论文信息 - A Lie Group Formulation of Robot Dynamics

A Lie Group Formulation of Robot Dynamics

In this article we present a unified geometric treatment of robot dynamics. Using standard ideas from Lie groups and Rieman nian geometry, we formulate the equations of motion for an open chain manipulator both recursively and in closed form. The recursive formulation leads to an O(n) algorithm that ex presses the dynamics entirely in terms of coordinate-free Lie algebraic operations. The Lagrangian formulation also ex presses the dynamics in terms of these Lie algebraic operations and leads to a particularly simple set of closed-form equations, in which the kinematic and inertial parameters appear explic itly and independently of each other. The geometric approach permits a high-level, coordinate-free view of robot dynamics that shows explicitly some of the connections with the larger body of work in mathematics and physics. At the same time the resulting equations are shown to be computationally ef fective and easily differentiated and factored with respect to any of the robot parameters. This latter feature makes the ge ometric formulation attractive for applications such as robot design and calibration, motion optimization, and optimal control, where analytic gradients involving the dynamics are required.

[1] D. T. Greenwood. Principles of dynamics , 1965 .

[2] J. Y. S. Luh,et al. Erratum: “On-Line Computational Scheme for Mechanical Manipulators” (Journal of Dynamic Systems, Measurement, and Control, 1980, 102, pp. 69–76) , 1980 .

[3] Roger W. Brockett,et al. Robotic manipulators and the product of exponentials formula , 1984 .

[4] Roy Featherstone,et al. Robot Dynamics Algorithms , 1987 .

[5] K. Kreutz,et al. A Spatial Operator Algebra For Manipulator Modeling And Control , 1988, Other Conferences.

[6] Mark W. Spong,et al. Robot dynamics and control , 1989 .

[7] Rajnikant V. Patel,et al. Dynamic analysis of robot manipulators - a Cartesian tensor approach , 1991, The Kluwer international series in engineering and computer science.

[8] Rajnikant V. Patel,et al. Dynamic Analysis of Robot Manipulators , 1991 .

[9] Mark W. Spong. Remarks on robot dynamics: canonical transformations and Riemannian geometry , 1992, Proceedings 1992 IEEE International Conference on Robotics and Automation.

[10] Guillermo Rodríguez-Ortiz,et al. Spatial operator factorization and inversion of the manipulator mass matrix , 1992, IEEE Trans. Robotics Autom..

[11] Frank Chongwoo Park,et al. A geometrical formulation of the dynamical equations describing kinematic chains , 1993, [1993] Proceedings IEEE International Conference on Robotics and Automation.

[12] Richard M. Murray,et al. A Mathematical Introduction to Robotic Manipulation , 1994 .