Gaussian process hydrodynamics

IF 4.5 2区工程技术 Q1 MATHEMATICS, APPLIED

Applied Mathematics and Mechanics-English Edition Pub Date : 2023-04-18 DOI:10.1007/s10483-023-2990-9

H. Owhadi

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引用次数: 1

Abstract

We present a Gaussian process (GP) approach, called Gaussian process hydrodynamics (GPH) for approximating the solution to the Euler and Navier-Stokes (NS) equations. Similar to smoothed particle hydrodynamics (SPH), GPH is a Lagrangian particle-based approach that involves the tracking of a finite number of particles transported by a flow. However, these particles do not represent mollified particles of matter but carry discrete/partial information about the continuous flow. Closure is achieved by placing a divergence-free GP prior ξ on the velocity field and conditioning it on the vorticity at the particle locations. Known physics (e.g., the Richardson cascade and velocity increment power laws) is incorporated into the GP prior by using physics-informed additive kernels. This is equivalent to expressing ξ as a sum of independent GPs ξ^l, which we call modes, acting at different scales (each mode ξ^l self-activates to represent the formation of eddies at the corresponding scales). This approach enables a quantitative analysis of the Richardson cascade through the analysis of the activation of these modes, and enables us to analyze coarse-grain turbulence statistically rather than deterministically. Because GPH is formulated by using the vorticity equations, it does not require solving a pressure equation. By enforcing incompressibility and fluid-structure boundary conditions through the selection of a kernel, GPH requires significantly fewer particles than SPH. Because GPH has a natural probabilistic interpretation, the numerical results come with uncertainty estimates, enabling their incorporation into an uncertainty quantification (UQ) pipeline and adding/removing particles (quanta of information) in an adapted manner. The proposed approach is suitable for analysis because it inherits the complexity of state-of-the-art solvers for dense kernel matrices and results in a natural definition of turbulence as information loss. Numerical experiments support the importance of selecting physics-informed kernels and illustrate the major impact of such kernels on the accuracy and stability. Because the proposed approach uses a Bayesian interpretation, it naturally enables data assimilation and predictions and estimations by mixing simulation data and experimental data.

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高斯过程流体力学

我们提出了一种高斯过程（GP）方法，称为高斯过程流体动力学（GPH），用于近似Euler和Navier-Stokes（NS）方程的解。与光滑粒子流体动力学（SPH）类似，GPH是一种基于拉格朗日粒子的方法，涉及对流动输送的有限数量粒子的跟踪。然而，这些粒子并不代表物质的软化粒子，而是携带关于连续流动的离散/部分信息。闭合是通过在速度场上放置无发散的GP先验ξ并将其调节为粒子位置的涡度来实现的。已知的物理（例如，Richardson级联和速度增量幂律）通过使用物理知情的加性核被结合到GP先验中。这相当于将ξ表示为在不同尺度上作用的独立GPsξl的和，我们称之为模式（每个模式ξl自激活以表示在相应尺度上涡流的形成）。这种方法能够通过分析这些模式的激活来对理查森级联进行定量分析，并使我们能够从统计角度而非确定性地分析粗粒湍流。因为GPH是通过使用涡度方程来公式化的，所以它不需要求解压力方程。通过选择核来增强不可压缩性和流体结构边界条件，GPH需要的粒子比SPH少得多。由于GPH具有自然的概率解释，因此数值结果带有不确定性估计，从而能够将其纳入不确定性量化（UQ）管道，并以适当的方式添加/删除粒子（信息量）。所提出的方法适用于分析，因为它继承了最先进的密集核矩阵求解器的复杂性，并将湍流自然定义为信息损失。数值实验支持选择基于物理的核的重要性，并说明了这种核对精度和稳定性的主要影响。由于所提出的方法使用贝叶斯解释，它自然能够通过混合模拟数据和实验数据来实现数据同化、预测和估计。

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来源期刊

Applied Mathematics and Mechanics-English Edition 数学-力学

CiteScore

6.70

自引率

9.10%

发文量

106

审稿时长

2.0 months

期刊介绍： Applied Mathematics and Mechanics is the English version of a journal on applied mathematics and mechanics published in the People''s Republic of China. Our Editorial Committee, headed by Professor Chien Weizang, Ph.D., President of Shanghai University, consists of scientists in the fields of applied mathematics and mechanics from all over China. Founded by Professor Chien Weizang in 1980, Applied Mathematics and Mechanics became a bimonthly in 1981 and then a monthly in 1985. It is a comprehensive journal presenting original research papers on mechanics, mathematical methods and modeling in mechanics as well as applied mathematics relevant to neoteric mechanics.