Bayesian System Identification based on Hierarchical Sparse Bayesian Learning and Gibbs Sampling with Application to Structural Damage Assessment
Yong Huang, James L. Beck, Hui Li

TL;DR
This paper introduces two Gibbs sampling algorithms for Bayesian system identification that efficiently detect sparse structural damage using incomplete modal data, avoiding nonlinear eigenvalue problems and demonstrating robustness on benchmark studies.
Contribution
The paper proposes novel Gibbs sampling algorithms for Bayesian structural damage detection that handle posterior uncertainty and reduce computational complexity.
Findings
Algorithms effectively detect sparse stiffness changes from incomplete data.
No nonlinear eigenvalue problem solutions needed, improving computational efficiency.
Validated robustness and accuracy on benchmark structural damage datasets.
Abstract
The focus in this paper is Bayesian system identification based on noisy incomplete modal data where we can impose spatially-sparse stiffness changes when updating a structural model. To this end, based on a similar hierarchical sparse Bayesian learning model from our previous work, we propose two Gibbs sampling algorithms. The algorithms differ in their strategies to deal with the posterior uncertainty of the equation-error precision parameter, but both sample from the conditional posterior probability density functions (PDFs) for the structural stiffness parameters and system modal parameters. The effective dimension for the Gibbs sampling is low because iterative sampling is done from only three conditional posterior PDFs that correspond to three parameter groups, along with sampling of the equation-error precision parameter from another conditional posterior PDF in one of the…
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Taxonomy
MethodsAffine Coupling · Normalizing Flows
