Stochastic model updating with uncertainty quantification: an overview and tutorial
Stochastic model updating with uncertainty quantification: an overview and tutorial
This paper presents an overview of the theoretic framework of stochastic model updating, including critical aspects of model parameterisation, sensitivity analysis, surrogate modelling, test-analysis correlation, parameter calibration, etc. Special attention is paid to uncertainty analysis, which extends model updating from the deterministic domain to the stochastic domain. This extension is significantly promoted by uncertainty quantification metrics, no longer describing the model parameters as unknown-but-fixed constants but random variables with uncertain distributions, i.e. imprecise probabilities. As a result, the stochastic model updating no longer aims at a single model prediction with maximum fidelity to a single experiment, but rather a reduced uncertainty space of the simulation enveloping the complete scatter of multiple experiment data. Quantification of such an imprecise probability requires a dedicated uncertainty propagation process to investigate how the uncertainty space of the input is propagated via the model to the uncertainty space of the output. The two key aspects, forward uncertainty propagation and inverse parameter calibration, along with key techniques such as P-box propagation, statistical distance-based metrics, Markov chain Monte Carlo sampling, and Bayesian updating, are elaborated in this tutorial. The overall technical framework is demonstrated by solving the NASA Multidisciplinary UQ Challenge 2014, with the purpose of encouraging the readers to reproduce the result following this tutorial. The second practical demonstration is performed on a newly designed benchmark testbed, where a series of lab-scale aeroplane models are manufactured with varying geometry sizes, following pre-defined probabilistic distributions, and tested in terms of their natural frequencies and model shapes. Such a measurement database contains naturally not only measurement errors but also, more importantly, controllable uncertainties from the pre-defined distributions of the structure geometry. Finally, open questions are discussed to fulfil the motivation of this tutorial in providing researchers, especially beginners, with further directions on stochastic model updating with uncertainty treatment perspectives.
Bi, Sifeng
93deb24b-fda1-4b18-927b-6225976d8d3f
Beer, Michael
e44760ce-70c0-44f2-bb18-7197ba142788
Cogan, Scott
54b55b2c-27f8-4460-ac0c-565442551917
Mottershead, John
3f3812f1-59bd-40ef-a20b-8ffeb96b60e4
23 September 2023
Bi, Sifeng
93deb24b-fda1-4b18-927b-6225976d8d3f
Beer, Michael
e44760ce-70c0-44f2-bb18-7197ba142788
Cogan, Scott
54b55b2c-27f8-4460-ac0c-565442551917
Mottershead, John
3f3812f1-59bd-40ef-a20b-8ffeb96b60e4
Bi, Sifeng, Beer, Michael, Cogan, Scott and Mottershead, John
(2023)
Stochastic model updating with uncertainty quantification: an overview and tutorial.
Mechanical Systems and Signal Processing, 204, [110784].
(doi:10.1016/j.ymssp.2023.110784).
Abstract
This paper presents an overview of the theoretic framework of stochastic model updating, including critical aspects of model parameterisation, sensitivity analysis, surrogate modelling, test-analysis correlation, parameter calibration, etc. Special attention is paid to uncertainty analysis, which extends model updating from the deterministic domain to the stochastic domain. This extension is significantly promoted by uncertainty quantification metrics, no longer describing the model parameters as unknown-but-fixed constants but random variables with uncertain distributions, i.e. imprecise probabilities. As a result, the stochastic model updating no longer aims at a single model prediction with maximum fidelity to a single experiment, but rather a reduced uncertainty space of the simulation enveloping the complete scatter of multiple experiment data. Quantification of such an imprecise probability requires a dedicated uncertainty propagation process to investigate how the uncertainty space of the input is propagated via the model to the uncertainty space of the output. The two key aspects, forward uncertainty propagation and inverse parameter calibration, along with key techniques such as P-box propagation, statistical distance-based metrics, Markov chain Monte Carlo sampling, and Bayesian updating, are elaborated in this tutorial. The overall technical framework is demonstrated by solving the NASA Multidisciplinary UQ Challenge 2014, with the purpose of encouraging the readers to reproduce the result following this tutorial. The second practical demonstration is performed on a newly designed benchmark testbed, where a series of lab-scale aeroplane models are manufactured with varying geometry sizes, following pre-defined probabilistic distributions, and tested in terms of their natural frequencies and model shapes. Such a measurement database contains naturally not only measurement errors but also, more importantly, controllable uncertainties from the pre-defined distributions of the structure geometry. Finally, open questions are discussed to fulfil the motivation of this tutorial in providing researchers, especially beginners, with further directions on stochastic model updating with uncertainty treatment perspectives.
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Accepted/In Press date: 15 September 2023
e-pub ahead of print date: 23 September 2023
Published date: 23 September 2023
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Local EPrints ID: 489974
URI: http://eprints.soton.ac.uk/id/eprint/489974
ISSN: 0888-3270
PURE UUID: c5a264b3-5c1d-499b-9c02-cf7c72966621
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Date deposited: 09 May 2024 16:32
Last modified: 10 May 2024 02:07
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Author:
Sifeng Bi
Author:
Michael Beer
Author:
Scott Cogan
Author:
John Mottershead
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