Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system

The purpose of controlling the vehicle handling is to ensure that the vehicle is in a safe condition and following its desire path. Vehicle yaw rate is controlled in order to achieve a good vehicle handling. In this paper, the optimal Composite Nonlinear Feedback (CNF) control technique is proposed...

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Main Authors: Y.M., Sam, Z., Mohamed, M., Khairi Aripin, M., Fahezal Ismail, L., Ramli
Format: Article
Language:en_US
Published: Penerbit UTM Press 2015
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Online Access:http://ddms.usim.edu.my/handle/123456789/8735
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Institution: Universiti Sains Islam Malaysia
Language: en_US
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spelling my.usim-87352017-02-23T03:00:24Z Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system Y.M., Sam, Z., Mohamed, M., Khairi Aripin, M., Fahezal Ismail, L., Ramli, Active front steering system Composite nonlinear feedback MOPSO Multiple objective Optimal controller Optimization Particle swarm optimization The purpose of controlling the vehicle handling is to ensure that the vehicle is in a safe condition and following its desire path. Vehicle yaw rate is controlled in order to achieve a good vehicle handling. In this paper, the optimal Composite Nonlinear Feedback (CNF) control technique is proposed for an Active Front Steering (AFS) system for improving the vehicle yaw rate response. The model used in order to validate the performance of controller is nonlinear vehicle model with 7 degree-of-freedom (DOF) and a bicycle model is implemented for the purpose of designing the controller. In designing an optimal CNF controller, the parameter estimation of linear and nonlinear gain becomes very important to produce the best output response. An intelligent algorithm is designed to minimize the time consumed to get the best parameter. To design an optimal method, Multi Objective Particle Swarm Optimization (MOPSO) is utilized to optimize the CNF controller performance. As a result, transient performance of the yaw rate has improved with the increased speed of in tracking and searching of the best optimized parameter estimation for the linear and the nonlinear gain of CNF controller. 2015-07-08T04:45:03Z 2015-07-08T04:45:03Z 2015 Article 1279696 http://ddms.usim.edu.my/handle/123456789/8735 en_US Penerbit UTM Press
institution Universiti Sains Islam Malaysia
building USIM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universit Sains Islam i Malaysia
content_source USIM Institutional Repository
url_provider http://ddms.usim.edu.my/
language en_US
topic Active front steering system
Composite nonlinear feedback
MOPSO
Multiple objective
Optimal controller
Optimization
Particle swarm optimization
spellingShingle Active front steering system
Composite nonlinear feedback
MOPSO
Multiple objective
Optimal controller
Optimization
Particle swarm optimization
Y.M., Sam,
Z., Mohamed,
M., Khairi Aripin,
M., Fahezal Ismail,
L., Ramli,
Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
description The purpose of controlling the vehicle handling is to ensure that the vehicle is in a safe condition and following its desire path. Vehicle yaw rate is controlled in order to achieve a good vehicle handling. In this paper, the optimal Composite Nonlinear Feedback (CNF) control technique is proposed for an Active Front Steering (AFS) system for improving the vehicle yaw rate response. The model used in order to validate the performance of controller is nonlinear vehicle model with 7 degree-of-freedom (DOF) and a bicycle model is implemented for the purpose of designing the controller. In designing an optimal CNF controller, the parameter estimation of linear and nonlinear gain becomes very important to produce the best output response. An intelligent algorithm is designed to minimize the time consumed to get the best parameter. To design an optimal method, Multi Objective Particle Swarm Optimization (MOPSO) is utilized to optimize the CNF controller performance. As a result, transient performance of the yaw rate has improved with the increased speed of in tracking and searching of the best optimized parameter estimation for the linear and the nonlinear gain of CNF controller.
format Article
author Y.M., Sam,
Z., Mohamed,
M., Khairi Aripin,
M., Fahezal Ismail,
L., Ramli,
author_facet Y.M., Sam,
Z., Mohamed,
M., Khairi Aripin,
M., Fahezal Ismail,
L., Ramli,
author_sort Y.M., Sam,
title Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
title_short Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
title_full Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
title_fullStr Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
title_full_unstemmed Composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
title_sort composite nonlinear feedback control with multi-objective particle swarm optimization for active front steering system
publisher Penerbit UTM Press
publishDate 2015
url http://ddms.usim.edu.my/handle/123456789/8735
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