Bayesian Experimental Design for Linear Elasticity

Sarah Eberle-Blick, Nuutti Hyvönen*

*Corresponding author for this work

Research output: Contribution to journalArticleScientificpeer-review

Abstract

This work considers Bayesian experimental design for the inverse boundary value problem of linear elasticity in a two-dimensional setting. The aim is to optimize the positions of compactly supported pressure activations on the boundary of the examined body in order to maximize the value of the resulting boundary deformations as data for the inverse problem of reconstructing the Lamé parameters inside the object. We resort to a linearized measurement model and adopt the framework of Bayesian experimental design, under the assumption that the prior and measurement noise distributions are mutually independent Gaussians. This enables the use of the standard Bayesian A-optimality criterion for deducing optimal positions for the pressure activations. The (second) derivatives of the boundary measurements with respect to the Lamé parameters and the positions of the boundary pressure activations are deduced to allow minimizing the corresponding objective function, i.e., the trace of the covariance matrix of the posterior distribution, by gradient-based optimization algorithms. Two-dimensional numerical experiments are performed to test the functionality of our approach: all introduced algorithms are able to improve experimental designs, but only exhaustive search reliably finds a global minimizer.
Original languageEnglish
Pages (from-to)1294-1319
Number of pages26
JournalInverse Problems and Imaging
Volume18
Issue number6
Early online dateApr 2024
DOIs
Publication statusE-pub ahead of print - Apr 2024
MoE publication typeA1 Journal article-refereed

Keywords

  • A-optimality
  • Bayesian experimental design
  • Lame<acute accent> parameters
  • Inverse problem
  • Linear elasticity

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