Bi-fidelity approximation for uncertainty quantification and sensitivity analysis of irradiated particle-laden turbulence.

Hillary R. Fairbanks, L. Jofre, G. Geraci, G. Iaccarino, A. Doostan
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引用次数: 13

Abstract

Efficiently performing predictive studies of irradiated particle-laden turbulent flows has the potential of providing significant contributions towards better understanding and optimizing, for example, concentrated solar power systems. As there are many uncertainties inherent in such flows, uncertainty quantification is fundamental to improve the predictive capabilities of the numerical simulations. For large-scale, multi-physics problems exhibiting high-dimensional uncertainty, characterizing the stochastic solution presents a significant computational challenge as many methods require a large number of high-fidelity solves. This requirement results in the need for a possibly infeasible number of simulations when a typical converged high-fidelity simulation requires intensive computational resources. To reduce the cost of quantifying high-dimensional uncertainties, we investigate the application of a non-intrusive, bi-fidelity approximation to estimate statistics of quantities of interest associated with an irradiated particle-laden turbulent flow. This method relies on exploiting the low-rank structure of the solution to accelerate the stochastic sampling and approximation processes by means of cheaper-to-run, lower fidelity representations. The application of this bi-fidelity approximation results in accurate estimates of the QoI statistics while requiring a small number of high-fidelity model evaluations.
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辐照粒子负载湍流不确定度量化及灵敏度分析的双保真近似。
有效地对受辐照的粒子负载湍流进行预测研究,有可能为更好地理解和优化(例如集中式太阳能发电系统)提供重大贡献。由于此类流动存在许多固有的不确定性,因此不确定性量化是提高数值模拟预测能力的基础。对于具有高维不确定性的大规模多物理场问题,由于许多方法需要大量高保真度的解,因此表征随机解是一项重大的计算挑战。当典型的聚合高保真仿真需要大量的计算资源时,这一需求导致需要可能不可行的模拟数量。为了减少量化高维不确定性的成本,我们研究了非侵入式双保真近似的应用,以估计与辐照粒子负载湍流相关的感兴趣量的统计量。该方法依赖于利用解的低秩结构,通过运行成本更低、保真度更低的表示来加速随机抽样和近似过程。这种双保真度近似的应用导致对qi统计数据的准确估计,同时需要少量的高保真度模型评估。
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