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Main Authors: Wang, Haixin, Cao, Yadi, Huang, Zijie, Liu, Yuxuan, Hu, Peiyan, Luo, Xiao, Song, Zezheng, Zhao, Wanjia, Liu, Jilin, Sun, Jinan, Zhang, Shikun, Wei, Long, Wang, Yue, Wu, Tailin, Ma, Zhi-Ming, Sun, Yizhou
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2408.12171
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author Wang, Haixin
Cao, Yadi
Huang, Zijie
Liu, Yuxuan
Hu, Peiyan
Luo, Xiao
Song, Zezheng
Zhao, Wanjia
Liu, Jilin
Sun, Jinan
Zhang, Shikun
Wei, Long
Wang, Yue
Wu, Tailin
Ma, Zhi-Ming
Sun, Yizhou
author_facet Wang, Haixin
Cao, Yadi
Huang, Zijie
Liu, Yuxuan
Hu, Peiyan
Luo, Xiao
Song, Zezheng
Zhao, Wanjia
Liu, Jilin
Sun, Jinan
Zhang, Shikun
Wei, Long
Wang, Yue
Wu, Tailin
Ma, Zhi-Ming
Sun, Yizhou
contents This paper explores the recent advancements in enhancing Computational Fluid Dynamics (CFD) tasks through Machine Learning (ML) techniques. We begin by introducing fundamental concepts, traditional methods, and benchmark datasets, then examine the various roles ML plays in improving CFD. The literature systematically reviews papers in recent five years and introduces a novel classification for forward modeling: Data-driven Surrogates, Physics-Informed Surrogates, and ML-assisted Numerical Solutions. Furthermore, we also review the latest ML methods in inverse design and control, offering a novel classification and providing an in-depth discussion. Then we highlight real-world applications of ML for CFD in critical scientific and engineering disciplines, including aerodynamics, combustion, atmosphere & ocean science, biology fluid, plasma, symbolic regression, and reduced order modeling. Besides, we identify key challenges and advocate for future research directions to address these challenges, such as multi-scale representation, physical knowledge encoding, scientific foundation model and automatic scientific discovery. This review serves as a guide for the rapidly expanding ML for CFD community, aiming to inspire insights for future advancements. We draw the conclusion that ML is poised to significantly transform CFD research by enhancing simulation accuracy, reducing computational time, and enabling more complex analyses of fluid dynamics. The paper resources can be viewed at https://github.com/WillDreamer/Awesome-AI4CFD.
format Preprint
id arxiv_https___arxiv_org_abs_2408_12171
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Recent Advances on Machine Learning for Computational Fluid Dynamics: A Survey
Wang, Haixin
Cao, Yadi
Huang, Zijie
Liu, Yuxuan
Hu, Peiyan
Luo, Xiao
Song, Zezheng
Zhao, Wanjia
Liu, Jilin
Sun, Jinan
Zhang, Shikun
Wei, Long
Wang, Yue
Wu, Tailin
Ma, Zhi-Ming
Sun, Yizhou
Machine Learning
This paper explores the recent advancements in enhancing Computational Fluid Dynamics (CFD) tasks through Machine Learning (ML) techniques. We begin by introducing fundamental concepts, traditional methods, and benchmark datasets, then examine the various roles ML plays in improving CFD. The literature systematically reviews papers in recent five years and introduces a novel classification for forward modeling: Data-driven Surrogates, Physics-Informed Surrogates, and ML-assisted Numerical Solutions. Furthermore, we also review the latest ML methods in inverse design and control, offering a novel classification and providing an in-depth discussion. Then we highlight real-world applications of ML for CFD in critical scientific and engineering disciplines, including aerodynamics, combustion, atmosphere & ocean science, biology fluid, plasma, symbolic regression, and reduced order modeling. Besides, we identify key challenges and advocate for future research directions to address these challenges, such as multi-scale representation, physical knowledge encoding, scientific foundation model and automatic scientific discovery. This review serves as a guide for the rapidly expanding ML for CFD community, aiming to inspire insights for future advancements. We draw the conclusion that ML is poised to significantly transform CFD research by enhancing simulation accuracy, reducing computational time, and enabling more complex analyses of fluid dynamics. The paper resources can be viewed at https://github.com/WillDreamer/Awesome-AI4CFD.
title Recent Advances on Machine Learning for Computational Fluid Dynamics: A Survey
topic Machine Learning
url https://arxiv.org/abs/2408.12171