Beyond black-boxes in Bayesian inverse problems and model validation: applications in solid mechanics of elastography

L. Bruder, P. Koutsourelakis
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引用次数: 6

Abstract

The present paper is motivated by one of the most fundamental challenges in inverse problems, that of quantifying model discrepancies and errors. While significant strides have been made in calibrating model parameters, the overwhelming majority of pertinent methods is based on the assumption of a perfect model. Motivated by problems in solid mechanics which, as all problems in continuum thermodynamics, are described by conservation laws and phenomenological constitutive closures, we argue that in order to quantify model uncertainty in a physically meaningful manner, one should break open the black-box forward model. In particular we propose formulating an undirected probabilistic model that explicitly accounts for the governing equations and their validity. This recasts the solution of both forward and inverse problems as probabilistic inference tasks where the problem's state variables should not only be compatible with the data but also with the governing equations as well. Even though the probability densities involved do not contain any black-box terms, they live in much higher-dimensional spaces. In combination with the intractability of the normalization constant of the undirected model employed, this poses significant challenges which we propose to address with a linearly-scaling, double-layer of Stochastic Variational Inference. We demonstrate the capabilities and efficacy of the proposed model in synthetic forward and inverse problems (with and without model error) in elastography.
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超越贝叶斯反问题和模型验证中的黑箱:在弹性力学中的应用
本文的动机是反问题中最基本的挑战之一,即量化模型差异和误差。虽然在校准模型参数方面取得了重大进展,但绝大多数相关方法都是基于完美模型的假设。固体力学中的问题和连续介质热力学中的所有问题一样,都是用守恒定律和现象学本构闭包来描述的,我们认为,为了以一种物理上有意义的方式量化模型的不确定性,我们应该打破黑箱正演模型。特别地,我们建议制定一个无向概率模型,明确地说明控制方程及其有效性。这将正反问题的解决方案重新塑造为概率推理任务,其中问题的状态变量不仅应与数据兼容,而且应与控制方程兼容。尽管所涉及的概率密度不包含任何黑箱项,但它们存在于更高维度的空间中。结合所采用的无向模型的归一化常数的顽固性,这提出了重大的挑战,我们建议用线性缩放的双层随机变分推理来解决。我们证明了所提出的模型在弹性学中综合正逆问题(有或没有模型误差)中的能力和有效性。
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