Shengyu Chen, Tianshu Bao, Peyman Givi, Can Zheng, Xiaowei Jia
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引用次数: 0
Abstract
Accurate simulation of turbulent flows is of crucial importance in many branches of science and engineering. Direct numerical simulation (DNS) provides the highest fidelity means of capturing all intricate physics of turbulent transport. However, the method is computationally expensive because of the wide range of turbulence scales that must be accounted for in such simulations. Large eddy simulation (LES) provides an alternative. In such simulations, the large scales of the flow are resolved and the effects of small scales are modelled. Reconstruction of the DNS field from the low-resolution LES is needed for a wide variety of applications. Thus the construction of super-resolution (SR) methodologies that can provide this reconstruction has become an area of active research. In this work, a new physics-guided neural network is developed for such a reconstruction. The method leverages the partial differential equation that underlies the flow dynamics in the design of spatio-temporal model architecture. A degradation-based refinement method is also developed to enforce physical constraints and to further reduce the accumulated reconstruction errors over long periods. Detailed DNS data on two turbulent flow configurations are used to assess the performance of the model.
湍流的精确模拟在许多科学和工程领域都至关重要。直接数值模拟(DNS)是捕捉湍流传输所有复杂物理现象的保真度最高的方法。然而,由于这种模拟必须考虑广泛的湍流尺度,因此计算成本高昂。大涡模拟(LES)提供了一种替代方法。在这种模拟中,流动的大尺度被解析,小尺度的影响被模拟。各种应用都需要从低分辨率 LES 中重建 DNS 场。因此,构建能够提供这种重构的超分辨率(SR)方法已成为一个活跃的研究领域。在这项工作中,为这种重建开发了一种新的物理引导神经网络。该方法在设计时空模型结构时利用了作为水流动力学基础的偏微分方程。此外,还开发了一种基于退化的细化方法,以执行物理约束并进一步减少长期累积的重建误差。两种湍流配置的详细 DNS 数据用于评估模型的性能。
期刊介绍:
ACM Transactions on Intelligent Systems and Technology is a scholarly journal that publishes the highest quality papers on intelligent systems, applicable algorithms and technology with a multi-disciplinary perspective. An intelligent system is one that uses artificial intelligence (AI) techniques to offer important services (e.g., as a component of a larger system) to allow integrated systems to perceive, reason, learn, and act intelligently in the real world.
ACM TIST is published quarterly (six issues a year). Each issue has 8-11 regular papers, with around 20 published journal pages or 10,000 words per paper. Additional references, proofs, graphs or detailed experiment results can be submitted as a separate appendix, while excessively lengthy papers will be rejected automatically. Authors can include online-only appendices for additional content of their published papers and are encouraged to share their code and/or data with other readers.