多相激波管仿真中模型误差检测的不确定性降低

IF 0.5 Q4 ENGINEERING, MECHANICAL Journal of Verification, Validation and Uncertainty Quantification Pub Date : 2021-06-06 DOI:10.1115/1.4051407
Chanyoung Park, Samaun Nili, Justin T. Mathew, F. Ouellet, R. Koneru, N. Kim, S. Balachandar, R. Haftka
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引用次数: 2

摘要

不确定度量化(UQ)是科学计算验证和验证的重要步骤。当不确定性大于模拟和实验的可接受范围时,验证可能是不确定的。因此,减少不确定度(UR)对于实现有意义的验证非常重要。本文中的一种独特方法是将模型误差与不确定性分离,以便UR能够揭示模型误差。本文旨在分享从水平冲击管模拟的UQ和UR中吸取的经验教训,其目的是验证可压缩多相流的颗粒阻力模型。首先,模拟UQ揭示了由于数值通量方案而导致的模拟预测的不一致性,这一点通过实验的参数设计得到了明确的证明。通过改进数值通量格式,消除了不一致性带来的不确定性,同时增加了整体预测误差。其次,实验的几何形状和简化的1D模拟模型之间的不匹配被确定为缺乏知识。在修改了模拟条件和实验后,根据专家的意见,由于失配导致的误差很小,这是出乎意料的。最后,基于严格的UQ降低了颗粒初始体积分数的不确定性。所有这些UR措施共同作用,揭示了模拟预测中隐藏的建模误差,这可能导致未来的模型改进。我们总结了从这次演习中吸取的经验教训,包括空洞的成功、有用的失败和欺骗性的成功。
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Uncertainty Reduction for Model Error Detection in Multiphase Shock Tube Simulation
Uncertainty quantification (UQ) is an important step in the verification and validation of scientific computing. Validation can be inconclusive when uncertainties are larger than acceptable ranges for both simulation and experiment. Therefore, uncertainty reduction (UR) is important to achieve meaningful validation. A unique approach in this paper is to separate model error from uncertainty such that UR can reveal the model error. This paper aims to share lessons learned from UQ and UR of a horizontal shock tube simulation, whose goal is to validate the particle drag force model for the compressible multiphase flow. First, simulation UQ revealed the inconsistency in simulation predictions due to the numerical flux scheme, which was clearly shown using the parametric design of experiments. By improving the numerical flux scheme, the uncertainty due to inconsistency was removed, while increasing the overall prediction error. Second, the mismatch between the geometry of the experiments and the simplified 1D simulation model was identified as a lack of knowledge. After modifying simulation conditions and experiments, it turned out that the error due to the mismatch was small, which was unexpected based on expert opinions. Last, the uncertainty in the initial volume fraction of particles was reduced based on rigorous UQ. All these UR measures worked together to reveal the hidden modeling error in the simulation predictions, which can lead to a model improvement in the future. We summarized the lessons learned from this exercise in terms of empty success, useful failure, and deceptive success.
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来源期刊
CiteScore
1.60
自引率
16.70%
发文量
12
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