Saved in:
Bibliographic Details
Main Authors: Dong, Huanshuo, Wang, Hong, Wu, Hao, Zhuang, Zhiwei, Yang, Xuanze, Shu, Ruiqi, Gao, Yuan, Huang, Xiaomeng
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.16573
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866918211948118016
author Dong, Huanshuo
Wang, Hong
Wu, Hao
Zhuang, Zhiwei
Yang, Xuanze
Shu, Ruiqi
Gao, Yuan
Huang, Xiaomeng
author_facet Dong, Huanshuo
Wang, Hong
Wu, Hao
Zhuang, Zhiwei
Yang, Xuanze
Shu, Ruiqi
Gao, Yuan
Huang, Xiaomeng
contents Neural operators have demonstrated considerable effectiveness in accelerating the solution of time-dependent partial differential equations (PDEs) by directly learning governing physical laws from data. However, for PDEs governed by conservation laws(e.g., conservation of mass, energy, or matter), existing neural operators fail to satisfy conservation properties, which leads to degraded model performance and limited generalizability. Moreover, we observe that distinct PDE problems generally require different optimal neural network architectures. This finding underscores the inherent limitations of specialized models in generalizing across diverse problem domains. To address these limitations, we propose Exterior-Embedded Conservation Framework (ECF), a universal conserving framework that can be integrated with various data-driven neural operators to enforce conservation laws strictly in predictions. The framework consists of two key components: a conservation quantity encoder that extracts conserved quantities from input data, and a conservation quantity decoder that adjusts the neural operator's predictions using these quantities to ensure strict conservation compliance in the final output. Since our architecture enforces conservation laws, we theoretically prove that it enhances model performance. To validate the performance of our method, we conduct experiments on multiple conservation-law-constrained PDE scenarios, including adiabatic systems, shallow water equations, and the Allen-Cahn problem. These baselines demonstrate that our method effectively improves model accuracy while strictly enforcing conservation laws in the predictions.
format Preprint
id arxiv_https___arxiv_org_abs_2511_16573
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle An Exterior-Embedding Neural Operator Framework for Preserving Conservation Laws
Dong, Huanshuo
Wang, Hong
Wu, Hao
Zhuang, Zhiwei
Yang, Xuanze
Shu, Ruiqi
Gao, Yuan
Huang, Xiaomeng
Other Computer Science
Machine Learning
Neural operators have demonstrated considerable effectiveness in accelerating the solution of time-dependent partial differential equations (PDEs) by directly learning governing physical laws from data. However, for PDEs governed by conservation laws(e.g., conservation of mass, energy, or matter), existing neural operators fail to satisfy conservation properties, which leads to degraded model performance and limited generalizability. Moreover, we observe that distinct PDE problems generally require different optimal neural network architectures. This finding underscores the inherent limitations of specialized models in generalizing across diverse problem domains. To address these limitations, we propose Exterior-Embedded Conservation Framework (ECF), a universal conserving framework that can be integrated with various data-driven neural operators to enforce conservation laws strictly in predictions. The framework consists of two key components: a conservation quantity encoder that extracts conserved quantities from input data, and a conservation quantity decoder that adjusts the neural operator's predictions using these quantities to ensure strict conservation compliance in the final output. Since our architecture enforces conservation laws, we theoretically prove that it enhances model performance. To validate the performance of our method, we conduct experiments on multiple conservation-law-constrained PDE scenarios, including adiabatic systems, shallow water equations, and the Allen-Cahn problem. These baselines demonstrate that our method effectively improves model accuracy while strictly enforcing conservation laws in the predictions.
title An Exterior-Embedding Neural Operator Framework for Preserving Conservation Laws
topic Other Computer Science
Machine Learning
url https://arxiv.org/abs/2511.16573