Abstract
In this work a second order approach for reliability-based design optimization (RBDO) with mixtures of uncorrelated non-Gaussian variables is derived by applying second order reliability methods (SORM) and sequential quadratic programming (SQP). The derivation is performed by introducing intermediate variables defined by the incremental iso-probabilistic transformation at the most probable point (MPP). By using these variables in the Taylor expansions of the constraints, a corresponding general first order reliability method (FORM) based quadratic programming (QP) problem is formulated and solved in the standard normal space. The MPP is found in the physical space in the metric of Hasofer-Lind by using a Newton algorithm, where the efficiency of the Newton method is obtained by introducing an inexact Jacobian and a line-search of Armijo type. The FORM-based SQP approach is then corrected by applying four SORM approaches: Breitung, Hohenbichler, Tvedt and a recent suggested formula. The proposed SORM-based SQP approach for RBDO is accurate, efficient and robust. This is demonstrated by solving several established benchmarks, with values on the target of reliability that are considerable higher than what is commonly used, for mixtures of five different distributions (normal, lognormal, Gumbel, gamma and Weibull). Established benchmarks are also generalized in order to study problems with large number of variables and several constraints. For instance, it is shown that the proposed approach efficiently solves a problem with 300 variables and 240 constraints within less than 20 CPU minutes on a laptop. Finally, a most well-know deterministic benchmark of a welded beam is treated as a RBDO problem using the proposed SORM-based SQP approach.
Highlights
The first order reliability method by Hasofer and Lind (1974) is based on two key ingredients in the case of uncorrelated variables; the iso-probabilistic transformation (IsoT) and the most probable point
The outline of the paper is as follows: in Section 2 the first order reliability method (FORM)-based sequential quadratic programming (SQP) is derived by using the most probable point (MPP) and the IsoT, we introduce the four SORMbased corrections, in Section 4 the suggested second order approach for reliabilitybased design optimization (RBDO) is evaluated for several benchmarks, and, we present some concluding remarks
In this work second order reliability methods (SORM)-based RBDO is performed by SQP for large problem sizes with mixtures of non-Gaussian distributions and high targets of reliability
Summary
The first order reliability method by Hasofer and Lind (1974) is based on two key ingredients in the case of uncorrelated variables; the iso-probabilistic transformation (IsoT) and the most probable point. The SORM-based SQP approach for RBDO presented in this paper is proven to be efficient for solving large problem sizes with mixtures of non-Gaussian variables and high targets of reliability. This is demonstrated for a benchmark studied by Cho and Lee (2011) with 10 variables and 8 constraints, where the overall CPU-time for the SORM-based SQP approach is less than 12 seconds. The outline of the paper is as follows: in Section 2 the FORM-based SQP is derived by using the MPP and the IsoT, we introduce the four SORMbased corrections, in Section 4 the suggested second order approach for RBDO is evaluated for several benchmarks, and, we present some concluding remarks
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