Singular Configurations of Parallel Manipulators and Grassmann Geometry

Abstract

Parallel manipulators have a specific mechanical architecture where all the links are connected both at the base and at the gripper of the robot. By changing the lengths of these links we are able to control the position¹ of the gripper. In general, for a given set of links lengths there is only one position for the gripper. However, it may be suspected that in some cases more than one solution may be found for the position of the gripper: the robot is in a singular configuration. To determine these singular configurations the classical method is to find the roots of the determinant of the jacobian matrix. In our case the jacobian matrix is complex, and it seems not to be possible to find these roots. We propose here a new method based on Grassmann line geometry. The set of lines, P³, constitutes a linear variety of rank 6. We show that a singular configuration is obtained when the variety spanned by the lines associated to the robot links has a rank less than 6. An important feature of the varieties of this geometry is that they can be described by simple geometric rules. Thus to find the singular configurations of parallel manipulators we have to find the configuration in which the robot matches these rules. Such an analysis is performed on a special parallel manip ulator. We show that we find all the well-known singular configurations, and also some new ones.

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References

Baret, M. 1978 (Bruxelle, April). Six degrees of freedom large motion system for flight simulators. Proc. AGARD Conf. 249, Piloted Aircraft Environment Simulation Techniques, pp 22.1-22.8.

Behnke, H. , et al. 1986. Fundamentals of Mathematics: Geometry, vol. II, ed. 3. Cambridge, Mass.: MIT Press.

Bricard, R. 1987. Mémoire sur la théorie de l'octaèdre articulé. Journal de Mathématiques Pures et Appliquées. Liouville cinquième série, tome 3.

Cauchy, A. 1813. Deuxième mémoire sur les polygones et les polyèdres. Journal de l'Ecole Polytechnique, XVIeme cahier.

Crapo, H. 1973 (Rome, September). A combinatorial perspective on algebraic geometry. Colloquio Int. Sulle Teorie Combinatorie.

Dandurand, A. 1984. The rigidity of compound spatial grid. Structural Topology 10:41-55.

Fichter, E.F. 1986. A Stewart platform based manipulator: General theory and practical construction. Int. J. of Robotics Research 5(2):157-181.

Hilbert, D. , and Cohn-Vossen, S. 1952. Geometry and the Imagination. New York : Chelsea Publ. Company.

Hunt, K.H. 1978. Kinematics geometry of mechanisms. Oxford: Clarendon Press.

10.

Hunt, K.H. 1983. Structural kinematics in parallel actuated robot arms. Trans. of the ASME, J. of Mechanisms, Transmissions, and Automation in Design 105:705-712.

11.

Inoue, H. , Tsusaka, Y. , and Fukuizumi, T. 1985 (Gouvieux, France, October). Parallel manipulator. Proc 3rd ISRR.

12.

MacCallion, H. , and Pham, D.T. 1979 (Montreal, July). The analysis of a six degree of freedom work station for mechanized assembly. Proc. 5th World Congress on Theory of Machines and Mechanisms .

13.

Merlet, J-P. 1986. Contribution à la formalisation de la commanded par retour d'efforts. Application à la commande de robots parallèles. Ph.D. thesis, Paris VI University, 18 June 1986.

14.

Merlet, J-P. 1987. Parallel manipulator, part 1: Theory, design, kinematics and control. INRIA Research Report No. 646, March.

15.

Merlet, J-P. 1988. Parallel manipulator, part 2: Singular configurations and Grassman geometry. INRIA research Report No. 791, February.

16.

Minsky, M. 1972. Manipulator design vignettes. MIT AIL Memo 267, Cambridge, Mass., October.

17.

Mohamed, M.G. , and Duffy, J. 1985. A direct determination of the instantaneous kinematics of fully parallel robot manipulators. Trans. of the ASME, J. of Mechanisms, Transmissions, and Automation in Design 107:226-229.

18.

Reboulet, C. , and Robert, A. 1985 (Gouvieux, France, October). Hybrid control of a manipulator with an active compliant wrist. Proc 3rd ISRR, pp. 76 -80.

19.

Stewart, D. 1965. A platform with 6 degrees of freedom. Proc. of the Institution of Mechanical Engineers 1965-66 180 (part 1, number 15):371-386.

20.

Tanaka, M. 1988 (Atlanta, April). Motion and dynamics of flexible arm of a mast-type statically determinate truss. Proc. Computational Mechanics '88, Theory and Applications , pp. 42.iii.1-42.iii.4.

21.

Tyrrell, J.A. , and Semple, J.G. 1971. Generalized Clifford Parallelism. Cambridge: Cambridge Univ. Press.

22.

Veblen, O. , and Young, J.W. 1910. Projective Geometry. Boston: The Athenaeum Press.

23.

Watson, P. 1984. Flight simulators—the grand illusion. Electron. Aust. 46(4):12-17.

24.

Yang, D.C.H. , and Lee, T.W. 1984. Feasibility study of a platform type of robotic manipulator from a kinematic viewpoint. Trans. of the ASME, J. of Mechanisms, Transmissions, and Automation in Design 106(June 1984):191-198.

25.

Zamanov, V.B. , and Sotirov, Z.M. 1984 (Tokyo, July). Structures and kinematics of parallel topology manipulating systems. Proc. Int. Symp. on Design and Synthesis, pp. 453-458.