English

Physics-enhanced deep surrogates for partial differential equations

Machine Learning 2023-12-18 v4 Applied Physics

Abstract

Many physics and engineering applications demand Partial Differential Equations (PDE) property evaluations that are traditionally computed with resource-intensive high-fidelity numerical solvers. Data-driven surrogate models provide an efficient alternative but come with a significant cost of training. Emerging applications would benefit from surrogates with an improved accuracy-cost tradeoff, while studied at scale. Here we present a "physics-enhanced deep-surrogate" ("PEDS") approach towards developing fast surrogate models for complex physical systems, which is described by PDEs. Specifically, a combination of a low-fidelity, explainable physics simulator and a neural network generator is proposed, which is trained end-to-end to globally match the output of an expensive high-fidelity numerical solver. Experiments on three exemplar testcases, diffusion, reaction-diffusion, and electromagnetic scattering models, show that a PEDS surrogate can be up to 3×\times more accurate than an ensemble of feedforward neural networks with limited data (103\approx 10^3 training points), and reduces the training data need by at least a factor of 100 to achieve a target error of 5%. Experiments reveal that PEDS provides a general, data-driven strategy to bridge the gap between a vast array of simplified physical models with corresponding brute-force numerical solvers modeling complex systems, offering accuracy, speed, data efficiency, as well as physical insights into the process.

Keywords

Cite

@article{arxiv.2111.05841,
  title  = {Physics-enhanced deep surrogates for partial differential equations},
  author = {Raphaël Pestourie and Youssef Mroueh and Chris Rackauckas and Payel Das and Steven G. Johnson},
  journal= {arXiv preprint arXiv:2111.05841},
  year   = {2023}
}
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