Multilevel-Langevin pathwise average for Gibbs approximation

Abstract

We propose and study a new multilevel method for the numerical approximation of a Gibbs distribution π on Rd, based on (overdamped) Langevin diffusions. This method inspired by mainPPlangevin and gilesszpruchinvariant relies on a multilevel occupation measure, i.e. on an appropriate combination of R occupation measures of (constant-step) Euler schemes with respective steps γr = γ0 2-r, r=0,…,R. We first state a quantitative result under general assumptions which guarantees an -approximation (in a L2-sense) with a cost of the order -2 or -2| |3 under less contractive assumptions. We then apply it to overdamped Langevin diffusions with strongly convex potential U:Rd→R and obtain an -complexity of the order O(d-23(d-2)) or O(d-2) under additional assumptions on U. More precisely, up to universal constants, an appropriate choice of the parameters leads to a cost controlled by (λU 1)2λU-3 d-2 (where λU and λU respectively denote the supremum and the infimum of the largest and lowest eigenvalue of D2U). We finally complete these theoretical results with some numerical illustrations including comparisons to other algorithms in Bayesian learning and opening to non strongly convex setting.