Radial Basis Function Surrogates for Uncertainty Quantification and Aerodynamic Shape Optimization under Uncertainties

IF 1.8 Q3 MECHANICS

Fluids Pub Date : 2023-10-30 DOI:10.3390/fluids8110292

Varvara Asouti, Marina Kontou, Kyriakos Giannakoglou

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引用次数: 0

Abstract

This paper investigates the adequacy of radial basis function (RBF)-based models as surrogates in uncertainty quantification (UQ) and CFD shape optimization; for the latter, problems with and without uncertainties are considered. In UQ, these are used to support the Monte Carlo, as well as, the non-intrusive, Gauss Quadrature and regression-based polynomial chaos expansion methods. They are applied to the flow around an isolated airfoil and a wing to quantify uncertainties associated with the constants of the γ−R˜eθt transition model and the surface roughness (in the 3D case); it is demonstrated that the use of the RBF-based surrogates leads to an up to 50% reduction in computational cost, compared with the same UQ method that uses CFD computations. In shape optimization under uncertainties, solved by stochastic search methods, RBF-based surrogates are used to compute statistical moments of the objective function. In applications with geometric uncertainties which are modeled through the Karhunen–Loève technique, the use on an RBF-based surrogate reduces the turnaround time of an evolutionary algorithm by orders of magnitude. In this type of applications, RBF networks are also used to perform mesh displacement for the perturbed geometries.

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不确定性量化与不确定条件下气动外形优化的径向基函数替代

研究了基于径向基函数(RBF)模型在不确定性量化(UQ)和CFD形状优化中的充分性;对于后者，考虑了有不确定性和没有不确定性的问题。在UQ中，这些用于支持蒙特卡罗，以及非侵入式，高斯正交和基于回归的多项式混沌展开方法。它们被应用于孤立翼型和机翼周围的流动，以量化与γ−R≈θt过渡模型常数和表面粗糙度(在3D情况下)相关的不确定性;结果表明，与使用CFD计算的相同UQ方法相比，使用基于rbf的替代方法可以减少高达50%的计算成本。在不确定条件下的形状优化中，采用随机搜索方法求解，利用基于rbf的代理函数计算目标函数的统计矩。在通过karhunen - lo技术建模的具有几何不确定性的应用程序中，使用基于rbf的代理将进化算法的周转时间缩短了几个数量级。在这种类型的应用中，RBF网络也用于对扰动几何形状执行网格位移。

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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来源期刊

Fluids Engineering-Mechanical Engineering

CiteScore

3.40

自引率

10.50%

发文量

326

审稿时长

12 weeks