Physic-informed probabilistic analysis with Bayesian machine learning in augmented space

Fangqi Hong; Pengfei Wei; Jingwen Song; Matthias G.R. Faes; Marcos A. Valdebenito; Michael Beer

doi:10.3850/978-981-18-5184-1_MS-06-055-cd

Physic-informed probabilistic analysis with Bayesian machine learning in augmented space

Fangqi Hong, Pengfei Wei, Jingwen Song, Matthias G.R. Faes, Marcos A. Valdebenito, Michael Beer

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Probabilistic engineering computation involves two groups of models, i.e., the probability model for characterizing the randomness of input variables, and the physic model (usually described as a set of PDEs) for describing the behavior of a physic system. The probabilistic analysis aims at propagating the probability models through the physic one, and this way to capture the probabilistic character of the outcomes of physic systems. The state-of-the-art developments for addressing this problem are mostly non-intrusive, which means to first generate a (large) number of random samples from the probability models, and for each sample, solve the PDEs via, e.g., finite element analysis. This strategy shows two main limitations. First, the computational cost is usually very high due to the huge number of physic model calls, each of which can be time-demanding. Second, it involves two sources of numerical errors, i.e., the one resulting from numerically solving the PDEs, and the one from the numerical solution of uncertainty propagation, these two are difficult to be evaluated with one quality, resulting in a disturbing risk with the results. In this paper, a new idea based on Bayesian machine learning in the state-probability joint space is developed for addressing this problem. Under this framework, the two numerical tasks mentioned above are formulated as one statistical inference problem, and both the information from the initial/boundary conditions and the PDEs grids are utilized for solving the inference problem with a Bayesian scheme. Both limitations of the non-intrusive methods have been overcome with the new scheme.

Original language	English
Title of host publication	Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022
Editors	Michael Beer, Enrico Zio, Kok-Kwang Phoon, Bilal M. Ayyub
Publisher	Research Publishing
Pages	152-159
Number of pages	8
ISBN (Print)	9789811851841
DOIs	https://doi.org/10.3850/978-981-18-5184-1_MS-06-055-cd
State	Published - 2024
Externally published	Yes
Event	8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022 - Hannover, Germany Duration: 4 Sep 2022 → 7 Sep 2022

Publication series

Name	Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022

Conference

Conference	8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022
Country/Territory	Germany
City	Hannover
Period	4/09/22 → 7/09/22

Keywords

Bayesian machine learning
Gaussian process regression
Probabilistic analysis
State-probability joint space

Access to Document

10.3850/978-981-18-5184-1_MS-06-055-cd

Cite this

Hong, F., Wei, P., Song, J., Faes, M. G. R., Valdebenito, M. A., & Beer, M. (2024). Physic-informed probabilistic analysis with Bayesian machine learning in augmented space. In M. Beer, E. Zio, K.-K. Phoon, & B. M. Ayyub (Eds.), Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022 (pp. 152-159). (Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022). Research Publishing. https://doi.org/10.3850/978-981-18-5184-1_MS-06-055-cd

Hong, Fangqi ; Wei, Pengfei ; Song, Jingwen et al. / Physic-informed probabilistic analysis with Bayesian machine learning in augmented space. Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022. editor / Michael Beer ; Enrico Zio ; Kok-Kwang Phoon ; Bilal M. Ayyub. Research Publishing, 2024. pp. 152-159 (Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022).

