Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty

Yao Wang; Shengkui Zeng; Jianbin Guo

doi:10.1109/QR2MSE.2013.6625623

Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty

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

Abstract

With the increasing of systems' scale and complexity, reliability analysis faces more challenges which mainly include hybrid uncertainty, implicit limit state function and numerous uncertain input variables. Non-intrusive polynomial chaos (NIPC) is a promising technology for uncertainty quantification with high efficiency and accuracy. However, as polynomial chaos is defined in probability space, NIPC is not applicable to reliability analysis under hybrid uncertainty with multiple input variables. To address this issue, an improved NIPC approach is proposed that Klir log-scale transformation is employed to unify fuzzy variables and random variables. And a combinatorial optimization algorithm is developed to efficiently select the optimal collocation points for NIPC with multiple uncertain inputs. Comparative study on the airborne retractable system shows that the proposed approach can achieve higher accuracy than response surface method with identical computational cost.

Original language	English
Title of host publication	QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering
Pages	460-464
Number of pages	5
DOIs	https://doi.org/10.1109/QR2MSE.2013.6625623
State	Published - 2013
Event	2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2013 - Sichuan, China Duration: 15 Jul 2013 → 18 Jul 2013

Publication series

Name	QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering

Conference

Conference	2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2013
Country/Territory	China
City	Sichuan
Period	15/07/13 → 18/07/13

Keywords

Reliability analysis
hybrid uncertainty
non-intrusive polynomial chaos
possibility distribution

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10.1109/QR2MSE.2013.6625623

Cite this

Wang, Y., Zeng, S., & Guo, J. (2013). Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty. In QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering (pp. 460-464). Article 6625623 (QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering). https://doi.org/10.1109/QR2MSE.2013.6625623

Wang, Yao ; Zeng, Shengkui ; Guo, Jianbin. / Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty. QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering. 2013. pp. 460-464 (QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering).

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title = "Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty",

abstract = "With the increasing of systems' scale and complexity, reliability analysis faces more challenges which mainly include hybrid uncertainty, implicit limit state function and numerous uncertain input variables. Non-intrusive polynomial chaos (NIPC) is a promising technology for uncertainty quantification with high efficiency and accuracy. However, as polynomial chaos is defined in probability space, NIPC is not applicable to reliability analysis under hybrid uncertainty with multiple input variables. To address this issue, an improved NIPC approach is proposed that Klir log-scale transformation is employed to unify fuzzy variables and random variables. And a combinatorial optimization algorithm is developed to efficiently select the optimal collocation points for NIPC with multiple uncertain inputs. Comparative study on the airborne retractable system shows that the proposed approach can achieve higher accuracy than response surface method with identical computational cost.",

keywords = "Reliability analysis, hybrid uncertainty, non-intrusive polynomial chaos, possibility distribution",

author = "Yao Wang and Shengkui Zeng and Jianbin Guo",

year = "2013",

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pages = "460--464",

booktitle = "QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering",

note = "2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2013 ; Conference date: 15-07-2013 Through 18-07-2013",

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Wang, Y , Zeng, S & Guo, J 2013, Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty. in QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering., 6625623, QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, pp. 460-464, 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering, QR2MSE 2013, Sichuan, China, 15/07/13. https://doi.org/10.1109/QR2MSE.2013.6625623

Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty. / Wang, Yao ; Zeng, Shengkui ; Guo, Jianbin.
QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering. 2013. p. 460-464 6625623 (QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering).

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

TY - GEN

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AU - Zeng, Shengkui

AU - Guo, Jianbin

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N2 - With the increasing of systems' scale and complexity, reliability analysis faces more challenges which mainly include hybrid uncertainty, implicit limit state function and numerous uncertain input variables. Non-intrusive polynomial chaos (NIPC) is a promising technology for uncertainty quantification with high efficiency and accuracy. However, as polynomial chaos is defined in probability space, NIPC is not applicable to reliability analysis under hybrid uncertainty with multiple input variables. To address this issue, an improved NIPC approach is proposed that Klir log-scale transformation is employed to unify fuzzy variables and random variables. And a combinatorial optimization algorithm is developed to efficiently select the optimal collocation points for NIPC with multiple uncertain inputs. Comparative study on the airborne retractable system shows that the proposed approach can achieve higher accuracy than response surface method with identical computational cost.

AB - With the increasing of systems' scale and complexity, reliability analysis faces more challenges which mainly include hybrid uncertainty, implicit limit state function and numerous uncertain input variables. Non-intrusive polynomial chaos (NIPC) is a promising technology for uncertainty quantification with high efficiency and accuracy. However, as polynomial chaos is defined in probability space, NIPC is not applicable to reliability analysis under hybrid uncertainty with multiple input variables. To address this issue, an improved NIPC approach is proposed that Klir log-scale transformation is employed to unify fuzzy variables and random variables. And a combinatorial optimization algorithm is developed to efficiently select the optimal collocation points for NIPC with multiple uncertain inputs. Comparative study on the airborne retractable system shows that the proposed approach can achieve higher accuracy than response surface method with identical computational cost.

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KW - possibility distribution

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Wang Y , Zeng S , Guo J. Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty. In QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering. 2013. p. 460-464. 6625623. (QR2MSE 2013 - Proceedings of 2013 International Conference on Quality, Reliability, Risk, Maintenance, and Safety Engineering). doi: 10.1109/QR2MSE.2013.6625623

Improved non-intrusive polynomial chaos for reliability analysis under hybrid uncertainty

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