For many mechanical systems, including nearly all robotic manipulators, the set of possible configurations that the links may assume can be described by a system of polynomial equations. Thus, solving such systems is central to many problems in analyzing the motion of a mechanism or in designing a mechanism to achieve a desired motion. This paper describes techniques, based on polynomial continuation, for numerically solving such systems. Whereas in the past, these techniques were focused on finding isolated roots, we now address the treatment of systems having higher-dimensional solution sets. Special attention is given to cases of exceptional mechanisms, which have a higher degree of freedom of motion than predicted by their mobility. In fact, such mechanisms often have several disjoint assembly modes, and the degree of freedom of motion is not necessarily the same in each mode. Our algorithms identify all such assembly modes, determine their dimension and degree, and give sample points on each.
Advances in Polynomial Continuation for Solving Problems in Kinematics
Contributed by the Mechanisms and Robotics Committee for publication in the JOURNAL OF MECHANICAL DESIGN. Manuscript received July 2002; revised February 2003. Associate Editor: C. Mavroidis.
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Sommese, A. J., Verschelde, J., and Wampler, C. W. (May 5, 2004). "Advances in Polynomial Continuation for Solving Problems in Kinematics ." ASME. J. Mech. Des. March 2004; 126(2): 262–268. https://doi.org/10.1115/1.1649965
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