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title = "Physic-informed probabilistic analysis with Bayesian machine learning in augmented space",

abstract = "Probabilistic engineering computation involves two groups of models, i.e., the probability model for characterizing the randomness of input variables, and the physic model (usually described as a set of PDEs) for describing the behavior of a physic system. The probabilistic analysis aims at propagating the probability models through the physic one, and this way to capture the probabilistic character of the outcomes of physic systems. The state-of-the-art developments for addressing this problem are mostly non-intrusive, which means to first generate a (large) number of random samples from the probability models, and for each sample, solve the PDEs via, e.g., finite element analysis. This strategy shows two main limitations. First, the computational cost is usually very high due to the huge number of physic model calls, each of which can be time-demanding. Second, it involves two sources of numerical errors, i.e., the one resulting from numerically solving the PDEs, and the one from the numerical solution of uncertainty propagation, these two are difficult to be evaluated with one quality, resulting in a disturbing risk with the results. In this paper, a new idea based on Bayesian machine learning in the state-probability joint space is developed for addressing this problem. Under this framework, the two numerical tasks mentioned above are formulated as one statistical inference problem, and both the information from the initial/boundary conditions and the PDEs grids are utilized for solving the inference problem with a Bayesian scheme. Both limitations of the non-intrusive methods have been overcome with the new scheme.",

keywords = "Bayesian machine learning, Gaussian process regression, Probabilistic analysis, State-probability joint space",

author = "Fangqi Hong and Pengfei Wei and Jingwen Song and Faes, {Matthias G.R.} and Valdebenito, {Marcos A.} and Michael Beer",

note = "Publisher Copyright: {\textcopyright} 2022 ISRERM Organizers. Published by Research Publishing, Singapore.; 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022 ; Conference date: 04-09-2022 Through 07-09-2022",

year = "2024",

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language = "English",

isbn = "9789811851841",

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publisher = "Research Publishing",

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Hong, F, Wei, P, Song, J, Faes, MGR, Valdebenito, MA & Beer, M 2024, Physic-informed probabilistic analysis with Bayesian machine learning in augmented space. in M Beer, E Zio, K-K Phoon & BM Ayyub (eds), Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022. Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022, Research Publishing, pp. 152-159, 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022, Hannover, Germany, 4/09/22. https://doi.org/10.3850/978-981-18-5184-1_MS-06-055-cd

Physic-informed probabilistic analysis with Bayesian machine learning in augmented space. / Hong, Fangqi; Wei, Pengfei; Song, Jingwen et al.
Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022. ed. / Michael Beer; Enrico Zio; Kok-Kwang Phoon; Bilal M. Ayyub. Research Publishing, 2024. p. 152-159 (Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AB - Probabilistic engineering computation involves two groups of models, i.e., the probability model for characterizing the randomness of input variables, and the physic model (usually described as a set of PDEs) for describing the behavior of a physic system. The probabilistic analysis aims at propagating the probability models through the physic one, and this way to capture the probabilistic character of the outcomes of physic systems. The state-of-the-art developments for addressing this problem are mostly non-intrusive, which means to first generate a (large) number of random samples from the probability models, and for each sample, solve the PDEs via, e.g., finite element analysis. This strategy shows two main limitations. First, the computational cost is usually very high due to the huge number of physic model calls, each of which can be time-demanding. Second, it involves two sources of numerical errors, i.e., the one resulting from numerically solving the PDEs, and the one from the numerical solution of uncertainty propagation, these two are difficult to be evaluated with one quality, resulting in a disturbing risk with the results. In this paper, a new idea based on Bayesian machine learning in the state-probability joint space is developed for addressing this problem. Under this framework, the two numerical tasks mentioned above are formulated as one statistical inference problem, and both the information from the initial/boundary conditions and the PDEs grids are utilized for solving the inference problem with a Bayesian scheme. Both limitations of the non-intrusive methods have been overcome with the new scheme.

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Hong F, Wei P, Song J, Faes MGR, Valdebenito MA, Beer M. Physic-informed probabilistic analysis with Bayesian machine learning in augmented space. In Beer M, Zio E, Phoon KK, Ayyub BM, editors, Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022. Research Publishing. 2024. p. 152-159. (Proceedings of the 8th International Symposium on Reliability Engineering and Risk Management, ISRERM 2022). doi: 10.3850/978-981-18-5184-1_MS-06-055-cd

Physic-informed probabilistic analysis with Bayesian machine learning in augmented space

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