4.6 Article

A Grasshopper Optimization Algorithm-Based Response Surface Method for Non-Probabilistic Structural Reliability Analysis with an Implicit Performance Function

期刊

BUILDINGS
卷 12, 期 7, 页码 -

出版社

MDPI
DOI: 10.3390/buildings12071061

关键词

non-probabilistic reliability analysis; response surface method; grasshopper optimization algorithm; finite element analysis

资金

  1. Basic Scientific Research Ability Improvement Project for Young and Middle-aged Teachers of Universities in GuangXi [2022KY1156]

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Non-probabilistic reliability analysis has great potential in structural reliability analysis, especially when it is difficult to obtain accurate probability distribution functions. This study proposes a response surface method based on the grasshopper optimization algorithm, which approximates the implicit performance functions using a quadratic polynomial and improves computing efficiency with a dynamic response surface updating strategy.
Non-probabilistic reliability analysis has great developmental potential in the field of structural reliability analysis, as it is often difficult to obtain enough samples to construct an accurate probability distribution function of random variables based on probabilistic theory. In practical engineering cases, the performance function (PF) is commonly implicit. Monte Carlo simulation (MCS) is commonly used for structural reliability analysis with implicit PFs. However, MCS requires the calculation of thousands of PF values. Such calculation could be time-consuming when the structural systems are complicated, and numerical analysis procedures such as the finite element method have to be adopted to obtain the PF values. To address this issue, this paper presents a grasshopper optimization algorithm-based response surface method (RSM). First, the method employs a quadratic polynomial to approximate the implicit PF with a small set of the actual values of the implicit PF. Second, the grasshopper optimization algorithm (GOA) is used to search for the global optimal solution of the scaling factor of the convex set since the problem of solving the reliability index is transformed into an unconstrained optimal problem. During the search process in the GOA, a dynamic response surface updating strategy is used to improve the approximate accuracy near the current optimal point to improve the computing efficiency. Two mathematical examples and two engineering structure examples that use the proposed method are given to verify its feasibility. The results compare favorably with those of MCS. The proposed method can be non-invasively combined with finite element analysis software to solve non-probabilistic reliability analysis problems of structures with implicit PF with high efficiency and high accuracy.

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