Optimization of the linear quadratic regulator (LQR) control quarter car suspension system using genetic algorithm

被引：0

作者：

Nagarkar, M. P. ^{[1
]}

Vikhe, G. J. ^{[2
]}

机构：

[1] AVCoE, India PhD Dept, SCSM Coll Engn, Sangamner, India

[2] AVCoE, Sangamner, India

来源：

INGENIERIA E INVESTIGACION | 2016年 / 36卷 / 01期

关键词：

Genetic algorithm (GA); MacPherson strut; quarter car; linear quadratic regulator (LQR); optimization; VEHICLE; DESIGN;

D O I：

10.15446/ing.investig.v36n1.49253

中图分类号：

T [工业技术];

学科分类号：

08 ;

摘要：

In this paper, a genetic algorithm (GA) based in an optimization approach is presented in order to search the optimum weighting matrix parameters of a linear quadratic regulator (LQR). A Macpherson strut quarter car suspension system is implemented for ride control application. Initially, the GA is implemented with the objective of minimizing root mean square (RMS) controller force. For single objective optimization, RMS controller force is reduced by 20.42% with slight increase in RMS sprung mass acceleration. Trade-off is observed between controller force and sprung mass acceleration. Further, an analysis is extended to multi-objective optimization with objectives such as minimization of RMS controller force and RMS sprung mass acceleration and minimization of RMS controller force, RMS sprung mass acceleration and suspension space deflection. For multi-objective optimization, Pareto-front gives flexibility in order to choose the optimum solution as per designer's need.

引用

页码：23 / 30

页数：8

共 50 条

[1] Multi-Objective Optimization of LQR Control Quarter Car Suspension System using Genetic Algorithm
Nagarkar, M. P.
Patil, G. J. Vikhe
[J]. FME TRANSACTIONS, 2016, 44 (02): : 187 - 196
[2] ACTIVE CONTROL OF QUARTER-CAR SUSPENSION SYSTEM USING LINEAR QUADRATIC REGULATOR
Nagarkar, M. P.
Vikhe, G. J.
Borole, K. R.
Nandedkar, V. M.
[J]. INTERNATIONAL JOURNAL OF AUTOMOTIVE AND MECHANICAL ENGINEERING, 2011, 3 : 364 - 372
[3] Control of Quarter-Car Active Suspension System Based on Optimized Fuzzy Linear Quadratic Regulator Control Method
Abut, Tayfun
Salkim, Enver
[J]. APPLIED SCIENCES-BASEL, 2023, 13 (15):
[4] Linear quadratic Gaussian control of a quarter-car suspension
ElMadany, MM
Abduljabbar, ZS
[J]. VEHICLE SYSTEM DYNAMICS, 1999, 32 (06) : 479 - 497
[5] Performance Analysis of Quarter Car Active Suspension System: LQR and H∞ Control Strategies
Nagarkar, M. P.
Patil, G. J. Vikhe
[J]. 2012 THIRD INTERNATIONAL CONFERENCE ON COMPUTING COMMUNICATION & NETWORKING TECHNOLOGIES (ICCCNT), 2012,
[6] Response Optimization and LQR based Control for Quarter Car Suspension with Seat-driver Model
Divekar, Amit A.
Mahajan, Bhushan D.
[J]. 2016 INTERNATIONAL CONFERENCE ON AUTOMATIC CONTROL AND DYNAMIC OPTIMIZATION TECHNIQUES (ICACDOT), 2016, : 1007 - 1012
[7] Modeling and Simulation of Quarter Car Semi Active Suspension System Using LQR Controller
Rao, K. Dhananjay
Kumar, Shambhu
[J]. PROCEEDINGS OF THE 3RD INTERNATIONAL CONFERENCE ON FRONTIERS OF INTELLIGENT COMPUTING: THEORY AND APPLICATIONS (FICTA) 2014, VOL 1, 2015, 327 : 441 - 448
[8] Active Suspension System Design Using Fuzzy Logic Control and Linear Quadratic Regulator
Abdeen, Ahmed A.
Ibrahim, Khalil
Nasr, Abo-Bakr M.
[J]. PROCEEDINGS OF THE INTERNATIONAL CONFERENCE ON ADVANCED INTELLIGENT SYSTEMS AND INFORMATICS 2018, 2019, 845 : 152 - 166
[9] A Linear Model of Quarter Car Active Suspension System Using Composite Nonlinear Feedback Control
Ismail, Muhamad Fahezal
Sam, Yahaya Md
Peng, Kemao
Aripin, Muhamad Khairi
Hamzah, Norhazimi
Hasan, Mohd Hanif Che
[J]. 2012 IEEE STUDENT CONFERENCE ON RESEARCH AND DEVELOPMENT (SCORED), 2012,
[10] Stability analysis of parallel robot under linear quadratic regulator control based on genetic algorithm optimization
Wang, Linjun
Shi, Baozhou
Zhang, Dong
Xu, Bo
Zhu, Zongxiao
Zhou, Lan
[J]. Jisuanji Jicheng Zhizao Xitong/Computer Integrated Manufacturing Systems, CIMS, 2022, 28 (01): : 112 - 123

← 1 2 3 4 5 →