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Rare event estimation with sequential directional importance sampling
Highlights Sequential directional importance sampling is proposed for rare event estimation. The method samples a series of distributions and approaches the optimal directional importance density adaptively. The proposed method is demonstrated to be efficient for various complex problems.
Abstract In this paper, we propose a sequential directional importance sampling (SDIS) method for rare event estimation. SDIS expresses a small failure probability in terms of a sequence of auxiliary failure probabilities, defined by magnifying the input variability. The first probability in the sequence is estimated with Monte Carlo simulation in Cartesian coordinates, and all the subsequent ones are computed with directional importance sampling in polar coordinates. Samples from the directional importance sampling densities used to estimate the intermediate probabilities are drawn in a sequential manner through a resample-move scheme. The latter is conveniently performed in Cartesian coordinates and directional samples are obtained through a suitable transformation. For the move step, we discuss two Markov Chain Monte Carlo (MCMC) algorithms for application in low and high-dimensional problems. Finally, an adaptive choice of the parameters defining the intermediate failure probabilities is proposed and the resulting coefficient of variation of the failure probability estimate is analyzed. The proposed SDIS method is tested on five examples in various problem settings, which demonstrate that the method outperforms existing sequential sampling reliability methods.
Rare event estimation with sequential directional importance sampling
Highlights Sequential directional importance sampling is proposed for rare event estimation. The method samples a series of distributions and approaches the optimal directional importance density adaptively. The proposed method is demonstrated to be efficient for various complex problems.
Abstract In this paper, we propose a sequential directional importance sampling (SDIS) method for rare event estimation. SDIS expresses a small failure probability in terms of a sequence of auxiliary failure probabilities, defined by magnifying the input variability. The first probability in the sequence is estimated with Monte Carlo simulation in Cartesian coordinates, and all the subsequent ones are computed with directional importance sampling in polar coordinates. Samples from the directional importance sampling densities used to estimate the intermediate probabilities are drawn in a sequential manner through a resample-move scheme. The latter is conveniently performed in Cartesian coordinates and directional samples are obtained through a suitable transformation. For the move step, we discuss two Markov Chain Monte Carlo (MCMC) algorithms for application in low and high-dimensional problems. Finally, an adaptive choice of the parameters defining the intermediate failure probabilities is proposed and the resulting coefficient of variation of the failure probability estimate is analyzed. The proposed SDIS method is tested on five examples in various problem settings, which demonstrate that the method outperforms existing sequential sampling reliability methods.
Rare event estimation with sequential directional importance sampling
Cheng, Kai (author) / Papaioannou, Iason (author) / Lu, Zhenzhou (author) / Zhang, Xiaobo (author) / Wang, Yanping (author)
Structural Safety ; 100
2022-10-03
Article (Journal)
Electronic Resource
English
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