Residual-Based Error Bound for Physics-Informed Neural Networks

Shuheng Liu, Xiyue Huang, Pavlos Protopapas

UAI 2023 pp. 1284-1293

/uai/2023/liu2023uai-residualbased/

Abstract

Neural networks are universal approximators and are studied for their use in solving differential equations. However, a major criticism is the lack of error bounds for obtained solutions. This paper proposes a technique to rigorously evaluate the error bound of Physics-Informed Neural Networks (PINNs) on most linear ordinary differential equations (ODEs), certain nonlinear ODEs, and first-order linear partial differential equations (PDEs). The error bound is based purely on equation structure and residual information and does not depend on assumptions of how well the networks are trained. We propose algorithms that bound the error efficiently. Some proposed algorithms provide tighter bounds than others at the cost of longer run time.

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Cite

Text

Liu et al. "Residual-Based Error Bound for Physics-Informed Neural Networks." Uncertainty in Artificial Intelligence, 2023.

Markdown

[Liu et al. "Residual-Based Error Bound for Physics-Informed Neural Networks." Uncertainty in Artificial Intelligence, 2023.](https://mlanthology.org/uai/2023/liu2023uai-residualbased/)

BibTeX

@inproceedings{liu2023uai-residualbased,
  title     = {{Residual-Based Error Bound for Physics-Informed Neural Networks}},
  author    = {Liu, Shuheng and Huang, Xiyue and Protopapas, Pavlos},
  booktitle = {Uncertainty in Artificial Intelligence},
  year      = {2023},
  pages     = {1284-1293},
  volume    = {216},
  url       = {https://mlanthology.org/uai/2023/liu2023uai-residualbased/}
}