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Efficient Error Certification for Physics-Informed Neural Networks

Machine Learning 2024-05-30 v2 Mathematical Physics math.MP

Abstract

Recent work provides promising evidence that Physics-Informed Neural Networks (PINN) can efficiently solve partial differential equations (PDE). However, previous works have failed to provide guarantees on the worst-case residual error of a PINN across the spatio-temporal domain - a measure akin to the tolerance of numerical solvers - focusing instead on point-wise comparisons between their solution and the ones obtained by a solver on a set of inputs. In real-world applications, one cannot consider tests on a finite set of points to be sufficient grounds for deployment, as the performance could be substantially worse on a different set. To alleviate this issue, we establish guaranteed error-based conditions for PINNs over their continuous applicability domain. To verify the extent to which they hold, we introduce \partial-CROWN: a general, efficient and scalable post-training framework to bound PINN residual errors. We demonstrate its effectiveness in obtaining tight certificates by applying it to two classically studied PINNs - Burgers' and Schr\"odinger's equations -, and two more challenging ones with real-world applications - the Allan-Cahn and Diffusion-Sorption equations.

Keywords

Cite

@article{arxiv.2305.10157,
  title  = {Efficient Error Certification for Physics-Informed Neural Networks},
  author = {Francisco Eiras and Adel Bibi and Rudy Bunel and Krishnamurthy Dj Dvijotham and Philip Torr and M. Pawan Kumar},
  journal= {arXiv preprint arXiv:2305.10157},
  year   = {2024}
}

Comments

Accepted to ICML'24

R2 v1 2026-06-28T10:37:00.084Z