Title :
A Dual Quaternion Solution to Attitude and Position Control for Rigid-Body Coordination
Author :
Xiangke Wang ; Changbin Yu ; Zhiyun Lin
Author_Institution :
Coll. of Mechatron. & Autom., Nat. Univ. of Defense Technol., Changsha, China
Abstract :
This paper focuses on finding a dual quaternion solution to attitude and position control for multiple rigid body coordination. Representing rigid bodies in 3-D space by unit dual quaternion kinematics, a distributed control strategy, together with a specified rooted-tree structure, are proposed to control the attitude and position of networked rigid bodies simultaneously with notion concision and nonsingularity. A property called pairwise asymptotic stability of the overall system is then analyzed and validated by an example of seven quad-rotor formation in the Urban Search And Rescue Simulation (USARSim) platform. As a separate but related issue, a maximum depth condition of the rooted tree is found with respect to error accumulation along each path using dual quaternion algebra, such that a given safety bound on attitude and position errors can be satisfied.
Keywords :
asymptotic stability; attitude control; distributed parameter systems; manipulator kinematics; position control; trees (mathematics); 3D space; USARSim platform; Urban Search And Rescue Simulation platform; attitude control; attitude errors; distributed control strategy; dual quaternion algebra; error accumulation; manipulators; maximum depth condition; multiple rigid body coordination; networked rigid bodies; notion concision; notion nonsingularity; pairwise asymptotic stability; position control; position errors; rooted-tree structure; unit dual quaternion kinematics; Aerospace electronics; Asymptotic stability; Attitude control; Quaternions; Robots; Stability analysis; Vectors; Attitude and position; error accumulation; multiple rigid-body coordination; pairwise asymptotic stability (PAS); unit dual quaternion;
Journal_Title :
Robotics, IEEE Transactions on
DOI :
10.1109/TRO.2012.2196310
