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Main Authors: Hu, Tianhao, Li, Guanglian, Wang, Fengru, Xu, Yifeng, Zhou, Zhi
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2605.28291
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author Hu, Tianhao
Li, Guanglian
Wang, Fengru
Xu, Yifeng
Zhou, Zhi
author_facet Hu, Tianhao
Li, Guanglian
Wang, Fengru
Xu, Yifeng
Zhou, Zhi
contents The reliable and accurate numerical approximation of the $p$-Laplacian is particularly challenging in the extreme regimes $p \to 1^{+}$ and $p \gg 1$, where the operator becomes either highly singular or strongly degenerate, often causing severe instability in standard numerical methods. To address these difficulties, we propose a novel deep learning based framework, termed the dual variational neural network, for $p$-Laplace problems. The approach is based on a mixed formulation and an $L^q$-based Helmholtz decomposition, which decouples the original problem into two convex subproblems: a linear Poisson problem for the irrotational component and an unconstrained minimization problem over divergence-free fields for the solenoidal component. Following the decomposition, we employ two neural networks using a gradient--curl representation to approximate the flux, and further establish an error analysis of the neural approximation. The analysis relies on fundamental vector inequalities together with tools from statistical learning theory. Numerical experiments demonstrate robust convergence of the proposed method in challenging settings, including the extreme cases $p \to 1^{+}$ and $p \gg 1$, as well as the $p(x)$-Laplace equation.
format Preprint
id arxiv_https___arxiv_org_abs_2605_28291
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Dual Variational Neural Network for the $p$-Laplace Problem
Hu, Tianhao
Li, Guanglian
Wang, Fengru
Xu, Yifeng
Zhou, Zhi
Numerical Analysis
The reliable and accurate numerical approximation of the $p$-Laplacian is particularly challenging in the extreme regimes $p \to 1^{+}$ and $p \gg 1$, where the operator becomes either highly singular or strongly degenerate, often causing severe instability in standard numerical methods. To address these difficulties, we propose a novel deep learning based framework, termed the dual variational neural network, for $p$-Laplace problems. The approach is based on a mixed formulation and an $L^q$-based Helmholtz decomposition, which decouples the original problem into two convex subproblems: a linear Poisson problem for the irrotational component and an unconstrained minimization problem over divergence-free fields for the solenoidal component. Following the decomposition, we employ two neural networks using a gradient--curl representation to approximate the flux, and further establish an error analysis of the neural approximation. The analysis relies on fundamental vector inequalities together with tools from statistical learning theory. Numerical experiments demonstrate robust convergence of the proposed method in challenging settings, including the extreme cases $p \to 1^{+}$ and $p \gg 1$, as well as the $p(x)$-Laplace equation.
title Dual Variational Neural Network for the $p$-Laplace Problem
topic Numerical Analysis
url https://arxiv.org/abs/2605.28291