DESIGN OF A HYDRAULIC MOTION CONTROL SYSTEM USING TWO BACKSTEPPING TIME VARYING SLIDING MODE STRATEGIES

作     者：Abdullah, Aws M. Al–Samarraie, Shibly A. Ali, Hasan H. Al-Qassar, Arif A. 

作者机构：University of Baghdad Baghdad Iraq Control and Systems Engineering Department University of Technology Baghdad Iraq Directorate of Studies Planning and Follow-up Ministry of Higher Education and Scientific Research Baghdad Iraq 

出 版 物：《International Journal of Mechatronics and Applied Mechanics》 (Int. J. Mech. Appl. Mech.)

年 卷 期：2024年第2024卷第18期

页      面：250-263页

核心收录：

主　　题：Sliding mode control 

摘      要：A second-order sliding mode control is used for high-order uncertain plants using equivalent control approach to improve the performance of control systems. They combine backstepping with quasi-continuous controller and twisting controllers. This paper considers a two of the most popular controllers that are used to solve the nonlinearities problem which are the backstepping quasi-continuous control (BQCC) and backstepping twisting controllers to control the angular velocity of a hydraulic motor to improve tracking performance and robustness to uncertainties. For the system dynamics, a linear state feedback with suitable high gain was designed as the virtual controller, where steady state error can be made arbitrarily small according to the gain value. A time varying sliding variable was then selected based on the designed virtual controller. The main benefit of using time varying sliding variable is that the system torque required is initially zero, in addition to the fact that its increasing rate can be put in a suitable range. The system’s stability analysis has been presented using the Lyapunov function in the low level subsystem. The second order control action was used for the high level subsystem and the conventional sliding mode is used for the low level subsystem. The performance and the robustness of the proposed control in forcing the angular velocity to track the reference value (100-2000 RPM) with uncertainty of (+10%) and disturbances of (5-30 N.m) in the system parameters were studied. First, the mathematical model of the system was created. Then, Matlab-based simulation was used to assess the system performance. The results showed that the system exhibits excellent performance and robustness for multi-step input and multiplicative uncertainty. © 2024, Cefin Publishing House. All rights reserved.