构建用于求解不可压缩纳维-斯托克斯方程的人工神经网络

Pub Date : 2024-08-29 DOI:10.1134/S1064562424702156
V. B. Betelin, V. A. Galkin
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引用次数: 0

摘要

摘要根据传统的网格和投影方法分析复杂几何形状的粘性不可压缩流的动力学并使其可视化的任务,对实现既定目标所需的计算机性能有很高的要求。为了减少解决这类问题的计算负荷,可以应用人工神经网络(ANN)算法,使用给定空间区域上的纳维-斯托克斯方程精确解作为训练集来构建人工神经网络。人工神经网络用于构建由标准轴对称域(圆柱、球等)训练集组成的复合区域中的流动。为了减少三维问题的计算量,使用了低维度的不变量流形。这使得详细识别解的结构成为可能。研究发现,此类流动的典型不变区域是旋转图形,特别是与环同构的图形,它们构成拓扑束的结构,例如球、圆柱体和由此类图形组成的一般复合物。研究了根据最简单的三维非稳态涡流近似得到的流动结构。根据上述拓扑束的叠加,区分了不可压缩纳维-斯托克斯系统在 \({{\mathbb{R}}_{3}}\) 有界区域中的精确解的类别。数值对比实验表明,应用所提出的ANN类可以显著加快计算速度,从而允许使用低性能计算机。
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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Construction of an Artificial Neural Network for Solving the Incompressible Navier–Stokes Equations

The tasks of analyzing and visualizing the dynamics of viscous incompressible flows of complex geometry based on traditional grid and projection methods are associated with significant requirements for computer performance necessary to achieve the set goals. To reduce the computational load in solving this class of problems, it is possible to apply algorithms for constructing artificial neural networks (ANNs) using exact solutions of the Navier–Stokes equations on a given set of spatial regions as training sets. An ANN is implemented to construct flows in regions that are complexes made up of training sets of standard axisymmetric domains (cylinders, balls, etc.). To reduce the amount of calculations in the case of 3D problems, invariant flow manifolds of lower dimensions are used. This makes it possible to identify the structure of solutions in detail. It is established that typical invariant regions of such flows are figures of rotation, in particular, ones homeomorphic to the torus, which form the structure of a topological bundle, for example, in a ball, cylinder, and general complexes composed of such figures. The structures of flows obtained by approximation based on the simplest 3D unsteady vortex flows are investigated. Classes of exact solutions of the incompressible Navier–Stokes system in bounded regions of \({{\mathbb{R}}_{3}}\) are distinguished based on the superposition of the above-mentioned topological bundles. Comparative numerical experiments suggest that the application of the proposed class of ANNs can significantly speed up the computations, which allows the use of low-performance computers.

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