English

The Zig-Zag Process and Super-Efficient Sampling for Bayesian Analysis of Big Data

Computation 2020-09-29 v2 Probability

Abstract

Standard MCMC methods can scale poorly to big data settings due to the need to evaluate the likelihood at each iteration. There have been a number of approximate MCMC algorithms that use sub-sampling ideas to reduce this computational burden, but with the drawback that these algorithms no longer target the true posterior distribution. We introduce a new family of Monte Carlo methods based upon a multi-dimensional version of the Zig-Zag process of (Bierkens, Roberts, 2017), a continuous time piecewise deterministic Markov process. While traditional MCMC methods are reversible by construction (a property which is known to inhibit rapid convergence) the Zig-Zag process offers a flexible non-reversible alternative which we observe to often have favourable convergence properties. We show how the Zig-Zag process can be simulated without discretisation error, and give conditions for the process to be ergodic. Most importantly, we introduce a sub-sampling version of the Zig-Zag process that is an example of an {\em exact approximate scheme}, i.e. the resulting approximate process still has the posterior as its stationary distribution. Furthermore, if we use a control-variate idea to reduce the variance of our unbiased estimator, then the Zig-Zag process can be super-efficient: after an initial pre-processing step, essentially independent samples from the posterior distribution are obtained at a computational cost which does not depend on the size of the data.

Keywords

Cite

@article{arxiv.1607.03188,
  title  = {The Zig-Zag Process and Super-Efficient Sampling for Bayesian Analysis of Big Data},
  author = {Joris Bierkens and Paul Fearnhead and Gareth Roberts},
  journal= {arXiv preprint arXiv:1607.03188},
  year   = {2020}
}
R2 v1 2026-06-22T14:51:54.799Z