Enregistré dans:
Détails bibliographiques
Auteurs principaux: Zhang, Zecheng, Liu, Hao, Fu, Guosheng, Schaeffer, Hayden, Lin, Guang
Format: Preprint
Publié: 2025
Sujets:
Accès en ligne:https://arxiv.org/abs/2510.26962
Tags: Ajouter un tag
Pas de tags, Soyez le premier à ajouter un tag!
_version_ 1866909879515480064
author Zhang, Zecheng
Liu, Hao
Fu, Guosheng
Schaeffer, Hayden
Lin, Guang
author_facet Zhang, Zecheng
Liu, Hao
Fu, Guosheng
Schaeffer, Hayden
Lin, Guang
contents We propose a finite-element local basis-based operator learning framework for solving partial differential equations (PDEs). Operator learning aims to approximate mappings from input functions to output functions, where the latter are typically represented using basis functions. While non-learnable bases reduce training costs, learnable bases offer greater flexibility but often require deep network architectures with a large number of trainable parameters. Existing approaches typically rely on deep global bases; however, many PDE solutions exhibit local behaviors such as shocks, sharp gradients, etc., and in parametrized PDE settings, these localized features may appear in different regions of the domain across different training and testing samples. Motivated by the use of local bases in finite element methods (FEM) for function approximation, we develop a shallow neural network architecture that constructs adaptive FEM bases. By adopting suitable activation functions, such as ReLU, the FEM bases can be assembled exactly within the network, introducing no additional approximation error in the basis construction process. This design enables the learning procedure to naturally mimic the adaptive refinement mechanism of FEM, allowing the network to discover basis functions tailored to intrinsic solution features such as shocks. The proposed learnable adaptive bases are then employed to represent the solution (output function) of the PDE. This framework reduces the number of trainable parameters while maintaining high approximation accuracy, effectively combining the adaptivity of FEM with the expressive power of operator learning. To evaluate performance, we validate the proposed method on seven families of PDEs with diverse characteristics, demonstrating its accuracy, efficiency, and robustness.
format Preprint
id arxiv_https___arxiv_org_abs_2510_26962
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Finite Element Representation Network (FERN) for Operator Learning with a Localized Trainable Basis
Zhang, Zecheng
Liu, Hao
Fu, Guosheng
Schaeffer, Hayden
Lin, Guang
Numerical Analysis
We propose a finite-element local basis-based operator learning framework for solving partial differential equations (PDEs). Operator learning aims to approximate mappings from input functions to output functions, where the latter are typically represented using basis functions. While non-learnable bases reduce training costs, learnable bases offer greater flexibility but often require deep network architectures with a large number of trainable parameters. Existing approaches typically rely on deep global bases; however, many PDE solutions exhibit local behaviors such as shocks, sharp gradients, etc., and in parametrized PDE settings, these localized features may appear in different regions of the domain across different training and testing samples. Motivated by the use of local bases in finite element methods (FEM) for function approximation, we develop a shallow neural network architecture that constructs adaptive FEM bases. By adopting suitable activation functions, such as ReLU, the FEM bases can be assembled exactly within the network, introducing no additional approximation error in the basis construction process. This design enables the learning procedure to naturally mimic the adaptive refinement mechanism of FEM, allowing the network to discover basis functions tailored to intrinsic solution features such as shocks. The proposed learnable adaptive bases are then employed to represent the solution (output function) of the PDE. This framework reduces the number of trainable parameters while maintaining high approximation accuracy, effectively combining the adaptivity of FEM with the expressive power of operator learning. To evaluate performance, we validate the proposed method on seven families of PDEs with diverse characteristics, demonstrating its accuracy, efficiency, and robustness.
title Finite Element Representation Network (FERN) for Operator Learning with a Localized Trainable Basis
topic Numerical Analysis
url https://arxiv.org/abs/2510.26962