Optimization Control System using the Quantum Behaved Particle Swarm Optimization on Vehicle Steering Control System with Steer-by-Wire System
DOI:
https://doi.org/10.11113/jt.v71.3726Keywords:
Steering, fuzzy logic, quantum behaved particle swarm optimizationAbstract
Fuzzy Logic includes a technique are widely applied to the vehicle steering control system, however, to get the parameters required by a reliable Fuzzy Logic Control (FLC), needed training and learning process. Quantum behaved Particle Swarm Optimization (QPSO) is a simple optimization method that guarantees the achievement of global convergence quickly. This paper aimed to optimize of the steering control system on vehicle with steer-by-wire system using QPSO. The vehicle steering control system consists of Fuzzy Logic Control (FLC) and the Proportional, Integral and Derivative (PID) control are built in cascade, in which FLC is used to minimize the lateral motion error and PID control is used to suppress yaw motion error of the vehicle. The parameters of the control system are optimized by QPSO consists of three parameters to determine the position of the centre and the width of the triangle membership function of FLC and three constant gain of PID control. The optimization is done through the software in the loop simulation of vehicle models represented by 10 Degree of Freedom (DOF) of the vehicle dynamics. Simulation results showed that optimization using QPSO on the parameters of the control system can guarantee the movement of the vehicle is constantly maintained at the desired trajectory with a smaller error and higher vehicle speeds compared to the control system without tuned. The results obtained will be used as the basis for testing of the hardware in the loop simulation (HILS) so it can further improve the performance of steer-by-wire system.Â
References
S.H. Jang, T.J. Park and C.S. Han. 2003. A control of vehicle using steer-by-wire system with hardware-in-the-loop-simulation system. IEEE/ASME International Conference on Advanced Intelligent Mechatronics, AIM 2003. 1: 389–394.
A. Adriansyah. 2010. Perancangan Pengendali Robot Bergerak Berbasis Perilaku Menggunakan Particle Swarm Fuzzy Controller. J. Ilmu Komput. Dan Inf. 3(1): 1–9.
E.P. Ping, K. Hudha, H. Jamaluddin. 2010. Hardware-in-the-loop simulation of automatic steering control for lanekeeping manoeuvre: outer-loop and inner-loop control design. Int. J. Veh. Saf. 5(1): 35–59.
L. Cai, A.B. Rad, W.L. Chan. 2007. A Genetic Fuzzy Controller for Vehicle Automatic Steering Control. IEEE Trans. Veh. Technol. 56(2): 529–543.
J. Kennedy, R. Eberhart. 1995. Particle swarm optimization. IEEE International Conference on Neural Networks, University of Western Australia. Perth, Western Australia. 4: 1942–1948.
S.N. Omkar, R. Khandelwal, T.V.S. Ananth, G. Narayana Naik, S. Gopalakrishnan. 2009. Quantum behaved Particle Swarm Optimization (QPSO) for multi-objective design optimization of composite structures. Expert Syst. Appl. 36(8): 11312–11322.
K. Hudha, Z.A. Kadir, M.R. Said, H. Jamaluddin. 2009. Modelling, validation and roll moment rejection control of pneumatically actuated active roll control for improving vehicle lateral dynamics performance. Int. J. Eng. Syst. Model. Simul. 1(2/3): 122–132.
F. Ahmad, K. Hudha, H. Jamaluddin. 2009. Gain Scheduling PID Control with Pitch Moment Rejection for Reducing Vehicle Dive and Squat. Int. J. Veh. Saf. 4(1): 1–30.
P. Falcone, F. Borrelli, J. Asgari, H.E. Tseng, D. Hrovat. 2007. Predictive Active Steering Control for Autonomous Vehicle Systems. IEEE Trans. Control Syst. Technol. 15(3): 566–580.
M.R. Stone, M.A. Demetriou. 2000. Modeling and simulation of vehicle ride and handling performance. The 2000 IEEE International Symposium on Intelligent Contro. Rio Patras. 1(1): 85–90.
J. Wang, M.F. Hsieh. 2009. Vehicle yaw inertia and mass independent adaptive control for stability and trajectory tracking enhancements. American Control Conference 2009, ACC ’09. St. Louis, MO. 689–694.
F. Hunaini, I. Robandi, N. Sutantra. 2010. Model and Simulation of Vehicle Lateral Stability Control. 2nd APTECS, 2010, International Seminar on Applied Technology, Science, and Arts. ITS, Surabaya, Indonesia. 26.
F. Hunaini, I. Robandi, N. Sutantra. 2011. Vehicle Stability Control On Steer By Wire System Using Fuzzy Logic. in ICAST,2011, The International Student Conference on Advanced Science and Technology. Shandong University, Jinan, China. 3–4.
F. Hunaini, I. Robandi, N. Sutantra. 2012. Modeling and Simulation Of Vehicle Stability Control On Steer By Wire System Using Fuzzy Logic Control And PID Control Tuned By PSO. 3rd International Conference on Engineering and ICT (ICEI2012), Melaka, Malaysia. 85.
F.G. Martins. 2005. Tuning PID Controllers using the ITAE Criterion. Int. J. Eng. Educ. 21(5): 867–873.
Z. Zhisheng. 2010. Quantum-behaved particle swarm optimization algorithm for economic load dispatch of power system. Expert Syst. Appl. 37: 1800–1803.
F.G. Martins. 2005. Tuning PID Controllers using the ITAE Criterion. The International Journal of Engineering Education. 21: 867–873.
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