A robust optimization for damage detection using multiobjective genetic algorithm, neural network and fuzzy decision making

An inverse problem of damage identification and localization in a structure is modelled as a robust optimization problem. In the robust optimization problem, the optimum value and small variations around this optimum value are considered. The structural health monitoring damage detection problem is...

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Bibliographic Details
Published in:Inverse problems in science and engineering Vol. 28; no. 1; pp. 21 - 46
Main Authors: Alexandrino, Patricia da Silva Lopes, Gomes, Guilherme Ferreira, Cunha, Sebastião Simões
Format: Journal Article
Language:English
Published: Taylor & Francis 02.01.2020
Subjects:
artificial neural network
boundary element method
Damage detection
fuzzy decision making
multiobjective genetic algorithm
ISSN:1741-5977, 1741-5985
Online Access:Get full text
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Summary:An inverse problem of damage identification and localization in a structure is modelled as a robust optimization problem. In the robust optimization problem, the optimum value and small variations around this optimum value are considered. The structural health monitoring damage detection problem is solved using a multiobjective genetic algorithm. So, the robust optimum value is obtained by solving a multiobjective problem where a functional and a variance function of this functional are used. This variance function is obtained by a Design of Experiment with regression and also through a relation between functional variance and damage parameters found by artificial neural network. As a multiobjective genetic algorithm obtains multiple solutions, a fuzzy decision making technique finds the better tradeoff solution for the problem. Boundary element method is utilized to obtain the distribution of stress to elastostatic problem. Numerical results clearly show that the proposed strategy and the use an optimized fuzzy decision making results in accurate damage identification and represents a powerful tool for structural health monitoring. Based on the analysis and numerical results, suggestions to potential researchers have also been provided for future scopes.
ISSN:1741-5977
1741-5985
DOI:10.1080/17415977.2019.1583225