Abstract
This article propounds addressing the design of a sliding mode controller with adaptive gains for trajectory tracking of unicycle mobile robots. The dynamics of this class of robots are strong, nonlinear, and subject to external disturbance. To compensate the effect of the unknown upper bounded external disturbances, a robust sliding mode controller based on an integral adaptive law is proposed. The salient feature of the developed controller resides in taking into account that the system is MIMO and the upper bound of disturbances is not priori known. Therefore, we relied on an estimation of each perturbation separately for each subsystem. Hence, the proposed controller provides a minimum acceptable errors and bounded adaptive laws with minimum of chattering problem. To complete the goal of the trajectory tracking, we apply a kinematic controller that takes into account the nonholonomic constraint of the robot. The stability and convergence properties of the proposed tracking dynamic and kinematic controllers are analytically proved using Lyapunov stability theory. Simulation results based on a comparative study show that the proposed controllers ensure better performances in terms of good robustness against disturbances, accuracy, minimum tracking errors, boundness of the adaptive gains, and minimum chattering effects.
Highlights
IntroductionThe tools of linear algebra allow obtaining for these systems and control laws possessing properties of stability and optimality.[1,2] Over the last decade, a lot of research effort has been put into the design of sophisticated control strategies for strongly nonlinear systems, such as nonholonomic mobile robots.[3,4,5,6,7,8] this class of robotic systems presents great advantages in terms of high energy efficiency, fast and precise response flexibility, and advanced control dynamics, it is very sensitive to disturbances and uncertainties
Control of linear systems is a well-proficient field
The objective of the kinematic controller proposed in this article is to elaborate a control law ðvc;wcÞ, which makes it possible to cancel the posture of error
Summary
The tools of linear algebra allow obtaining for these systems and control laws possessing properties of stability and optimality.[1,2] Over the last decade, a lot of research effort has been put into the design of sophisticated control strategies for strongly nonlinear systems, such as nonholonomic mobile robots.[3,4,5,6,7,8] this class of robotic systems presents great advantages in terms of high energy efficiency, fast and precise response flexibility, and advanced control dynamics, it is very sensitive to disturbances and uncertainties. This criteria has encouraged the researchers to focus deeply on studying the stability and trajectory tracking of the considered system.[7,8,9,10,11,12,13]
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