Title :
Coordinated control for velocity tracking of lunar rover on loose soil
Author :
Ge, Pingshu ; Wang, Rongben
Author_Institution :
Intell. Vehicle Group, Jilin Univ., Changchun, China
Abstract :
On lunar surface, terrain is mostly composed of fine grained soil in which a rover may be easily digging or stuck. So wheel-terrain interaction plays a key role in loose terrain mobility. Based on the characteristics of wheel-soil mechanics, in this paper a dynamic simulation model is developed with the equivalent conversion method in Adams. In order to achieve the velocity-tracking goal, a coordinated controller for velocity tracking based on slip ratio compensation is designed. The simulation is carried out by the approach of integrated simulation combining Adams with Matlab/simulink. The results indicate that the control method can reach the desired velocity quickly within the limited slip ratio.
Keywords :
compensation; control system synthesis; geotechnical engineering; lunar surface; soil; Adams; Matlab-simulink; coordinated control; dynamic simulation model; equivalent conversion method; fine grained soil; loose soil; loose terrain mobility; lunar rover; lunar surface; slip ratio compensation; velocity tracking; wheel-soil mechanics; wheel-terrain interaction; Educational institutions; Intelligent vehicles; Mathematical model; Moon; Soil; Stress; Transportation; Vehicle dynamics; Velocity control; Wheels; coordinated control; integrated simulation; lunar rover; velocity tracking; wheel-soil interaction mechanics;
Conference_Titel :
Computer Engineering and Technology (ICCET), 2010 2nd International Conference on
Conference_Location :
Chengdu
Print_ISBN :
978-1-4244-6347-3
DOI :
10.1109/ICCET.2010.5485508
