Robust tracking control design for Unicycle Mobile Robots with input saturation

被引:18
作者
Martinez, Edgar A. [1 ]
Rios, Hector [1 ,2 ]
Mera, Manuel [3 ]
机构
[1] Tecnol Nacl Mexico, Div Estudios Posgrad & Invest, IT La Laguna, Blvd Revoluc & Cuauhtemoc S-N, Torreon 27000, Coahuila, Mexico
[2] Catedras CONACYT, Av Insurgentes Sur 1582, Ciudad De Mexico 03940, Mexico
[3] Inst Politecn Nacl, ESIME, Av Ticoman 600, Ciudad De Mexico 07340, Mexico
来源
CONTROL ENGINEERING PRACTICE | 2021年 / 107卷
关键词
Unicycle Mobile Robots; Robust tracking control; Input saturation; BARRIER LYAPUNOV FUNCTIONS; TIME OBSTACLE AVOIDANCE; ACTUATOR SATURATION; MECHANICAL SYSTEMS; STATE CONSTRAINTS; ADAPTIVE-CONTROL; FEEDBACK; SUBJECT; MODEL;
D O I
10.1016/j.conengprac.2020.104676
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
In this paper a robust tracking control strategy is proposed for Unicycle Mobile Robots (UMRs) under the influence of some disturbances. The proposed strategy is designed taking into account the perturbed kinematic model and it is based on two robust control techniques: Sliding-Mode Control (SMC) and Attractive Ellipsoid Method (AEM). The control of the heading angle is designed by means of a saturated SMC algorithm while the position control is designed by means of the AEM considering a Barrier Lyapunov function (BLF) approach. Simulation results illustrate the performance of the proposed robust controller compared to a classic UMR controller. Finally, some experimental results and comparisons illustrate the performance of the proposed strategy.
引用
收藏
页数:11
相关论文
共 36 条
[1]   Integral Sliding Mode Control for Trajectory Tracking of Wheeled Mobile Robot in Presence of Uncertainties [J].
Bessas, Aicha ;
Benalia, Atallah ;
Boudjema, Fares .
JOURNAL OF CONTROL SCIENCE AND ENGINEERING, 2016, 2016
[2]  
Boyd S. P., 2004, Convex Optimization
[3]  
Brockett R.W, 1983, PROG MATH, P181
[4]   Control of mobile robots with uncertainties in the dynamical model: a discrete time sliding mode approach with experimental results [J].
Corradini, ML ;
Orlando, G .
CONTROL ENGINEERING PRACTICE, 2002, 10 (01) :23-34
[5]   Adaptive fuzzy dynamic surface control of nonlinear systems with input saturation and time-varying output constraints [J].
Edalati, L. ;
Sedigh, A. Khaki ;
Shooredeli, M. Aliyari ;
Moarefianpour, A. .
MECHANICAL SYSTEMS AND SIGNAL PROCESSING, 2018, 100 :311-329
[6]   Model predictive control of systems with deadzone and saturation [J].
Galuppini, Giacomo ;
Magni, Lalo ;
Raimondo, Davide Martino .
CONTROL ENGINEERING PRACTICE, 2018, 78 :56-64
[7]   Avoiding local minima in the potential field method using input-to-state stability [J].
Guerra, M. ;
Efimov, D. ;
Zheng, G. ;
Perruquetti, W. .
CONTROL ENGINEERING PRACTICE, 2016, 55 :174-184
[8]   Finite-time obstacle avoidance for unicycle-like robot subject to additive input disturbances [J].
Guerra, Matteo ;
Efimov, Denis ;
Zheng, Gang ;
Perruquetti, Wilfrid .
AUTONOMOUS ROBOTS, 2017, 41 (01) :19-30
[9]   Robust adaptive tracking control for a class of mechanical systems with unknown disturbances under actuator saturation [J].
Hu, Xin ;
Wei, Xinjiang ;
Zhang, Huifeng ;
Han, Jian ;
Liu, Xiuhua .
INTERNATIONAL JOURNAL OF ROBUST AND NONLINEAR CONTROL, 2019, 29 (06) :1893-1908
[10]   Control of LPV systems subject to state constraints and input saturation [J].
Hu, Yanmei ;
Duan, Guangren ;
Tan, Feng .
TRANSACTIONS OF THE INSTITUTE OF MEASUREMENT AND CONTROL, 2018, 40 (14) :3985-3993
1234