English

Scalable physics-guided data-driven component model reduction for steady Navier-Stokes flow

Numerical Analysis 2024-10-30 v1 Numerical Analysis Computational Physics Fluid Dynamics

Abstract

Computational physics simulation can be a powerful tool to accelerate industry deployment of new scientific technologies. However, it must address the challenge of computationally tractable, moderately accurate prediction at large industry scales, and training a model without data at such large scales. A recently proposed component reduced order modeling (CROM) tackles this challenge by combining reduced order modeling (ROM) with discontinuous Galerkin domain decomposition (DG-DD). While it can build a component ROM at small scales that can be assembled into a large scale system, its application is limited to linear physics equations. In this work, we extend CROM to nonlinear steady Navier-Stokes flow equation. Nonlinear advection term is evaluated via tensorial approach or empirical quadrature procedure. Application to flow past an array of objects at moderate Reynolds number demonstrates 23.7\sim23.7 times faster solutions with a relative error of 2.3%\sim 2.3\%, even at scales 256256 times larger than the original problem.

Keywords

Cite

@article{arxiv.2410.21583,
  title  = {Scalable physics-guided data-driven component model reduction for steady Navier-Stokes flow},
  author = {Seung Whan Chung and Youngsoo Choi and Pratanu Roy and Thomas Roy and Tiras Y. Lin and Du T. Nguyen and Christopher Hahn and Eric B. Duoss and Sarah E. Baker},
  journal= {arXiv preprint arXiv:2410.21583},
  year   = {2024}
}

Comments

6 pages, 1 figure

R2 v1 2026-06-28T19:38:56.262Z