Bayesian calibration of multi-level model with unobservable distributed response and application to miter gates

•Bayesian calibration of multi-level model with unobservable and distributed outputs•Simultaneous model parameter estimation and model discrepancy quantification•A two-phase estimation method to overcome computational challenge•Practical application of the proposed approach to miter gate Bayesian ca...

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Bibliographic Details
Published in:Mechanical systems and signal processing 2022-05, Vol.170, p.108852, Article 108852
Main Authors: Jiang, Chen, Vega, Manuel A., Ramancha, Mukesh K., Todd, Michael D., Conte, Joel P., Parno, Matthew, Hu, Zhen
Format: Article
Language:English
Subjects:
Bayesian analysis
Bayesian calibration
Boundary conditions
Calibration
Distributed model discrepancy
Machine learning
Mathematical models
Miter gates
Mitre gates
Multi-level model
Parameter uncertainty
Polynomials
Surrogate model
Unobservable distributed response
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Summary:•Bayesian calibration of multi-level model with unobservable and distributed outputs•Simultaneous model parameter estimation and model discrepancy quantification•A two-phase estimation method to overcome computational challenge•Practical application of the proposed approach to miter gate Bayesian calibration plays a vital role in improving the validity of computational models’ predictive power. However, the presence of unobservable distributed responses and uncertain model parameters in multi-level models poses challenges to Bayesian calibration, due to the lack of direct observations and the difficulty in identifying the hidden and distributed model discrepancy under uncertainty. This paper proposes a Bayesian calibration framework for multi-level simulation models to calibrate an unobservable distributed model using measurements of an observable model. In the proposed framework, the distributed model discrepancy of an unobservable model with distributed response is first represented as a series of orthogonal polynomials, with the polynomial coefficients modelled by surrogate models with unknown hyper-parameters. A two-phase machine learning method is then developed to construct surrogate models of the polynomial coefficients based on measurements of an observable model. The constructed model discrepancy is finally used to update the uncertain model parameters by following a modularized Bayesian calibration scheme. The developed framework is applied to the joint Bayesian calibration of the uncertain gap length and unobservable and distributed boundary condition model for a miter gate problem. Results of the miter gate application demonstrate the efficacy of the proposed framework.
ISSN:0888-3270
1096-1216
DOI:10.1016/j.ymssp.2022.108852