized procedure for conducting statistical inference on constrained and regularized problems. The power of ProxMCMC is illustrated on various statistical estimation and machine learning tasks, the inference of which is traditionally considered difficult from both frequentist and Bayesian perspectives.

Keywords

Hamiltonian Monte Carlo Moreau-Yosida envelope Proximal mapping

References

  1. Science. 2005 Apr 22;308(5721):523-9 [PMID: 15845847]
  2. Stat Sin. 2013 Jan 1;23(1):119-143 [PMID: 24478567]
  3. J Mach Learn Res. 2019 Apr;20: [PMID: 31649491]
  4. Math Program. 2014 Aug 1;146:409-436 [PMID: 25392563]
  5. J Comput Graph Stat. 2023;32(3):938-949 [PMID: 37822489]
  6. J Mach Learn Res. 2010 Mar 1;11:2287-2322 [PMID: 21552465]
  7. J Am Stat Assoc. 2013;108(502):540-552 [PMID: 24791032]
  8. J R Stat Soc Series B Stat Methodol. 2014 Mar 1;76(2):463-483 [PMID: 24648830]
  9. J Mach Learn Res. 2022;23: [PMID: 37205013]
  10. J Am Stat Assoc. 2015 Dec 1;110(512):1479-1490 [PMID: 27019543]
  11. J Comput Graph Stat. 2018;27(4):861-871 [PMID: 30618485]
  12. Biostatistics. 2008 Jul;9(3):432-41 [PMID: 18079126]
  13. J Comput Graph Stat. 2023;32(3):1097-1108 [PMID: 37982129]
  14. Can J Stat. 2018 Mar;46(1):41-61 [PMID: 30127543]

Grants

  1. R01 GM135928/NIGMS NIH HHS
  2. R01 HG006139/NHGRI NIH HHS
  3. R35 GM141798/NIGMS NIH HHS
Journal Article

Word Cloud

Created with Highcharts 10.0.0ProxMCMCBayesianMonteCarloinferenceestimationregularizationproximalconstrainedregularizedMoreau-YosidaenvelopestrengthparameterssamplingalgorithmsHamiltonianproblemsstatisticalProximalpaperadvocatesMarkovChainflexiblegeneralframeworkOriginallyintroducedimagingliteratureemployssmoothapproximationtotal-variationtermfixesvarianceconstantsusesLangevinalgorithmposteriorextendfullyprovidingdata-adaptiveincludingparameterpowerfulemployedscalehigh-dimensionalAnalogousoptimizationoffersversatilemodularizedprocedureconductingpowerillustratedvariousmachinelearningtaskstraditionallyconsidereddifficultfrequentistperspectivesMCMCInferenceConstrainedRegularizedEstimationmapping

Similar Articles

Cited By

No available data.