Sliding-mode control of a hydrostatic drive train with uncertain actuator dynamics

Author

Hao Sun ; Aschemann, Harald

Author_Institution

Univ. of Rostock, Rostock, Germany

fYear

2013

fDate

17-19 July 2013

Firstpage

3216

Lastpage

3221

Abstract

A sliding-mode approach with disturbance compensation is proposed in this paper for the tracking control of a hydrostatic drive train, which is commonly used in off-road vehicles. A control-oriented modelling results in a system of four nonlinear differential equations which are subject to uncertain actuator dynamics with saturation effects and unknown disturbances - a leakage volume flow and a disturbance torque acting on the hydraulic motor. The disturbances are estimated by a nonlinear reduced-order disturbance observer and used for a disturbance compensation. Thereby, the switching part in the sliding-mode control law and chattering phenomena can be reduced. Simulation results point out that the proposed approach leads to an excellent tracking performance despite the given uncertainties in the actuator dynamics.

Keywords

actuators; drives; nonlinear control systems; nonlinear differential equations; power transmission (mechanical); reduced order systems; time-varying systems; uncertain systems; variable structure systems; vehicles; chattering phenomena; control-oriented modelling; disturbance compensation; disturbance estimation; disturbance torque; hydraulic motor; hydrostatic drive train; leakage volume flow; nonlinear differential equation; nonlinear reduced-order disturbance observer; off-road vehicles; saturation effects; sliding-mode control law; switching part; tracking control; tracking performance; uncertain actuator dynamics; unknown disturbance; Actuators; Angular velocity; Equations; Mathematical model; Observers; Sliding mode control; Torque;

fLanguage

English

Publisher

ieee

Conference_Titel

Control Conference (ECC), 2013 European

Conference_Location

Zurich

Type

conf

Filename

6669571