English

Multi-scale Physical Representations for Approximating PDE Solutions with Graph Neural Operators

Machine Learning 2022-06-30 v1 Computer Vision and Pattern Recognition

Abstract

Representing physical signals at different scales is among the most challenging problems in engineering. Several multi-scale modeling tools have been developed to describe physical systems governed by \emph{Partial Differential Equations} (PDEs). These tools are at the crossroad of principled physical models and numerical schema. Recently, data-driven models have been introduced to speed-up the approximation of PDE solutions compared to numerical solvers. Among these recent data-driven methods, neural integral operators are a class that learn a mapping between function spaces. These functions are discretized on graphs (meshes) which are appropriate for modeling interactions in physical phenomena. In this work, we study three multi-resolution schema with integral kernel operators that can be approximated with \emph{Message Passing Graph Neural Networks} (MPGNNs). To validate our study, we make extensive MPGNNs experiments with well-chosen metrics considering steady and unsteady PDEs.

Keywords

Cite

@article{arxiv.2206.14687,
  title  = {Multi-scale Physical Representations for Approximating PDE Solutions with Graph Neural Operators},
  author = {Léon Migus and Yuan Yin and Jocelyn Ahmed Mazari and Patrick Gallinari},
  journal= {arXiv preprint arXiv:2206.14687},
  year   = {2022}
}

Comments

ICLR 2022 Workshop on Geometrical and Topological Representation Learning

R2 v1 2026-06-24T12:08:26.899Z