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Main Authors: Gao, Yu, Song, Yongcun, Tan, Zhiyu, Yue, Hangrui, Zeng, Shangzhi
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.14430
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author Gao, Yu
Song, Yongcun
Tan, Zhiyu
Yue, Hangrui
Zeng, Shangzhi
author_facet Gao, Yu
Song, Yongcun
Tan, Zhiyu
Yue, Hangrui
Zeng, Shangzhi
contents Elliptic variational inequalities (EVIs) present significant challenges in numerical computation due to their inherent non-smoothness, nonlinearity, and inequality formulations. Traditional mesh-based methods often struggle with complex geometries and high computational costs, while existing deep learning approaches lack generality for diverse EVIs. To alleviate these issues, this paper introduces Prox-PINNs, a novel deep learning algorithmic framework that integrates proximal operators with physics-informed neural networks (PINNs) to solve a broad class of EVIs. The Prox-PINNs reformulate EVIs as nonlinear equations using proximal operators and then approximate the solutions via neural networks that enforce boundary conditions as hard constraints. Then the neural networks are trained by minimizing physics-informed residuals. The Prox-PINNs framework advances the state-of-the-art by unifying the treatment of diverse EVIs within a mesh-free and scalable computational architecture. The framework is demonstrated on several prototypical applications, including obstacle problems, elasto-plastic torsion, Bingham visco-plastic flows, and simplified friction problems. Numerical experiments validate the method's accuracy, efficiency, robustness, and flexibility across benchmark examples.
format Preprint
id arxiv_https___arxiv_org_abs_2505_14430
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Prox-PINNs: A Deep Learning Algorithmic Framework for Elliptic Variational Inequalities
Gao, Yu
Song, Yongcun
Tan, Zhiyu
Yue, Hangrui
Zeng, Shangzhi
Optimization and Control
68T07, 65K15, 35J88
Elliptic variational inequalities (EVIs) present significant challenges in numerical computation due to their inherent non-smoothness, nonlinearity, and inequality formulations. Traditional mesh-based methods often struggle with complex geometries and high computational costs, while existing deep learning approaches lack generality for diverse EVIs. To alleviate these issues, this paper introduces Prox-PINNs, a novel deep learning algorithmic framework that integrates proximal operators with physics-informed neural networks (PINNs) to solve a broad class of EVIs. The Prox-PINNs reformulate EVIs as nonlinear equations using proximal operators and then approximate the solutions via neural networks that enforce boundary conditions as hard constraints. Then the neural networks are trained by minimizing physics-informed residuals. The Prox-PINNs framework advances the state-of-the-art by unifying the treatment of diverse EVIs within a mesh-free and scalable computational architecture. The framework is demonstrated on several prototypical applications, including obstacle problems, elasto-plastic torsion, Bingham visco-plastic flows, and simplified friction problems. Numerical experiments validate the method's accuracy, efficiency, robustness, and flexibility across benchmark examples.
title Prox-PINNs: A Deep Learning Algorithmic Framework for Elliptic Variational Inequalities
topic Optimization and Control
68T07, 65K15, 35J88
url https://arxiv.org/abs/2505.14430