A design method of a robust controller for hydraulic actuation with disturbance observers

In this paper, a design method of a robust controller for hydraulic actuators is proposed. Generally speaking, the hydraulic actuator generates hydraulic force, and a load is driven by the hydraulic force. In order to control the hydraulic actuators, non-linearity caused by chamber pressures and natural feedback meaning the effect by the load velocity on the hydraulic pressure dynamics should be considered. A controller with feedback linearization is one of the methods to compensate the effects of the non-linearity and the natural feedback. However, since the method is based on the model parameters of the hydraulic actuator, the control performance is affected by modeling errors and modeling uncertainties. Therefore, a robust controller for the hydraulic actuator is proposed to complement the disadvantage of the conventional method. To design the proposed controller, a part of the feedback linearization, that is, pressure (nonlinearity) compensation is used to linearize the hydraulic pressure dynamics virtually. By using the virtually linearized hydraulic dynamics and the nominal mass, the nominal model of the hydraulic pressure and that of the load motion dynamics model are designed. Then, the effects which prevent each dynamics from behaving as the nominal models are defined as disturbances. In the proposed controller, two types of the observers are designed to compensate the disturbances. In this paper, the design details are shown and the validity of the proposed method is shown by simulation and experiments.

[1]  Darwin G. Caldwell,et al.  On the role of load motion compensation in high-performance force control , 2012, 2012 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[2]  Darwin G. Caldwell,et al.  Control of a hydraulically-actuated quadruped robot leg , 2010, 2010 IEEE International Conference on Robotics and Automation.

[3]  Darwin G. Caldwell,et al.  Model-Based Hydraulic Impedance Control for Dynamic Robots , 2015 .

[4]  Zongxia Jiao,et al.  Extended-State-Observer-Based Output Feedback Nonlinear Robust Control of Hydraulic Systems With Backstepping , 2014, IEEE Transactions on Industrial Electronics.

[5]  Stefano Stramigioli,et al.  Passivity based control of hydraulic robot arms using natural Casimir functions: Theory and experiments , 2008, 2008 IEEE/RSJ International Conference on Intelligent Robots and Systems.

[6]  Darwin G. Caldwell,et al.  Towards versatile legged robots through active impedance control , 2015, Int. J. Robotics Res..

[7]  Andrew G. Alleyne,et al.  On the limitations of force tracking control for hydraulic active suspensions , 1998, Proceedings of the 1998 American Control Conference. ACC (IEEE Cat. No.98CH36207).

[8]  Shirley J. Dyke,et al.  Role of Control-Structure Interaction in Protective System Design , 1995 .

[9]  Bart L. R. De Moor,et al.  Robustness analysis and control system design for a hydraulic servo system , 1994, IEEE Trans. Control. Syst. Technol..

[10]  Rui Liu,et al.  Systematic control of a class of nonlinear systems with application to electrohydraulic cylinder pressure control , 2000, IEEE Trans. Control. Syst. Technol..

[11]  Kouhei Ohnishi,et al.  Motion control for advanced mechatronics , 1996 .

[12]  Yang Shi,et al.  Modeling and Robust Discrete-Time Sliding-Mode Control Design for a Fluid Power Electrohydraulic Actuator (EHA) System , 2013 .