一种有效量化参数和模型不确定性的方法

IF 0.5 Q4 ENGINEERING, MECHANICAL
R. Feldmann, C. M. Gehb, M. Schäffner, T. Melz
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引用次数: 0

摘要

复杂的结构系统通常需要计算密集型模型,由于需要大量的模型评估,这些模型需要高效的统计模型校准方法。在本文中,我们提出了一种基于贝叶斯推理的有效统计模型校准方法,该方法建立在低保真度模型的计算速度与计算密集型高保真度模型的精度的结合之上。所提出的两阶段方法结合了自适应METROPOLIS算法和基于高斯过程(GP)的自适应代理模型作为低保真度模型。为了考虑模型的不确定性,我们在模型校准中加入了基于GP的差异函数。通过与模型参数一起校准差异函数的超参数,我们防止了模型校准的结果有偏差。该方法通过模块化主动弹簧阻尼器系统中阻尼参数的统计模型校准来说明,该系统是达姆施塔特工业大学SFB 805合作研究中心开发的一个结构系统。通过评估模块化主动弹簧-阻尼器系统数学模型的预测能力,量化并说明了应用我们的方法所实现的参数和模型不确定性的降低。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Methodology for the Efficient Quantification of Parameter and Model Uncertainty
Complex structural systems often entail computationally intensive models that require efficient methods for statistical model calibration due to the high number of required model evaluations. In this paper, we present a BAYESIAN inference-based methodology for efficient statistical model calibration that builds upon the combination of the speed in computation of a low-fidelity model with the accuracy of the computationally intensive high-fidelity model. The proposed two-stage method incorporates the adaptive METROPOLIS algorithm and a GAUSSIAN process (GP)-based adaptive surrogate model as low-fidelity model. In order to account for model uncertainty, we incorporate a GP-based discrepancy function into the model calibration. By calibrating the hyperparameters of the discrepancy function alongside the model parameters, we prevent the results of the model calibration to be biased. The methodology is illustrated by the statistical model calibration of a damping parameter in the modular active spring-damper system, a structural system developed within the collaborative research center SFB 805 at the Technical University of Darmstadt. The reduction of parameter and model uncertainty achieved by application of our methodology is quantified and illustrated by assessing the predictive capability of the mathematical model of the modular active spring-damper system.
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来源期刊
CiteScore
1.60
自引率
16.70%
发文量
12
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