Multilevel Sequential Monte Carlo Samplers

TL;DR

This paper introduces a multilevel sequential Monte Carlo method to efficiently approximate expectations related to PDE solutions in Bayesian inverse problems, reducing computational effort while handling non-i.i.d. sampling challenges.

Contribution

It extends multilevel Monte Carlo techniques to sequential Monte Carlo frameworks, maintaining efficiency gains in complex sampling scenarios.

Findings

SMC multilevel approach reduces computational effort.

Efficiency gains are preserved under certain assumptions.

Applicable to Bayesian inverse problems involving PDEs.

Abstract

In this article we consider the approximation of expectations w.r.t. probability distributions associated to the solution of partial differential equations (PDEs); this scenario appears routinely in Bayesian inverse problems. In practice, one often has to solve the associated PDE numerically, using, for instance finite element methods and leading to a discretisation bias, with the step-size level $h_L$. In addition, the expectation cannot be computed analytically and one often resorts to Monte Carlo methods. In the context of this problem, it is known that the introduction of the multilevel Monte Carlo (MLMC) method can reduce the amount of computational effort to estimate expectations, for a given level of error. This is achieved via a telescoping identity associated to a Monte Carlo approximation of a sequence of probability distributions with discretisation levels $\infty>h_0>h_1\cdots>h_L$. In many practical problems of interest, one cannot achieve an i.i.d. sampling of the associated sequence of probability distributions. A sequential Monte Carlo (SMC) version of the MLMC method is introduced to deal with this problem. It is shown that under appropriate assumptions, the attractive property of a reduction of the amount of computational effort to estimate expectations, for a given level of error, can be maintained within the SMC context.