English

Non-asymptotic bounds for sampling algorithms without log-concavity

Probability 2019-10-11 v3 Statistics Theory Machine Learning Statistics Theory

Abstract

Discrete time analogues of ergodic stochastic differential equations (SDEs) are one of the most popular and flexible tools for sampling high-dimensional probability measures. Non-asymptotic analysis in the L2L^2 Wasserstein distance of sampling algorithms based on Euler discretisations of SDEs has been recently developed by several authors for log-concave probability distributions. In this work we replace the log-concavity assumption with a log-concavity at infinity condition. We provide novel L2L^2 convergence rates for Euler schemes, expressed explicitly in terms of problem parameters. From there we derive non-asymptotic bounds on the distance between the laws induced by Euler schemes and the invariant laws of SDEs, both for schemes with standard and with randomised (inaccurate) drifts. We also obtain bounds for the hierarchy of discretisation, which enables us to deploy a multi-level Monte Carlo estimator. Our proof relies on a novel construction of a coupling for the Markov chains that can be used to control both the L1L^1 and L2L^2 Wasserstein distances simultaneously. Finally, we provide a weak convergence analysis that covers both the standard and the randomised (inaccurate) drift case. In particular, we reveal that the variance of the randomised drift does not influence the rate of weak convergence of the Euler scheme to the SDE.

Keywords

Cite

@article{arxiv.1808.07105,
  title  = {Non-asymptotic bounds for sampling algorithms without log-concavity},
  author = {Mateusz B. Majka and Aleksandar Mijatović and Lukasz Szpruch},
  journal= {arXiv preprint arXiv:1808.07105},
  year   = {2019}
}

Comments

48 pages, revised version, accepted for publication in The Annals of Applied Probability

R2 v1 2026-06-23T03:40:02.997Z