NeuroSEM:通过耦合 PINNs 和频谱元素模拟多物理场问题的混合框架

IF 6.9 1区 工程技术 Q1 ENGINEERING, MULTIDISCIPLINARY
Khemraj Shukla , Zongren Zou , Chi Hin Chan , Additi Pandey , Zhicheng Wang , George Em Karniadakis
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引用次数: 0

摘要

多物理场问题的特点是流体动力学、热传递、结构力学和电磁学之间复杂的相互作用,由于其耦合性质,这些问题本身就具有挑战性。虽然可以获得某些状态变量的实验数据,但将这些数据与数值求解器进行整合仍是一项重大挑战。物理信息神经网络(PINNs)在各种工程学科中都取得了可喜的成果,特别是在处理噪声数据和解决偏微分方程(PDEs)中的逆问题方面。然而,它们在预测多物理场中的非线性现象,尤其是涉及湍流的非线性现象方面的有效性尚未完全确立。本研究介绍了 NeuroSEM,这是一个将 PINNs 与高保真谱元法 (SEM) 求解器 Nektar++ 相结合的混合框架。NeuroSEM 充分利用了 PINNs 和 SEM 的优势,为多物理场问题提供了稳健的解决方案。PINNs 经过训练,可以在特定子域中吸收数据并模拟物理现象,然后将其集成到 Nektar++ 求解器中。我们展示了 NeuroSEM 在空腔流热对流和流过圆柱体方面的效率和准确性。该框架通过处理数据可用的子域和状态变量,有效地处理了数据同化问题。我们将 NeuroSEM 应用于 Rayleigh-Bénard 对流系统,包括热边界条件缺失和数据集嘈杂的情况。最后,我们将提出的 NeuroSEM 框架应用于实际粒子图像测速仪(PIV)数据,以捕捉以马蹄形涡旋结构为特征的流动模式。结果表明,NeuroSEM 能准确模拟物理现象,并在指定的子域内同化数据。该框架的即插即用特性便于将其扩展到其他多物理场或多尺度问题。此外,NeuroSEM 经过优化,可在新兴的 GPU-CPU 集成架构上高效执行。这种混合方法提高了模拟的精度和效率,使其成为应对各种科学领域复杂工程挑战的强大工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
NeuroSEM: A hybrid framework for simulating multiphysics problems by coupling PINNs and spectral elements
Multiphysics problems that are characterized by complex interactions among fluid dynamics, heat transfer, structural mechanics, and electromagnetics, are inherently challenging due to their coupled nature. While experimental data on certain state variables may be available, integrating these data with numerical solvers remains a significant challenge. Physics-informed neural networks (PINNs) have shown promising results in various engineering disciplines, particularly in handling noisy data and solving inverse problems in partial differential equations (PDEs). However, their effectiveness in forecasting nonlinear phenomena in multiphysics regimes, particularly involving turbulence, is yet to be fully established. This study introduces NeuroSEM, a hybrid framework integrating PINNs with the high-fidelity Spectral Element Method (SEM) solver, Nektar++. NeuroSEM leverages the strengths of both PINNs and SEM, providing robust solutions for multiphysics problems. PINNs are trained to assimilate data and model physical phenomena in specific subdomains, which are then integrated into the Nektar++ solver. We demonstrate the efficiency and accuracy of NeuroSEM for thermal convection in cavity flow and flow past a cylinder. The framework effectively handles data assimilation by addressing those subdomains and state variables where the data is available. We applied NeuroSEM to the Rayleigh–Bénard convection system, including cases with missing thermal boundary conditions and noisy datasets. Finally, we applied the proposed NeuroSEM framework to real particle image velocimetry (PIV) data to capture flow patterns characterized by horseshoe vortical structures. Our results indicate that NeuroSEM accurately models the physical phenomena and assimilates the data within the specified subdomains. The framework’s plug-and-play nature facilitates its extension to other multiphysics or multiscale problems. Furthermore, NeuroSEM is optimized for efficient execution on emerging integrated GPU–CPU architectures. This hybrid approach enhances the accuracy and efficiency of simulations, making it a powerful tool for tackling complex engineering challenges in various scientific domains.
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来源期刊
CiteScore
12.70
自引率
15.30%
发文量
719
审稿时长
44 days
期刊介绍: Computer Methods in Applied Mechanics and Engineering stands as a cornerstone in the realm of computational science and engineering. With a history spanning over five decades, the journal has been a key platform for disseminating papers on advanced mathematical modeling and numerical solutions. Interdisciplinary in nature, these contributions encompass mechanics, mathematics, computer science, and various scientific disciplines. The journal welcomes a broad range of computational methods addressing the simulation, analysis, and design of complex physical problems, making it a vital resource for researchers in the field.
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