Statistical Finite Elements via Interacting Particle Langevin Dynamics

arXiv - STAT - Computation Pub Date : 2024-09-11 DOI:arxiv-2409.07101

Alex Glyn-Davies, Connor Duffin, Ieva Kazlauskaite, Mark Girolami, Ö. Deniz Akyildiz

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Abstract

In this paper, we develop a class of interacting particle Langevin algorithms to solve inverse problems for partial differential equations (PDEs). In particular, we leverage the statistical finite elements (statFEM) formulation to obtain a finite-dimensional latent variable statistical model where the parameter is that of the (discretised) forward map and the latent variable is the statFEM solution of the PDE which is assumed to be partially observed. We then adapt a recently proposed expectation-maximisation like scheme, interacting particle Langevin algorithm (IPLA), for this problem and obtain a joint estimation procedure for the parameters and the latent variables. We consider three main examples: (i) estimating the forcing for linear Poisson PDE, (ii) estimating the forcing for nonlinear Poisson PDE, and (iii) estimating diffusivity for linear Poisson PDE. We provide computational complexity estimates for forcing estimation in the linear case. We also provide comprehensive numerical experiments and preconditioning strategies that significantly improve the performance, showing that the proposed class of methods can be the choice for parameter inference in PDE models.

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通过相互作用粒子朗格文动力学实现统计有限元

在本文中，我们开发了一类交互粒子朗文算法来解决偏微分方程（PDE）的逆问题。特别是，我们利用统计有限元（statFEM）公式获得了一个有限维的潜变量统计模型，其中参数是（离散化）前向映射的参数，潜变量是假设为部分观测的偏微分方程的 statFEM 解。针对这一问题，我们采用了最近提出的类似期望最大化的方案--交互粒子朗文算法（IPLA），并获得了参数和潜变量的联合估计程序。我们考虑了三个主要例子：(i) 估计线性泊松 PDE 的强迫；(ii) 估计非线性泊松 PDE 的强迫；(iii) 估计线性泊松 PDE 的扩散性。我们为线性情况下的强迫估计提供了计算复杂性估计。我们还提供了可显著提高性能的综合数值实验和预处理策略，表明所提出的方法可以作为 PDE 模型参数推断的选择。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - STAT - Computation

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