利用神经算子加速粒子分辨直接数值模拟

IF 2.1 4区数学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Statistical Analysis and Data Mining Pub Date : 2024-05-29 DOI:10.1002/sam.11690

Mohammad Atif, Vanessa López‐Marrero, Tao Zhang, Abdullah Al Muti Sharfuddin, Kwangmin Yu, Jiaqi Yang, Fan Yang, Foluso Ladeinde, Yangang Liu, Meifeng Lin, Lingda Li

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引用次数: 0

摘要

我们介绍了我们正在进行的工作，该工作旨在加速一个粒子分辨直接数值模拟模型，该模型旨在研究气溶胶-云-湍流的相互作用。该动力学模型由两个主要部分组成--一组空气流速、温度和湿度的流体动力学方程，以及一组粒子（即云滴）追踪方程。我们没有试图用机器学习（ML）方法完全取代原始的数值求解方法，而是考虑开发一种混合方法。我们利用神经算子学习的潜力来建立快速准确的代用模型，并在本研究中开发了速度场和涡度场的代用模型。我们讨论了旨在评估所考虑的 ML 架构的性能及其捕捉相关动力系统行为的适用性的数值实验结果。

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Towards accelerating particle‐resolved direct numerical simulation with neural operators

We present our ongoing work aimed at accelerating a particle‐resolved direct numerical simulation model designed to study aerosol–cloud–turbulence interactions. The dynamical model consists of two main components—a set of fluid dynamics equations for air velocity, temperature, and humidity, coupled with a set of equations for particle (i.e., cloud droplet) tracing. Rather than attempting to replace the original numerical solution method in its entirety with a machine learning (ML) method, we consider developing a hybrid approach. We exploit the potential of neural operator learning to yield fast and accurate surrogate models and, in this study, develop such surrogates for the velocity and vorticity fields. We discuss results from numerical experiments designed to assess the performance of ML architectures under consideration as well as their suitability for capturing the behavior of relevant dynamical systems.

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来源期刊

Statistical Analysis and Data Mining COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCEC-COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

CiteScore

3.20

自引率

7.70%

发文量

期刊介绍： Statistical Analysis and Data Mining addresses the broad area of data analysis, including statistical approaches, machine learning, data mining, and applications. Topics include statistical and computational approaches for analyzing massive and complex datasets, novel statistical and/or machine learning methods and theory, and state-of-the-art applications with high impact. Of special interest are articles that describe innovative analytical techniques, and discuss their application to real problems, in such a way that they are accessible and beneficial to domain experts across science, engineering, and commerce. The focus of the journal is on papers which satisfy one or more of the following criteria: Solve data analysis problems associated with massive, complex datasets Develop innovative statistical approaches, machine learning algorithms, or methods integrating ideas across disciplines, e.g., statistics, computer science, electrical engineering, operation research. Formulate and solve high-impact real-world problems which challenge existing paradigms via new statistical and/or computational models Provide survey to prominent research topics.