基于不确定性量化决策支持的半参数函数校准

IF 0.5 Q4 ENGINEERING, MECHANICAL
Anton van Beek, A. Giuntoli, Nitin K. Hansoge, S. Keten, Wei Chen
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引用次数: 0

摘要

虽然大多数校准方法侧重于推断一组未知但假设为常数的模型参数,但许多模型的参数与可控输入变量具有函数关系。通过对这些校准函数进行低维近似,建模人员可以使用低保真度模型来探索高保真度源无法达到的长度和时间尺度上的现象。虽然函数校准方法可用于低维问题(例如,一到三个未知校准函数),但由于其计算成本和可识别性问题的风险,探索未知校准函数(例如,超过十个)的高维空间仍然是一项具有挑战性的任务。为了应对这一挑战,我们引入了一种半参数校准方法,该方法使用近似贝叶斯计算方案来量化未知校准函数中的不确定性,并利用这一见解来确定哪些函数可以用低维近似代替。通过一个测试问题和环氧树脂的粗粒度模型,我们证明了所引入的方法能够识别低维校准函数集,同时在校准精度方面有有限的折衷。所提出的方法的新颖性在于能够综合来自各种来源(即物理实验、模拟模型和专家见解)的领域知识,以实现高维函数校准,而不需要关于未知校准函数类别的先验知识。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Semi-Parametric Functional Calibration Using Uncertainty Quantification Based Decision Support
While most calibration methods focus on inferring a set of model parameters that are unknown but assumed to be constant, many models have parameters that have a functional relation with the controllable input variables. Formulating a low-dimensional approximation of these calibration functions allows modelers to use low-fidelity models to explore phenomena at lengths and time scales unattainable with their high-fidelity sources. While functional calibration methods are available for low-dimensional problems (e.g., one to three unknown calibration functions), exploring high-dimensional spaces of unknown calibration functions (e.g., more than ten) is still a challenging task due to its computational cost and the risk for identifiability issues. To address this challenge, we introduce a semiparametric calibration method that uses an approximate Bayesian computation scheme to quantify the uncertainty in the unknown calibration functions and uses this insight to identify what functions can be replaced with low-dimensional approximations. Through a test problem and a coarse-grained model of an epoxy resin, we demonstrate that the introduced method enables the identification of a low-dimensional set of calibration functions with a limited compromise in calibration accuracy. The novelty of the presented method is the ability to synthesize domain knowledge from various sources (i.e., physical experiments, simulation models, and expert insight) to enable high-dimensional functional calibration without the need for prior knowledge on the class of unknown calibration functions.
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来源期刊
CiteScore
1.60
自引率
16.70%
发文量
12
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