Computationally efficient techniques for spatial regression with differential regularization

IF 1.7 4区数学 Q2 MATHEMATICS, APPLIED

International Journal of Computer Mathematics Pub Date : 2023-08-03 DOI:10.1080/00207160.2023.2239944

Eleonora Arnone, C. de Falco, L. Formaggia, Giorgio Meretti, L. Sangalli

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引用次数: 0

Abstract

We investigate some computational aspects of an innovative class of PDE-regularized statistical models: Spatial Regression with Partial Differential Equation regularization (SR-PDE). These physics-informed regression methods can account for the physics of the underlying phenomena and handle data observed over spatial domains with nontrivial shapes, such as domains with concavities and holes or curved domains. The computational bottleneck in SR-PDE estimation is the solution of a computationally demanding linear system involving a low-rank but dense block. We address this aspect by innovatively using Sherman–Morrison–Woodbury identity. We also investigate the efficient selection of the smoothing parameter in SR-PDE estimates. Specifically, we propose ad hoc optimization methods to perform Generalized Cross-Validation, coupling suitable reformulation of key matrices, e.g. those based on Sherman–Morrison–Woodbury formula, with stochastic trace estimation, to approximate the equivalent degrees of freedom of the problem. These solutions permit high computational efficiency also in the context of massive data.

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具有微分正则化的空间回归计算效率技术

我们研究了一类创新的偏微分方程正则化统计模型的一些计算方面:偏微分方程正则化空间回归(SR-PDE)。这些基于物理的回归方法可以解释潜在现象的物理性质，并处理在具有非平凡形状的空间域上观察到的数据，例如具有凹陷和孔的域或弯曲域。SR-PDE估计的计算瓶颈是求解涉及低秩但密集块的计算要求高的线性系统。我们通过创新地使用谢尔曼-莫里森-伍德伯里身份来解决这方面的问题。我们还研究了SR-PDE估计中平滑参数的有效选择。具体来说，我们提出了特别的优化方法来执行广义交叉验证，将关键矩阵的适当重新表述(例如基于Sherman-Morrison-Woodbury公式的那些)与随机跟踪估计相结合，以近似问题的等效自由度。这些解决方案也允许在海量数据的背景下实现高计算效率。

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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来源期刊

International Journal of Computer Mathematics 数学-应用数学

CiteScore

3.60

自引率

0.00%

发文量

审稿时长

5 months

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