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GEPS: Boosting Generalization in Parametric PDE Neural Solvers through Adaptive Conditioning

Machine Learning 2024-11-11 v2 Artificial Intelligence

Abstract

Solving parametric partial differential equations (PDEs) presents significant challenges for data-driven methods due to the sensitivity of spatio-temporal dynamics to variations in PDE parameters. Machine learning approaches often struggle to capture this variability. To address this, data-driven approaches learn parametric PDEs by sampling a very large variety of trajectories with varying PDE parameters. We first show that incorporating conditioning mechanisms for learning parametric PDEs is essential and that among them, adaptive conditioning\textit{adaptive conditioning}, allows stronger generalization. As existing adaptive conditioning methods do not scale well with respect to the number of parameters to adapt in the neural solver, we propose GEPS, a simple adaptation mechanism to boost GEneralization in Pde Solvers via a first-order optimization and low-rank rapid adaptation of a small set of context parameters. We demonstrate the versatility of our approach for both fully data-driven and for physics-aware neural solvers. Validation performed on a whole range of spatio-temporal forecasting problems demonstrates excellent performance for generalizing to unseen conditions including initial conditions, PDE coefficients, forcing terms and solution domain. Project page\textit{Project page}: https://geps-project.github.io

Keywords

Cite

@article{arxiv.2410.23889,
  title  = {GEPS: Boosting Generalization in Parametric PDE Neural Solvers through Adaptive Conditioning},
  author = {Armand Kassaï Koupaï and Jorge Mifsut Benet and Yuan Yin and Jean-Noël Vittaut and Patrick Gallinari},
  journal= {arXiv preprint arXiv:2410.23889},
  year   = {2024}
}
R2 v1 2026-06-28T19:42:49.938Z