Sequential Bayesian Design for Efficient Surrogate Construction in the Inversion of Darcy Flows

TL;DR

This paper introduces a sequential Bayesian design method for constructing efficient, locally accurate surrogate models in Darcy flow inverse problems, significantly reducing computational costs while maintaining high inversion accuracy.

Contribution

It proposes a novel sequential Bayesian design strategy that models the likelihood's high-probability regions as a Gaussian process, enabling efficient surrogate construction with limited data.

Findings

The method improves inversion accuracy in Darcy flow problems.

It reduces computational costs compared to traditional global surrogates.

Experiments demonstrate faster convergence and high precision.

Abstract

Inverse problems governed by partial differential equations (PDEs) play a crucial role in various fields, including computational science, image processing, and engineering. Particularly, Darcy flow equation is a fundamental equation in fluid mechanics, which plays a crucial role in understanding fluid flow through porous media. Bayesian methods provide an effective approach for solving PDEs inverse problems, while their numerical implementation requires numerous evaluations of computationally expensive forward solvers. Therefore, the adoption of surrogate models with lower computational costs is essential. However, constructing a globally accurate surrogate model for high-dimensional complex problems demands high model capacity and large amounts of data. To address this challenge, this study proposes an efficient locally accurate surrogate that focuses on the high-probability regions of the true likelihood in inverse problems, with relatively low model complexity and few training data requirements. Additionally, we introduce a sequential Bayesian design strategy to acquire the proposed surrogate since the high-probability region of the likelihood is unknown. The strategy treats the posterior evolution process of sequential Bayesian design as a Gaussian process, enabling algorithmic acceleration through one-step ahead prior. The complete algorithmic framework is referred to as Sequential Bayesian design for locally accurate surrogate (SBD-LAS). Finally, three experiments based the Darcy flow equation demonstrate the advantages of the proposed method in terms of both inversion accuracy and computational speed.