English

Recovering missing CFD data for high-order discretizations using deep neural networks and dynamics learning

Computational Physics 2019-09-04 v3 Numerical Analysis

Abstract

Data I/O poses a significant bottleneck in large-scale CFD simulations; thus, practitioners would like to significantly reduce the number of times the solution is saved to disk, yet retain the ability to recover any field quantity (at any time instance) a posteriori. The objective of this work is therefore to accurately recover missing CFD data a posteriori at any time instance, given that the solution has been written to disk at only a relatively small number of time instances. We consider in particular high-order discretizations (e.g., discontinuous Galerkin), as such techniques are becoming increasingly popular for the simulation of highly separated flows. To satisfy this objective, this work proposes a methodology consisting of two stages: 1) dimensionality reduction and 2) dynamics learning. For dimensionality reduction, we propose a novel hierarchical approach. First, the method reduces the number of degrees of freedom within each element of the high-order discretization by applying autoencoders from deep learning. Second, the methodology applies principal component analysis to compress the global vector of encodings. This leads to a low-dimensional state, which associates with a nonlinear embedding of the original CFD data. For dynamics learning, we propose to apply regression techniques (e.g., kernel methods) to learn the discrete-time velocity characterizing the time evolution of this low-dimensional state. A numerical example on a large-scale CFD example characterized by nearly 13 million degrees of freedom illustrates the suitability of the proposed method in an industrial setting.

Keywords

Cite

@article{arxiv.1812.01177,
  title  = {Recovering missing CFD data for high-order discretizations using deep neural networks and dynamics learning},
  author = {Kevin T. Carlberg and Antony Jameson and Mykel J. Kochenderfer and Jeremy Morton and Liqian Peng and Freddie D. Witherden},
  journal= {arXiv preprint arXiv:1812.01177},
  year   = {2019}
}

Comments

Accepted in Journal of Computational Physics

R2 v1 2026-06-23T06:30:26.231Z