Lie Point Symmetry and Physics Informed Networks

Tara Akhound-Sadegh; Laurence Perreault-Levasseur; Johannes Brandstetter; Max Welling; Siamak Ravanbakhsh

Lie Point Symmetry and Physics Informed Networks

Tara Akhound-Sadegh, Laurence Perreault-Levasseur, Johannes Brandstetter, Max Welling, Siamak Ravanbakhsh

Published: 18 Jun 2023, Last Modified: 30 Jun 2023TAGML2023 PosterEveryoneRevisions

Keywords: PDE, PINNs, Neural PDE solver, Lie point symmetry, Symmetry

TL;DR: We use Lie Point Symmetries of PDEs to Improve Physics Informed Networks.

Abstract: Physics-informed neural networks (PINNs) are computationally efficient alternatives to traditional partial differential equation (PDE) solvers. However, their reliability is dependent on the accuracy of the trained neural network. In this work, we introduce a mechanism for leveraging the symmetries of a given PDE to improve PINN performance. In particular, we propose a loss function that informs the network about Lie point symmetries, similar to how traditional PINN models try to enforce the underlying PDE. Intuitively, our symmetry loss ensures that infinitesimal generators of the Lie group preserve solutions of the PDE. Effectively, this means that once the network learns a solution, it also learns the neighbouring solutions generated by Lie point symmetries. Our results confirm that Lie point symmetries of the respective PDEs are an effective inductive bias for PINNs and can lead to a significant increase in sample efficiency.

Supplementary Materials: pdf

Type Of Submission: Extended Abstract (4 pages, non-archival)

Submission Number: 55

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