Evaluation of state-specific transport properties using machine learning methods

Q3 Physics and Astronomy

Cybernetics and Physics Pub Date : 2023-06-30 DOI:10.35470/2226-4116-2023-12-1-34-41

V. Istomin, E. Kustova, Semen M. Lagutin, I. Y. Shalamov

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引用次数: 1

Abstract

In this study, machine learning algorithms are employed to calculate state-to-state transport coefficients in nonequilibrium reacting gas flows. The focus is on the evaluation of thermal conductivity, shear viscosity, and bulk viscosity coefficients under conditions of strong coupling between vibrational-chemical kinetics and gas dynamics. In order to solve a regression problem for evaluating state-to-state transport coefficients, a specific software application with user interface is developed, which allows loading, processing, and saving of data arrays; configuring model architecture; training and evaluating models with various optimizers, loss functions, and metrics; making predictions using trained models. Using the developed software the multi-layer perceptron regression model is constructed and trained. The model is assessed in a binary mixture of molecular and atomic nitrogen taking into account 48 vibrational states; the coefficients are computed in the wide temperature range for the varying mixture composition. Good agreement of the results with the original transport coefficients calculated using rigorous but computationally expensive kinetic theory algorithms is shown. Applying machine learning techniques yields a significant speedup of about two orders of magnitude in the computation of transport coefficients. It is concluded that implementation of machine learning methods may considerably reduce the computational efforts required for nonequilibrium flow simulations.

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使用机器学习方法评估特定状态的传输属性

在本研究中，机器学习算法用于计算非平衡反应气体流动的状态到状态输运系数。重点是在振动化学动力学和气体动力学之间强耦合的条件下评估热导率、剪切粘度和体积粘度系数。为了解决状态到状态传输系数评估的回归问题，开发了一个具有用户界面的特定软件应用程序，允许加载、处理和保存数据数组;配置模型体系结构;训练和评估模型与各种优化器，损失函数，和指标;使用训练过的模型进行预测。利用开发的软件构建并训练了多层感知器回归模型。该模型在考虑48种振动态的分子和原子氮二元混合物中进行评估;对于不同的混合成分，在较宽的温度范围内计算系数。结果与用严格但计算代价昂贵的动力学算法计算的原始输运系数很好地吻合。应用机器学习技术可以在传输系数的计算中产生大约两个数量级的显著速度。结论是，机器学习方法的实现可以大大减少非平衡流模拟所需的计算工作量。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Cybernetics and Physics Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

1.70

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： The scope of the journal includes: -Nonlinear dynamics and control -Complexity and self-organization -Control of oscillations -Control of chaos and bifurcations -Control in thermodynamics -Control of flows and turbulence -Information Physics -Cyber-physical systems -Modeling and identification of physical systems -Quantum information and control -Analysis and control of complex networks -Synchronization of systems and networks -Control of mechanical and micromechanical systems -Dynamics and control of plasma, beams, lasers, nanostructures -Applications of cybernetic methods in chemistry, biology, other natural sciences The papers in cybernetics with physical flavor as well as the papers in physics with cybernetic flavor are welcome. Cybernetics is assumed to include, in addition to control, such areas as estimation, filtering, optimization, identification, information theory, pattern recognition and other related areas.