Open AccessFreeing the Serial Mechanism Designer from Inverse Kinematic Solvability Constraints
Author(s) -
Diana C. W. Friedman,
Timothy M. Kowalewski,
Radivoje Jovanovic,
Jacob Rosen,
Blake Hannaford
Publication year - 2010
Publication title -
applied bionics and biomechanics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.397
H-Index - 23
eISSN - 1754-2103
pISSN - 1176-2322
DOI - 10.1155/2010/605978
Subject(s) - kinematics , inverse kinematics , inverse , forward kinematics , control theory (sociology) , actuator , serial manipulator , kinematics equations , mechanism (biology) , manipulator (device) , power (physics) , computer science , parallel manipulator , robotic arm , engineering , control engineering , robot kinematics , simulation , mathematics , robot , artificial intelligence , geometry , control (management) , physics , classical mechanics , quantum mechanics , mobile robot
This paper presents a fast numerical solution for the inverse kinematics of a serial manipulator. The method is implemented on the C-arm, a manipulator designed for use in robotic surgery. The inverse kinematics solution provides all possible solutions for any six degree-of-freedom serial manipulator, assuming that the forward kinematics are known and that it is possible to solve for the remaining joint angles if one joint angle’s value is known. With a fast numerical method and the current levels of computing power, designing a manipulator with closed-form inverse kinematics is no longer necessary. When designing the C-arm, we therefore chose to weigh other factors, such as actuator size and patient safety, more heavily than the ability to find a closed-form inverse kinematics solution.
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