A Geometric Approach to the Kinematics of the Canfield Joint
This work addresses kinematics modeling for robotic linkages like the Canfield joint, used in applications such as wrist replacements and precision pointing, but it is incremental as it builds upon and generalizes prior analyses.
The paper tackles the forward and inverse kinematics of the Canfield joint, a parallel robotic linkage for pointing applications, by providing a geometric derivation and generalizing previous analyses to include failure modes like leg freezing. It clarifies necessary assumptions and offers engineering guidance for practical use.
This paper details an accessible geometric derivation of the forward and inverse kinematics of a parallel robotic linkage known as the Canfield joint, which can be used for pointing applications. The original purpose of the Canfield joint was to serve as a human wrist replacement, and it can be utilized for other purposes such as the precision pointing and tracking of antennas, telescopes, and thrusters. We build upon previous analyses, and generalize them to include the situation where one of the three legs freezes; the kinematics are also substantially generalized beyond failure modes, detailed within. The core of this work states and clarifies the assumptions necessary to analyze this type of parallel robotic linkage. Specific guidance is included for engineering use cases.