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Main Authors: Zhou, Xu-Hui, Han, Jiequn, Zafar, Muhammad I., Wolf, Eric M., Schrock, Christopher R., Roy, Christopher J., Xiao, Heng
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2312.11842
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author Zhou, Xu-Hui
Han, Jiequn
Zafar, Muhammad I.
Wolf, Eric M.
Schrock, Christopher R.
Roy, Christopher J.
Xiao, Heng
author_facet Zhou, Xu-Hui
Han, Jiequn
Zafar, Muhammad I.
Wolf, Eric M.
Schrock, Christopher R.
Roy, Christopher J.
Xiao, Heng
contents Recently, the use of neural networks to accelerate the solving of partial differential equations (PDEs) has gained significant traction in both academia and industry. However, employing neural networks as standalone surrogate models raises concerns about solution reliability, especially in precision-critical scientific tasks. This study introduces a novel "super-fidelity" method that leverages neural networks for warm-starting steady-state PDE solvers, ensuring both efficiency and accuracy. Inspired by super-resolution techniques in computer vision, this method maps low-fidelity solutions to high-fidelity targets using a vector-cloud neural network with equivariance (VCNN-e), a neural operator that preserves all necessary invariance and equivariance properties for scalar and vector predictions while seamlessly adapting to different spatial discretizations. We evaluated this approach in three scenarios: (1) a weakly nonlinear case involving low Reynolds number flows around elliptical cylinders, (2) a strongly nonlinear case with high Reynolds number flows over airfoils, and (3) a practical case with high Reynolds number flows over a wing. In all cases, the neural operator-based initialization accelerated convergence by at least two-fold compared to traditional methods, without sacrificing accuracy. The method's robustness and scalability are further demonstrated across different linear equation solvers and multi-process computing configurations. It also achieves overall time savings in scenarios with multiple simulations, even when accounting for model development time. Overall, our approach provides an effective means to accelerate steady-state PDE solutions using neural operators, maintaining high accuracy while significantly improving computational efficiency, particularly in precision-driven scientific applications.
format Preprint
id arxiv_https___arxiv_org_abs_2312_11842
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Neural operator-based super-fidelity: A warm-start approach for accelerating steady-state simulations
Zhou, Xu-Hui
Han, Jiequn
Zafar, Muhammad I.
Wolf, Eric M.
Schrock, Christopher R.
Roy, Christopher J.
Xiao, Heng
Computational Physics
Recently, the use of neural networks to accelerate the solving of partial differential equations (PDEs) has gained significant traction in both academia and industry. However, employing neural networks as standalone surrogate models raises concerns about solution reliability, especially in precision-critical scientific tasks. This study introduces a novel "super-fidelity" method that leverages neural networks for warm-starting steady-state PDE solvers, ensuring both efficiency and accuracy. Inspired by super-resolution techniques in computer vision, this method maps low-fidelity solutions to high-fidelity targets using a vector-cloud neural network with equivariance (VCNN-e), a neural operator that preserves all necessary invariance and equivariance properties for scalar and vector predictions while seamlessly adapting to different spatial discretizations. We evaluated this approach in three scenarios: (1) a weakly nonlinear case involving low Reynolds number flows around elliptical cylinders, (2) a strongly nonlinear case with high Reynolds number flows over airfoils, and (3) a practical case with high Reynolds number flows over a wing. In all cases, the neural operator-based initialization accelerated convergence by at least two-fold compared to traditional methods, without sacrificing accuracy. The method's robustness and scalability are further demonstrated across different linear equation solvers and multi-process computing configurations. It also achieves overall time savings in scenarios with multiple simulations, even when accounting for model development time. Overall, our approach provides an effective means to accelerate steady-state PDE solutions using neural operators, maintaining high accuracy while significantly improving computational efficiency, particularly in precision-driven scientific applications.
title Neural operator-based super-fidelity: A warm-start approach for accelerating steady-state simulations
topic Computational Physics
url https://arxiv.org/abs/2312.11842