Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure

This paper focused on modelling of a gradient flexible plate system utilizing an evolutionary algorithm, namely particle swarm optimization (PSO) and cuckoo search (CS) algorithm. A square aluminium plate experimental rig with a gradient of 30 degrees and all edges clamped were designed and fabricat...

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Published in:INTERNATIONAL JOURNAL OF AUTOMOTIVE AND MECHANICAL ENGINEERING
Main Authors: Jamali, A.; Hassan, M. H.; Lidyana, R.; Hadi, M. S.
Format: Article
Language:English
Published: UNIV MALAYSIA PAHANG 2023
Subjects:
Online Access:https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001177174200001
author Jamali
A.; Hassan
M. H.; Lidyana
R.; Hadi, M. S.
spellingShingle Jamali
A.; Hassan
M. H.; Lidyana
R.; Hadi, M. S.
Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
Engineering
author_facet Jamali
A.; Hassan
M. H.; Lidyana
R.; Hadi, M. S.
author_sort Jamali
spelling Jamali, A.; Hassan, M. H.; Lidyana, R.; Hadi, M. S.
Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
INTERNATIONAL JOURNAL OF AUTOMOTIVE AND MECHANICAL ENGINEERING
English
Article
This paper focused on modelling of a gradient flexible plate system utilizing an evolutionary algorithm, namely particle swarm optimization (PSO) and cuckoo search (CS) algorithm. A square aluminium plate experimental rig with a gradient of 30 degrees and all edges clamped were designed and fabricated to acquire input-output vibration data experimentally. This input-output data was then applied in a system identification method, which used an evolutionary algorithm with a linear autoregressive with exogenous (ARX) model structure to generate a dynamic model of the system. The obtained results were then compared with the conventional method that is recursive least square (RLS). The developed models were evaluated based on the lowest mean square error (MSE), within the 95% confidence level of both auto and cross-correlation tests as well as high stability in the pole-zero diagram. Investigation of results indicates that both evolutionary algorithms provide lower MSE than RLS. It is demonstrated that intelligence algorithms, PSO and CS outperformed the conventional algorithm by 85% and 89%, respectively. However, in terms of the overall assessment, model order 4 by the CS algorithm was selected to be the ideal model in representing the dynamic modelling of the system since it had the lowest MSE value, which fell inside the 95% confidence threshold, indicating unbiasedness and stability.
UNIV MALAYSIA PAHANG
2229-8649
2180-1606
2023
20
3
10.15282/ijame.20.3.2023.01.0815
Engineering
Green Accepted, gold
WOS:001177174200001
https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001177174200001
title Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
title_short Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
title_full Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
title_fullStr Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
title_full_unstemmed Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
title_sort Implementation of Evolutionary Algorithms to Parametric Identification of Gradient Flexible Plate Structure
container_title INTERNATIONAL JOURNAL OF AUTOMOTIVE AND MECHANICAL ENGINEERING
language English
format Article
description This paper focused on modelling of a gradient flexible plate system utilizing an evolutionary algorithm, namely particle swarm optimization (PSO) and cuckoo search (CS) algorithm. A square aluminium plate experimental rig with a gradient of 30 degrees and all edges clamped were designed and fabricated to acquire input-output vibration data experimentally. This input-output data was then applied in a system identification method, which used an evolutionary algorithm with a linear autoregressive with exogenous (ARX) model structure to generate a dynamic model of the system. The obtained results were then compared with the conventional method that is recursive least square (RLS). The developed models were evaluated based on the lowest mean square error (MSE), within the 95% confidence level of both auto and cross-correlation tests as well as high stability in the pole-zero diagram. Investigation of results indicates that both evolutionary algorithms provide lower MSE than RLS. It is demonstrated that intelligence algorithms, PSO and CS outperformed the conventional algorithm by 85% and 89%, respectively. However, in terms of the overall assessment, model order 4 by the CS algorithm was selected to be the ideal model in representing the dynamic modelling of the system since it had the lowest MSE value, which fell inside the 95% confidence threshold, indicating unbiasedness and stability.
publisher UNIV MALAYSIA PAHANG
issn 2229-8649
2180-1606
publishDate 2023
container_volume 20
container_issue 3
doi_str_mv 10.15282/ijame.20.3.2023.01.0815
topic Engineering
topic_facet Engineering
accesstype Green Accepted, gold
id WOS:001177174200001
url https://www-webofscience-com.uitm.idm.oclc.org/wos/woscc/full-record/WOS:001177174200001
record_format wos
collection Web of Science (WoS)
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