Generalized Kinematics Analysis of Hybrid Mechanisms Based on Screw Theory and Lie Groups Lie Algebras

Advanced mathematical tools are used to conduct research on the kinematics analysis of hybrid mechanisms, and the generalized analysis method and concise kinematics transfer matrix are obtained. In this study, first, according to the kinematics analysis of serial mechanisms, the basic principles of Lie groups and Lie algebras are briefly explained in dealing with the spatial switching and differential operations of screw vectors. Then, based on the standard ideas of Lie operations, the method for kinematics analysis of parallel mechanisms is derived, and Jacobian matrix and Hessian matrix are formulated recursively and in a closed form. Then, according to the mapping relationship between the parallel joints and corresponding equivalent series joints, a forward kinematics analysis method and two inverse kinematics analysis methods of hybrid mechanisms are examined. A case study is performed to verify the calculated matrices wherein a humanoid hybrid robotic arm with a parallel-series-parallel configuration is considered as an example. The results of a simulation experiment indicate that the obtained formulas are exact and the proposed method for kinematics analysis of hybrid mechanisms is practically feasible.

Automated summary

Advanced mathematical tools are used to conduct research on the kinematics analysis of hybrid mechanisms, leading to the development of a generalized analysis method and a concise kinematics transfer matrix. The study explores the basic principles of Lie groups and Lie algebras to derive a method for kinematics analysis of parallel mechanisms, formulating Jacobian matrix and Hessian matrix recursively. The proposed method for kinematics analysis of hybrid mechanisms is shown to be practically feasible through a simulation experiment on a humanoid hybrid robotic arm.