Title :
Kinematically optimal hyper-redundant manipulator configurations
Author :
Chirikjian, Gregory S. ; Burdick, Joel W.
Author_Institution :
Dept. of Mech. Eng., Johns Hopkins Univ., Baltimore, MD, USA
fDate :
12/1/1995 12:00:00 AM
Abstract :
“Hyper-redundant” robots have a very large or infinite degree of kinematic redundancy. This paper develops new methods for determining “optimal” hyper-redundant manipulator configurations based on a continuum formulation of kinematics. This formulation uses a backbone curve model to capture the robot´s essential macroscopic geometric features. The calculus of variations is used to develop differential equations, whose solution is the optimal backbone curve shape. We show that this approach is computationally efficient on a single processor, and generates solutions in O(1) time for an N degree-of-freedom manipulator when implemented in parallel on O(N) processors. For this reason, it is better suited to hyper-redundant robots than other redundancy resolution methods. Furthermore, this approach is useful for many hyper-redundant mechanical morphologies which are not handled by known methods
Keywords :
computational complexity; differential equations; manipulator kinematics; optimal control; redundancy; backbone curve model; continuum formulation; differential equations; kinematically optimal hyper-redundant manipulator configurations; macroscopic geometric features; Calculus; Concurrent computing; Differential equations; Kinematics; Manipulators; Morphology; Robots; Shape; Solid modeling; Spine;
Journal_Title :
Robotics and Automation, IEEE Transactions on
