Extending Fourier Neural Operators for Modeling Parameterized and Coupled PDEs
Abstract
Parameterized and coupled partial differential equations (PDEs) are central to modeling phenomena in science and engineering, yet neural operator methods that address both aspects remain limited. We extend Fourier neural operators (FNOs) with minimal architectural modifications along two directions. For parameterized dynamics, we propose a hypernetwork-based modulation that conditions the operator on physical parameters. For coupled systems, we conduct a systematic exploration of architectural choices, examining how operator components can be adapted to balance shared structure with cross-variable interactions while retaining the efficiency of standard FNOs. Evaluations on benchmark PDEs, including the one-dimensional capacitively coupled plasma equations and the Gray–Scott system, show that our methods achieve up to 55~72% lower errors than strong baselines, demonstrating the effectiveness of principled modulation and systematic design exploration.
Cite
Text
Jing et al. "Extending Fourier Neural Operators for Modeling Parameterized and Coupled PDEs." International Conference on Learning Representations, 2026.Markdown
[Jing et al. "Extending Fourier Neural Operators for Modeling Parameterized and Coupled PDEs." International Conference on Learning Representations, 2026.](https://mlanthology.org/iclr/2026/jing2026iclr-extending/)BibTeX
@inproceedings{jing2026iclr-extending,
title = {{Extending Fourier Neural Operators for Modeling Parameterized and Coupled PDEs}},
author = {Jing, Cheng and Mudiyanselage, Uvini Balasuriya and Verma, Abhishek and Bera, Kallol and Rauf, Shahid and Lee, Kookjin},
booktitle = {International Conference on Learning Representations},
year = {2026},
url = {https://mlanthology.org/iclr/2026/jing2026iclr-extending/}
}