Generalization of non-intrusive imprecise stochastic simulation for mixed uncertain variables

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Jingwen Song
  • Pengfei Wei
  • Marcos Valdebenito
  • Sifeng Bi
  • Matteo Broggi
  • Michael Beer
  • Zuxiang Lei

Externe Organisationen

  • Northwestern Polytechnical University
  • Universidad Tecnica Federico Santa Maria
  • The University of Liverpool
  • Tongji University
  • East China Jiaotong University
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Details

OriginalspracheEnglisch
Aufsatznummer106316
FachzeitschriftMechanical Systems and Signal Processing
Jahrgang134
Frühes Online-Datum27 Aug. 2019
PublikationsstatusVeröffentlicht - 1 Dez. 2019

Abstract

Non-intrusive Imprecise Stochastic Simulation (NISS) is a recently developed general methodological framework for efficiently propagating the imprecise probability models and for estimating the resultant failure probability functions and bounds. Due to the simplicity, high efficiency, stability and good convergence, it has been proved to be one of the most appealing forward uncertainty quantification methods. However, the current version of NISS is only applicable for model with input variables characterized by precise and imprecise probability models. In real-world applications, the uncertainties of model inputs may also be characterized by non-probabilistic models such as interval model due to the extreme scarcity or imprecise information. In this paper, the NISS method is generalized for models with three kinds of mixed inputs characterized by precise probability model, non-probabilistic models and imprecise probability models respectively, and specifically, the interval model and distributional p-box model are exemplified. This generalization is realized by combining Bayes rule and the global NISS method, and is shown to conserve all the advantages of the classical NISS method. With this generalization, the three kinds of inputs can be propagated with only one set of function evaluations in a pure simulation manner, and two kinds of potential estimation errors are properly addressed by sensitivity indices and bootstrap. A numerical test example and the NASA uncertainty quantification challenging problem are solved to demonstrate the effectiveness of the generalized NISS procedure.

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Generalization of non-intrusive imprecise stochastic simulation for mixed uncertain variables. / Song, Jingwen; Wei, Pengfei; Valdebenito, Marcos et al.
in: Mechanical Systems and Signal Processing, Jahrgang 134, 106316, 01.12.2019.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Song J, Wei P, Valdebenito M, Bi S, Broggi M, Beer M et al. Generalization of non-intrusive imprecise stochastic simulation for mixed uncertain variables. Mechanical Systems and Signal Processing. 2019 Dez 1;134:106316. Epub 2019 Aug 27. doi: 10.1016/j.ymssp.2019.106316
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title = "Generalization of non-intrusive imprecise stochastic simulation for mixed uncertain variables",
abstract = "Non-intrusive Imprecise Stochastic Simulation (NISS) is a recently developed general methodological framework for efficiently propagating the imprecise probability models and for estimating the resultant failure probability functions and bounds. Due to the simplicity, high efficiency, stability and good convergence, it has been proved to be one of the most appealing forward uncertainty quantification methods. However, the current version of NISS is only applicable for model with input variables characterized by precise and imprecise probability models. In real-world applications, the uncertainties of model inputs may also be characterized by non-probabilistic models such as interval model due to the extreme scarcity or imprecise information. In this paper, the NISS method is generalized for models with three kinds of mixed inputs characterized by precise probability model, non-probabilistic models and imprecise probability models respectively, and specifically, the interval model and distributional p-box model are exemplified. This generalization is realized by combining Bayes rule and the global NISS method, and is shown to conserve all the advantages of the classical NISS method. With this generalization, the three kinds of inputs can be propagated with only one set of function evaluations in a pure simulation manner, and two kinds of potential estimation errors are properly addressed by sensitivity indices and bootstrap. A numerical test example and the NASA uncertainty quantification challenging problem are solved to demonstrate the effectiveness of the generalized NISS procedure.",
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note = "Funding Information: This work is supported by the National Natural Science of China (NSFC 51905430) and the Aerospace Science and Technology Foundation of China. The first author is supported by the program of China Scholarships Council (CSC). The second to fourth authors are all supported by the Alexander von Humboldt Foundation of Germany. The second author is also supported by the Top International University Visiting Program for Outstanding Young Scholars of Northwestern Polytechnical University. The third author acknowledges the support by CONICYT (National Commission for Scientific and Technological Research) under grant number 1180271. The authors also appreciate the two anonymous reviewers for their very useful comments and suggestions. ",
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T1 - Generalization of non-intrusive imprecise stochastic simulation for mixed uncertain variables

AU - Song, Jingwen

AU - Wei, Pengfei

AU - Valdebenito, Marcos

AU - Bi, Sifeng

AU - Broggi, Matteo

AU - Beer, Michael

AU - Lei, Zuxiang

N1 - Funding Information: This work is supported by the National Natural Science of China (NSFC 51905430) and the Aerospace Science and Technology Foundation of China. The first author is supported by the program of China Scholarships Council (CSC). The second to fourth authors are all supported by the Alexander von Humboldt Foundation of Germany. The second author is also supported by the Top International University Visiting Program for Outstanding Young Scholars of Northwestern Polytechnical University. The third author acknowledges the support by CONICYT (National Commission for Scientific and Technological Research) under grant number 1180271. The authors also appreciate the two anonymous reviewers for their very useful comments and suggestions.

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Non-intrusive Imprecise Stochastic Simulation (NISS) is a recently developed general methodological framework for efficiently propagating the imprecise probability models and for estimating the resultant failure probability functions and bounds. Due to the simplicity, high efficiency, stability and good convergence, it has been proved to be one of the most appealing forward uncertainty quantification methods. However, the current version of NISS is only applicable for model with input variables characterized by precise and imprecise probability models. In real-world applications, the uncertainties of model inputs may also be characterized by non-probabilistic models such as interval model due to the extreme scarcity or imprecise information. In this paper, the NISS method is generalized for models with three kinds of mixed inputs characterized by precise probability model, non-probabilistic models and imprecise probability models respectively, and specifically, the interval model and distributional p-box model are exemplified. This generalization is realized by combining Bayes rule and the global NISS method, and is shown to conserve all the advantages of the classical NISS method. With this generalization, the three kinds of inputs can be propagated with only one set of function evaluations in a pure simulation manner, and two kinds of potential estimation errors are properly addressed by sensitivity indices and bootstrap. A numerical test example and the NASA uncertainty quantification challenging problem are solved to demonstrate the effectiveness of the generalized NISS procedure.

AB - Non-intrusive Imprecise Stochastic Simulation (NISS) is a recently developed general methodological framework for efficiently propagating the imprecise probability models and for estimating the resultant failure probability functions and bounds. Due to the simplicity, high efficiency, stability and good convergence, it has been proved to be one of the most appealing forward uncertainty quantification methods. However, the current version of NISS is only applicable for model with input variables characterized by precise and imprecise probability models. In real-world applications, the uncertainties of model inputs may also be characterized by non-probabilistic models such as interval model due to the extreme scarcity or imprecise information. In this paper, the NISS method is generalized for models with three kinds of mixed inputs characterized by precise probability model, non-probabilistic models and imprecise probability models respectively, and specifically, the interval model and distributional p-box model are exemplified. This generalization is realized by combining Bayes rule and the global NISS method, and is shown to conserve all the advantages of the classical NISS method. With this generalization, the three kinds of inputs can be propagated with only one set of function evaluations in a pure simulation manner, and two kinds of potential estimation errors are properly addressed by sensitivity indices and bootstrap. A numerical test example and the NASA uncertainty quantification challenging problem are solved to demonstrate the effectiveness of the generalized NISS procedure.

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