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Abstract

Criteria for determining an optimum locality of a manipulator arm are developed. In many cases, in a manufacturing environment, the tools, fixtures and targets that a manipulator has to deal with cannot be relocated. Thus, the choice of the manipulator locality is important. The method presented in this paper uses the notion of a service sphere to determine required orientability at an operating point. The boundary surfaces to the wrist-accessible output set is determined and positioned such that the service sphere is inside the wrist-accessible output set.

To determine boundary surfaces of the wrist-accessible output set, manipulator singularities (internal boundary, and higher order) are computed and substituted into the constraint equation to parameterize singular surfaces. Part of these surfaces may lie internal to the boundary while other parts are a subset of the boundary. Singular surfaces are then intersected to determine second-order singularities. Second-order singularities partition surfaces into subsurfaces. Those subsurfaces on the boundary are determined by perturbing a point on the surface and concluding whether the perturbed point satisfies the constraint equations. The boundary to the wrist-accessible output set is then located with respect to the service sphere. The locality of the manipulator is determined for maximum orientability.

Keywords

robotics kinematics optimal locality

References

Zeghloul

Pamanes-Garcia

J. A.

Multi-criteria optimal placement of robots in constrained environments. Robotica, 1993, 11, 105–110.

Nelson

Pederson

Donath

Locating assembly tasks in a manipulator's workspace. IEEE Proceedings of International Conference on Robotics and automation, 1987, pp. 1367–1372.

Pamanes-Garcia

J. A.

A criterion for optimal placement of robotic manipulators. IFAC Proceedings of Sixth Symposium on Information control problems in manufacturing technology, 1989, pp. 183–187.

Yoshikawa

Manipulability of robotic mechanisms. Int. J. Robotic Res..

Vinagradov

Details of kinematics of manipulators with the method of volumes (in Russian). Mexanika Mashin, 1971, 27–28, 5–16.

Roth

Performance evaluation of manipulators from a kinematic viewpoint. NBS Special Publications 459, 1975, pp. 39–61.

Kumar

Waldron

K. J.

The dextrous workspace. ASME paper 80-DET-108, 1980.

Tsai

Y. C.

Soni

A. H.

Accessible region and synthesis of robot arms. Trans. ASME, J. Mech. Des., 1981, 103, 803–811.

Gupta

K. C.

Roth

Design consideration for manipulator workspace. Trans. ASME, J. Meek Des. and Transm., 1982, 104(4), 704–712.

10.

Haug

E. J.

Adkins

F. A.

Qiu

C. C.

Yen

Analysis of barriers to control of manipulators within accessible output sets. Proceedings of Twentieth Conference on Design automation, Minneapolis, Minnesota, 1994.

11.

Haug

E. J.

Numerical algorithms for mapping boundaries of manipulator workspaces. Proceedings of Twenty-third ASME Mechanisms Conference, Minneapolis, Minnesota, 1994.

12.

Wang

J. Y.

J. K.

Dexterous workspaces of manipulators, Part 2: Computational methods. Mechanics of Structs and Machs, 1993, 21(4), 471–506.

13.

Qiu

C. C.

Luh

C. M.

Haug

E. J.

Dexterous workspaces of manipulators, Part III: Calculation of continuation curves at bifurcation points. Mechanics of Structs and Machs, 1995, 23(1), 115–130.

14.

Kumar

Waldron

K. J.

The workspace of a mechanical manipulator. Trans. ASME, J. Mech. Des., 1981, 103, 665–672.

15.

Lai

Z. C.

On the dexterity of robotic manipulators. PhD dissertation, University of California, Los Angeles, California, 1986.

16.

Lai

Z. C.

The dexterous workspace of simple manipulators. IEEE J. Robotics and Automn, 1988, 4(1).

17.

Abdel-Malek

Paul

The dexterous solid angle for manipulators with a spherical wrist. Proceedings of Twenty-third ASME Mechanisms Conference, Minneapolis, Minnesota, 1994.

18.

Abdel-Malek

Dexterity of manipulator arms at an operating point. ASME Des. Automn, 1995, 82(1), 781–788.

19.

Yang

D. C. H.

Lee

T. W.

On the workspace of mechanical manipulators. J. Mechanisms, Transm. and Automn Des., 1983, 105, 62–69.

20.

Gosselin

Angeles

Singularity analysis of closed loop kinematic chains. IEEE Trans. on Robotics and Automn, 1990, 6(3), 281–290.

21.

Emiris

D. M.

Workspace analysis of realistic elbow and dual-elbow robot. Mechanisms and Mach. Theory, 1993, 28(3), 375–396.

22.

Agrawal

S. K.

Workspace boundaries of in-parallel manipulator systems. Int. J. Robotics and Automn, 1990, 7(2), 94–99.

23.

Denavit

Hartenberg

R. S.

A kinematic notation for lower-pair mechanisms based on matrices. Trans. ASME, J. Appl. Mechanics, 1955, 22, 215–221.

24.

McKerrow

P. J.

Introduction to Robotics, 1991 (Addison Wesley, Reading, Massachusetts).

25.

Haug

E. J.

Wang

J. Y.

J. K.

Dextrous workspaces of manipulators. I. Analytical criteria. Mech. Structs and Machs (Ed. Haug

E. J.

), 1992, 20(3), 321–361.

26.

Qiulin

Davies

B. J.

Surface engineering geometry for computer-aided design and manufacturing, 1987 (Ellis Horwood Publishers, Chichester).

27.

Dupont

Differential geometry, 1993 (Aarhus Publishers, Denmark).

28.

Pieper

D. L.

The kinematics of manipulators under computer control. Report AIM 72, Stanford Artificial Intelligence Laboratory, Stanford University, 1968.

29.

Abdel-Malek

Off-line programming using commercial CAD systems, and design criteria for inherently high accuracy robots. PhD dissertation, University of Pennsylvania, Philadelphia, Pennsylvania, 1993.

Criterion for the Locality of a Manipulator Arm with Respect to an Operating Point

Abstract

Keywords

References