Abstract
Estimating the probability of rare failure events is an essential step in the reliability assessment of engineering systems. Computing this failure probability for complex non-linear systems is challenging, and has recently spurred the development of active-learning reliability methods. These methods approximate the limit-state function (LSF) using surrogate models trained with a sequentially enriched set of model evaluations. A recently proposed method called stochastic spectral embedding (SSE) aims to improve the local approximation accuracy of global, spectral surrogate modelling techniques by sequentially embedding local residual expansions in subdomains of the input space. In this work we apply SSE to the LSF, giving rise to a stochastic spectral embedding-based reliability (SSER) method. The resulting partition of the input space decomposes the failure probability into a set of easy-to-compute conditional failure probabilities. We propose a set of modifications that tailor the algorithm to efficiently solve rare event estimation problems. These modifications include specialized refinement domain selection, partitioning and enrichment strategies. We showcase the algorithm performance on four benchmark problems of various dimensionality and complexity in the LSF.
Highlights
Ensuring the reliability of structures and systems is a core task in many engineering disciplines
In this paper we propose a novel active learning reliability method that utilizes the recently proposed stochastic spectral embedding method (SSE, Marelli et al (2021)) and the active learning sequential partitioning approach developed for Bayesian inverse problems in Wagner et al (2021)
Leveraging the flexibility of the recently proposed stochastic spectral embedding formalism (Marelli et al, 2021), we show that the adaptive sequential partitioning approach introduced in (Wagner et al, 2021) can be efficiently modified to an active learning reliability method
Summary
Ensuring the reliability of structures and systems is a core task in many engineering disciplines. Analytical computation of the failure probability is rarely possible in practice and direct numerical integration (e.g., via quadrature) is often hindered by the inherently small scale of the failure probability and the potentially high input dimensionality M For these reasons, initial efforts in the reliability literature focused on developing methods that approximate the limit-state surface (Basler, 1960; Hasofer and Lind, 1974; Rackwitz and Fiessler, 1978; Zhang and Der Kiureghian, 1995; Hohenbichler et al, 1987; Breitung, 1989; Tvedt, 1990; Cai and Elishakoff, 1994).
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