Title :
Trajectory tracking control for intelligent vehicle based on the Euler-Lagrange systems
Author :
Chuang Guo ; Longfei Dong ; Yanrong Ge
Author_Institution :
Coll. of Electron. Inf. & Control Eng., Beijing Univ. of Technol., Beijing, China
fDate :
May 31 2014-June 2 2014
Abstract :
In this paper, an improved trajectory tracking control law is proposed for a four-wheel differential nonholonomic drive intelligent vehicle. Based on the kinematics model and Euler-Lagrange (EL) system of the vehicle, the control laws adopt an improved typical backstepping method to design the kinematics controller and a fast terminal sliding mode technique to devise the dynamic control law, which can completely track the desired trajectory in finite time. The system is global asymptotic stability by Lyapunov theory and the parameters are optimized through the pole assignment method when the vehicle is near the reference trajectory. Finally, simulations demonstrate the effectiveness and correctness of the proposed control strategy.
Keywords :
Lyapunov methods; asymptotic stability; control nonlinearities; control system synthesis; mobile robots; pole assignment; robot kinematics; trajectory control; variable structure systems; EL; Euler-Lagrange systems; Lyapunov theory; backstepping method; dynamic control law; fast terminal sliding mode technique; four-wheel differential nonholonomic drive intelligent vehicle; global asymptotic stability; kinematics controller design; kinematics model; pole assignment method; trajectory tracking control law; Kinematics; Mobile communication; Mobile robots; Trajectory; Vehicle dynamics; Vehicles; Wheels; Euler-Lagrange system; Intelligent vehicle; Lyapunov theory; Pole assignment; Trajectory tracking;
Conference_Titel :
Control and Decision Conference (2014 CCDC), The 26th Chinese
Conference_Location :
Changsha
Print_ISBN :
978-1-4799-3707-3
DOI :
10.1109/CCDC.2014.6852438
