Structural reliability analysis on the basis of small samples: An interval quasi-Monte Carlo method

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  • University of Liverpool
  • Harbin Institute of Technology
  • University of Sydney
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Details

Original languageEnglish
Pages (from-to)137-151
Number of pages15
JournalMechanical Systems and Signal Processing
Volume37
Issue number1-2
Early online date22 Mar 2012
Publication statusPublished - May 2013
Externally publishedYes

Abstract

In practice, reliability analysis of structures is often performed on the basis of limited data. Under this circumstance, there are practical difficulties in identifying unique distributions as input for a probabilistic analysis. But the selection of realistic probabilistic input is critical for the quality of the results of the reliability analysis. This problem can be addressed using an entire set of plausible distribution functions rather than one single distribution for random variables based on limited data. The uncertain nature of the available information is then reflected in the probabilistic input. An imprecise probability distribution can be modeled by a probability box, i.e., the bounds of the cumulative distribution function for the random variable. Sampling-based methods have been proposed to perform reliability analysis with probability boxes. However, direct sampling of probability boxes requires a large number of samples. The computational cost can be very high as each simulation involves an interval analysis (a range-finding problem). This study proposes an interval quasi-Monte Carlo simulation methodology to efficiently compute the bounds of structure failure probabilities. The methodology is based on deterministic low-discrepancy sequences, which are distributed more regularly than the (pseudo) random points in direct Monte Carlo simulation. The efficiency and accuracy of the present method is illustrated using two examples. The reliability implications of different approaches for construction of probability boxes are also investigated through the example.

Keywords

    Epistemic uncertainty, Imprecise probability, Low-discrepancy sequence, Probability box, Quasi-Monte Carlo, Structural reliability

ASJC Scopus subject areas

Cite this

Structural reliability analysis on the basis of small samples: An interval quasi-Monte Carlo method. / Zhang, Hao; Dai, Hongzhe; Beer, Michael et al.
In: Mechanical Systems and Signal Processing, Vol. 37, No. 1-2, 05.2013, p. 137-151.

Research output: Contribution to journalArticleResearchpeer review

Zhang H, Dai H, Beer M, Wang W. Structural reliability analysis on the basis of small samples: An interval quasi-Monte Carlo method. Mechanical Systems and Signal Processing. 2013 May;37(1-2):137-151. Epub 2012 Mar 22. doi: 10.1016/j.ymssp.2012.03.001
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abstract = "In practice, reliability analysis of structures is often performed on the basis of limited data. Under this circumstance, there are practical difficulties in identifying unique distributions as input for a probabilistic analysis. But the selection of realistic probabilistic input is critical for the quality of the results of the reliability analysis. This problem can be addressed using an entire set of plausible distribution functions rather than one single distribution for random variables based on limited data. The uncertain nature of the available information is then reflected in the probabilistic input. An imprecise probability distribution can be modeled by a probability box, i.e., the bounds of the cumulative distribution function for the random variable. Sampling-based methods have been proposed to perform reliability analysis with probability boxes. However, direct sampling of probability boxes requires a large number of samples. The computational cost can be very high as each simulation involves an interval analysis (a range-finding problem). This study proposes an interval quasi-Monte Carlo simulation methodology to efficiently compute the bounds of structure failure probabilities. The methodology is based on deterministic low-discrepancy sequences, which are distributed more regularly than the (pseudo) random points in direct Monte Carlo simulation. The efficiency and accuracy of the present method is illustrated using two examples. The reliability implications of different approaches for construction of probability boxes are also investigated through the example.",
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N1 - Funding Information: This research was supported, in part, by grants from the Australian Research Council (Discovery Project DP110104263 ) and the National Natural Science Foundation of China (Project 10902028 and Project 50978078 ). These supports are gratefully acknowledged. However, the views expressed in this paper are solely those of the authors, and may not represent the positions of the sponsoring organizations. The authors would like to acknowledge the thoughtful suggestions of three anonymous reviewers, which substantially improved the present paper. The authors also acknowledge helpful discussions with Dr. Scott Ferson during the preparation of this paper.

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