Title :
Sliding-Mode Formation Control for Underactuated Surface Vessels
Author_Institution :
Alberta Univ., Edmonton
fDate :
6/1/2007 12:00:00 AM
Abstract :
Sliding-mode control laws for controlling multiple unmanned surface vessels in arbitrary formations are proposed. The presented formation control method uses local information as well as the planned gross motion of the formation to achieve mesh stability. A three-degree-of-freedom dynamic model has been used for the surface vessels. It is assumed that each vessel only has two actuators and the vessels are underactuated. Mesh stability and parameter uncertainty in the dynamic model and wave disturbance are considered in designing the controllers. It is shown that the internal dynamics of the underactuated system is also stable. The effectiveness and robustness of these control laws in the presence of parameter uncertainty in the dynamic model and wave disturbances and the mesh stability of the formation are demonstrated by computer simulation.
Keywords :
control system synthesis; marine vehicles; mobile robots; stability; uncertain systems; variable structure systems; computer simulation; controller design; dynamic model; mesh stability; multiple unmanned surface vessel; parameter uncertainty; planned gross motion; sliding-mode formation control; underactuated surface vessel; wave disturbance; Force control; Mobile robots; Robot control; Robust stability; Rough surfaces; Sliding mode control; Space vehicles; Surface roughness; Uncertain systems; Vehicle dynamics; Autonomous vehicle; disturbances; formation control; leader–follower; mesh stability; parameter uncertainty; sliding-mode control; surface vessel; underactuated system;
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2007.898961
