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Main Authors: Wang, Jindong, Hao, Wenrui
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2502.05571
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author Wang, Jindong
Hao, Wenrui
author_facet Wang, Jindong
Hao, Wenrui
contents Learning reaction-diffusion equations has become increasingly important across scientific and engineering disciplines, including fluid dynamics, materials science, and biological systems. In this work, we propose the Laplacian Eigenfunction-Based Neural Operator (LE-NO), a novel framework designed to efficiently learn nonlinear reaction terms in reaction-diffusion equations. LE-NO models the nonlinear operator on the right-hand side using a data-driven approach, with Laplacian eigenfunctions serving as the basis. This spectral representation enables efficient approximation of the nonlinear terms, reduces computational complexity through direct inversion of the Laplacian matrix, and alleviates challenges associated with limited data and large neural network architectures-issues commonly encountered in operator learning. We demonstrate that LE-NO generalizes well across varying boundary conditions and provides interpretable representations of learned dynamics. Numerical experiments in mathematical physics showcase the effectiveness of LE-NO in capturing complex nonlinear behavior, offering a powerful and robust tool for the discovery and prediction of reaction-diffusion dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2502_05571
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Laplacian Eigenfunction-Based Neural Operator for Learning Nonlinear Reaction-Diffusion Dynamics
Wang, Jindong
Hao, Wenrui
Mathematical Physics
Learning reaction-diffusion equations has become increasingly important across scientific and engineering disciplines, including fluid dynamics, materials science, and biological systems. In this work, we propose the Laplacian Eigenfunction-Based Neural Operator (LE-NO), a novel framework designed to efficiently learn nonlinear reaction terms in reaction-diffusion equations. LE-NO models the nonlinear operator on the right-hand side using a data-driven approach, with Laplacian eigenfunctions serving as the basis. This spectral representation enables efficient approximation of the nonlinear terms, reduces computational complexity through direct inversion of the Laplacian matrix, and alleviates challenges associated with limited data and large neural network architectures-issues commonly encountered in operator learning. We demonstrate that LE-NO generalizes well across varying boundary conditions and provides interpretable representations of learned dynamics. Numerical experiments in mathematical physics showcase the effectiveness of LE-NO in capturing complex nonlinear behavior, offering a powerful and robust tool for the discovery and prediction of reaction-diffusion dynamics.
title Laplacian Eigenfunction-Based Neural Operator for Learning Nonlinear Reaction-Diffusion Dynamics
topic Mathematical Physics
url https://arxiv.org/abs/2502.05571