Adaptive sliding mode control for six-DOF relative motion of spacecraft with input constraint

This paper addresses the synchronized control problem of relative position and attitude for spacecraft with input constraint. First, using dual quaternion, the kinematic and dynamic models of the six-degree-of-freedom relative motion of spacecraft are introduced. Second, a new adaptive sliding mode control scheme is proposed to guarantee the globally asymptotic convergence of relative motion despite the presence of control input constraint, parametric uncertainties and external disturbances. A detailed stability analysis of the resulting closed-loop system is included. Finally, simulation results are presented to illustrate the validity and effectiveness of the proposed controller, which has the following properties: (1) explicit accounting for the problem of input constraint, (2) fast convergent rate and accurate results can be obtained, (3) no chattering phenomenon is present in the control torque and control force, (4) self-adaptive regulation law is dynamically adjusted to ensure the tracking errors tend to zero asymptotically, (5) the upper bounds of unknown variables are estimated dynamically.

► The synchronized control for six-DOF relative motion of spacecraft is addressed. ► Dual quaternion is used to model the six-DOF relative motion of spacecraft. ► A new adaptive sliding mode control scheme with input constraint is proposed. ► The control scheme is robust to model uncertainties and external disturbances. ► No chattering phenomenon is present in the control torque and control force.