HyperPINN: Learning Parameterized Differential Equations with Physics-Informed Hypernetworks
Abstract
Many types of physics-informed neural network models have been proposed in recent years as approaches for learning solutions to differential equations. When a particular task requires solving a differential equation at multiple parameterizations, this requires either re-training the model, or expanding its representation capacity to include the parameterization -- both solution that increase its computational cost. We propose the HyperPINN, which uses hypernetworks to learn to generate neural networks that can solve a differential equation from a given parameterization. We demonstrate with experiments on both a PDE and an ODE that this type of model can lead to neural network solutions to differential equations that maintain a small size, even when learning a family of solutions over a parameter space.
Cite
Text
de Avila Belbute-Peres et al. "HyperPINN: Learning Parameterized Differential Equations with Physics-Informed Hypernetworks." NeurIPS 2021 Workshops: DLDE, 2021.Markdown
[de Avila Belbute-Peres et al. "HyperPINN: Learning Parameterized Differential Equations with Physics-Informed Hypernetworks." NeurIPS 2021 Workshops: DLDE, 2021.](https://mlanthology.org/neuripsw/2021/deavilabelbuteperes2021neuripsw-hyperpinn/)BibTeX
@inproceedings{deavilabelbuteperes2021neuripsw-hyperpinn,
title = {{HyperPINN: Learning Parameterized Differential Equations with Physics-Informed Hypernetworks}},
author = {de Avila Belbute-Peres, Filipe and Chen, Yi-fan and Sha, Fei},
booktitle = {NeurIPS 2021 Workshops: DLDE},
year = {2021},
url = {https://mlanthology.org/neuripsw/2021/deavilabelbuteperes2021neuripsw-hyperpinn/}
}