English

De-randomizing MCMC dynamics with the diffusion Stein operator

Machine Learning 2021-10-11 v1 Machine Learning

Abstract

Approximate Bayesian inference estimates descriptors of an intractable target distribution - in essence, an optimization problem within a family of distributions. For example, Langevin dynamics (LD) extracts asymptotically exact samples from a diffusion process because the time evolution of its marginal distributions constitutes a curve that minimizes the KL-divergence via steepest descent in the Wasserstein space. Parallel to LD, Stein variational gradient descent (SVGD) similarly minimizes the KL, albeit endowed with a novel Stein-Wasserstein distance, by deterministically transporting a set of particle samples, thus de-randomizes the stochastic diffusion process. We propose de-randomized kernel-based particle samplers to all diffusion-based samplers known as MCMC dynamics. Following previous work in interpreting MCMC dynamics, we equip the Stein-Wasserstein space with a fiber-Riemannian Poisson structure, with the capacity of characterizing a fiber-gradient Hamiltonian flow that simulates MCMC dynamics. Such dynamics discretizes into generalized SVGD (GSVGD), a Stein-type deterministic particle sampler, with particle updates coinciding with applying the diffusion Stein operator to a kernel function. We demonstrate empirically that GSVGD can de-randomize complex MCMC dynamics, which combine the advantages of auxiliary momentum variables and Riemannian structure, while maintaining the high sample quality from an interacting particle system.

Keywords

Cite

@article{arxiv.2110.03768,
  title  = {De-randomizing MCMC dynamics with the diffusion Stein operator},
  author = {Zheyang Shen and Markus Heinonen and Samuel Kaski},
  journal= {arXiv preprint arXiv:2110.03768},
  year   = {2021}
}

Comments

22 pages, 6 figures. NeurIPS 2021

R2 v1 2026-06-24T06:43:16.779Z