Efficiency of PID Controller Based on Genetic Algorithm for controlling a Quarter Car Suspension System-Reference-Cited by-同舟云学术

Efficiency of PID Controller Based on Genetic Algorithm for controlling a Quarter Car Suspension System

Published:2022-02-08 Issue:22 Volume: Page:1-10
ISSN:2799-1156
Container-title:Journal of Electronics,Computer Networking and Applied Mathematics
language:en
Short-container-title:JECNAM

Author:

B Zineb.¹,A Abdelaziz.¹,CH Kheireddine.²

Affiliation:

1. LABGET Laboratory,Department of Electrical Engineering Faculty of Science and Technology Larbi Tebessi University Tebessa, Algeria.

2. LAAAS Laboratory, Department of Electronics Faculty of Technology University of Batna 2, 5000 Batna, Algeria

Abstract

the purpose of this paper is to improve the performance of a car's active suspension system (a quarter model), with two degrees of freedom , a combination of components and mechanisms ensure both passengers' comfort and driving safety, the stability and ride performance depends generally on the quality of the suspension , and this is why car manufacturers are turning to an adjustable suspension that can be adapted to any type of road surface as it controls vertical movement for car wheels. In this work we show how proportional integral differential (PID) controller tuned by using two methods, Ziegler Nichols and genetic algorithms (GA) can used to achieve a good performance of the active suspension system, The simulation results show the robustness and effectiveness of genetic algorithm (GA) in providing good ride quality and good road handling, however the presence of a time delay.

Publisher

HM Publishers

Reference28 articles.

1. M.Canal., M.Milanse., and all. Semi-active suspension control using fast model-predictive techniques, IEEE Transaction on control system Technology, vol 4, PP: 1034-1046. Nov 2006.

2. Chen H.Y., Huang S.J. Adaptative control for active suspension system. International conference on control and automatic.June, Budapest, Hungary.2005.

3. M. C. Smith, F. C. Wang. Performance benefited in passive vehicle suspension employing inserters. Vehicle system dynamics, vol 42, No 4, pp: 235-257. 2004.

4. T. T. Tran, H. Hasegawa. Advanced passive suspension with Interner device and optimization design for vehicle oscillation. International Journal of Mechanical Engineering and Robotics Research, vol 4, No 4, pp: 354. 2015.

5. J. Genov. Multi-criteria synthesis of frequency. Modulation Discrete control of semi-Active Vehicle suspension-Part 1 Analysis and control strategies. In IOP Conference Series: Materials science and Engineering, vol 618, No 1, pp: 012066. IOP Publishing, October 2019.

Cited by 2 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. A novel approach with a fuzzy sliding mode proportional integral control algorithm tuned by fuzzy method (FSMPIF);Scientific Reports;2023-05-05

2. Proposing an original control algorithm for the active suspension system to improve vehicle vibration: Adaptive fuzzy sliding mode proportional-integral-derivative tuned by the fuzzy (AFSPIDF);Heliyon;2023-03