Graph Neural Network Based Surrogate Model of Physics Simulations for Geometry Design

Computational Intelligence (CI) techniques have shown great potential as a surrogate model of expensive physics simulation, with demonstrated ability to make fast predictions, albeit at the expense of accuracy in some cases. For many scientific and engineering problems involving geometrical design,...

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Published in2022 IEEE Symposium Series on Computational Intelligence (SSCI) pp. 1469 - 1475
Main Authors Wong, Jian Cheng, Ooi, Chin Chun, Chattoraj, Joyjit, Lestandi, Lucas, Dong, Guoying, Kizhakkinan, Umesh, Rosen, David William, Jhon, Mark Hyunpong, Dao, My Ha
Format Conference Proceeding
LanguageEnglish
Published IEEE 04.12.2022
Subjects
Atmospheric modeling
Computational modeling
fast surrogate model
Geometry
Graph neural network
Graph neural networks
physics simulation
Predictive models
Task analysis
Training
Online AccessGet full text
DOI10.1109/SSCI51031.2022.10022022

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Abstract Computational Intelligence (CI) techniques have shown great potential as a surrogate model of expensive physics simulation, with demonstrated ability to make fast predictions, albeit at the expense of accuracy in some cases. For many scientific and engineering problems involving geometrical design, it is desirable for the surrogate models to precisely describe the change in geometry and predict the consequences. In that context, we develop graph neural networks (GNNs) as fast surrogate models for physics simulation, which allow us to directly train the models on 2/3D geometry designs that are represented by an unstructured mesh or point cloud, without the need for any explicit or hand-crafted parameterization. We utilize an encoder-processor-decoder-type architecture which can flexibly make prediction at both node level and graph level. The performance of our proposed GNN-based surrogate model is demonstrated on 2 example applications: feature designs in the domain of additive engineering and airfoil design in the domain of aerodynamics. The models show good accuracy in their predictions on a separate set of test geometries after training, with almost instant prediction speeds, as compared to O(hour) for the high-fidelity simulations required otherwise.
AbstractList Computational Intelligence (CI) techniques have shown great potential as a surrogate model of expensive physics simulation, with demonstrated ability to make fast predictions, albeit at the expense of accuracy in some cases. For many scientific and engineering problems involving geometrical design, it is desirable for the surrogate models to precisely describe the change in geometry and predict the consequences. In that context, we develop graph neural networks (GNNs) as fast surrogate models for physics simulation, which allow us to directly train the models on 2/3D geometry designs that are represented by an unstructured mesh or point cloud, without the need for any explicit or hand-crafted parameterization. We utilize an encoder-processor-decoder-type architecture which can flexibly make prediction at both node level and graph level. The performance of our proposed GNN-based surrogate model is demonstrated on 2 example applications: feature designs in the domain of additive engineering and airfoil design in the domain of aerodynamics. The models show good accuracy in their predictions on a separate set of test geometries after training, with almost instant prediction speeds, as compared to O(hour) for the high-fidelity simulations required otherwise.
Author Kizhakkinan, Umesh
Lestandi, Lucas
Ooi, Chin Chun
Dao, My Ha
Dong, Guoying
Wong, Jian Cheng
Chattoraj, Joyjit
Rosen, David William
Jhon, Mark Hyunpong
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  organization: Institute of High Performance Computing,Department of Fluid Dynamics,ASTAR,Singapore
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SubjectTerms Atmospheric modeling
Computational modeling
fast surrogate model
Geometry
Graph neural network
Graph neural networks
physics simulation
Predictive models
Task analysis
Training
Title Graph Neural Network Based Surrogate Model of Physics Simulations for Geometry Design
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