Thibault Maurel-Oujia, Suhas S. Jain, Keigo Matsuda, Kai Schneider, Jacob R. West, Kazuki Maeda
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引用次数: 0
Abstract
Cluster and void formations are key processes in the dynamics of particle-laden turbulence. In this work, we assess the performance of various neural network models for synthesizing preferential concentration fields of particles in turbulence. A database of direct numerical simulations of homogeneous isotropic two-dimensional turbulence with one-way coupled inertial point particles, is used to train the models using vorticity as the input to predict the particle number density fields. We compare encoder–decoder, U-Net, generative adversarial network (GAN), and diffusion model approaches, and assess the statistical properties of the generated particle number density fields. We find that the GANs are superior in predicting clusters and voids, and therefore result in the best performance. Additionally, we explore a concept of “supersampling”, where neural networks can be used to predict full particle data using only the information of few particles, which yields promising perspectives for reducing the computational cost of expensive DNS computations by avoiding the tracking of millions of particles. We also explore the inverse problem of synthesizing the absolute values of the vorticity fields using the particle number density distribution as the input at different Stokes numbers. Hence, our study also indicates the potential use of neural networks to predict turbulent flow statistics using experimental measurements of inertial particles.
团聚和空隙形成是富含颗粒的湍流动力学中的关键过程。在这项工作中,我们评估了各种神经网络模型在合成湍流中粒子优先浓度场方面的性能。我们利用单向耦合惯性点粒子的均质各向同性二维湍流直接数值模拟数据库,以涡度作为预测粒子数量密度场的输入来训练模型。我们比较了编码器-解码器、U-Net、生成式对抗网络(GAN)和扩散模型方法,并评估了生成的粒子数密度场的统计特性。我们发现,生成式对抗网络在预测集群和空洞方面更胜一筹,因此性能最佳。此外,我们还探讨了 "超采样 "的概念,即神经网络可以仅使用少数粒子的信息来预测全部粒子数据,从而避免了对数百万个粒子的跟踪,为降低昂贵的 DNS 计算成本带来了广阔的前景。我们还探索了在不同斯托克斯数下使用粒子数密度分布作为输入合成涡度场绝对值的逆问题。因此,我们的研究还表明,利用惯性粒子的实验测量结果预测湍流统计量是神经网络的潜在用途。
期刊介绍:
Theoretical and Computational Fluid Dynamics provides a forum for the cross fertilization of ideas, tools and techniques across all disciplines in which fluid flow plays a role. The focus is on aspects of fluid dynamics where theory and computation are used to provide insights and data upon which solid physical understanding is revealed. We seek research papers, invited review articles, brief communications, letters and comments addressing flow phenomena of relevance to aeronautical, geophysical, environmental, material, mechanical and life sciences. Papers of a purely algorithmic, experimental or engineering application nature, and papers without significant new physical insights, are outside the scope of this journal. For computational work, authors are responsible for ensuring that any artifacts of discretization and/or implementation are sufficiently controlled such that the numerical results unambiguously support the conclusions drawn. Where appropriate, and to the extent possible, such papers should either include or reference supporting documentation in the form of verification and validation studies.
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