A Neural Multilevel Method for High-Dimensional Parametric PDEs

Abstract

In scientific machine learning, neural networks recently have become a popular tool for learning the solutions of differential equations. However, practical results often conflict the existing theoretical predictions in that observed convergence stagnates early. A substantial improvement can be achieved by the presented multilevel scheme which decomposes the considered problem into easier to train sub-problems, resulting in a sequence of neural networks. The efficacy of the approach is demonstrated for high-dimensional parametric elliptic PDEs that are common benchmark problems in uncertainty quantification. Moreover, a theoretical analysis of the expressivity of the developed neural networks is devised.

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Cite

Text

Heiß et al. "A Neural Multilevel Method for High-Dimensional Parametric PDEs." NeurIPS 2021 Workshops: DLDE, 2021.

Markdown

[Heiß et al. "A Neural Multilevel Method for High-Dimensional Parametric PDEs." NeurIPS 2021 Workshops: DLDE, 2021.](https://mlanthology.org/neuripsw/2021/hei2021neuripsw-neural/)

BibTeX

@inproceedings{hei2021neuripsw-neural,
  title     = {{A Neural Multilevel Method for High-Dimensional Parametric PDEs}},
  author    = {Heiß, Cosmas and Gühring, Ingo and Eigel, Martin},
  booktitle = {NeurIPS 2021 Workshops: DLDE},
  year      = {2021},
  url       = {https://mlanthology.org/neuripsw/2021/hei2021neuripsw-neural/}
}