Sage Journals: Discover world-class research

Abstract

This article presents an optimal trajectory-planning method for robot manipulators with collision detection and avoidance. The obstacles and robot segments are represented by a set of convex polyhedra. The collision detection is performed at each discretized robot configuration by an efficient procedure devel oped with the computational geometry method, which computes a distance function of the robot segments and the obstacles. By introducing this function for specifying the collision-free con straint, the path-planning problem is formulated as an optimal control problem using the augmented Lagrangian, which may be considered as a combination of the duality, penalty and con straint relaxation methods. The problem is solved by a robust UZAWA-like algorithm, where a subgradient method is applied for the primal optimization, as the distance function is not ev erywhere differentiable. An example is given for the trajectory planning of a robot arm with three revolute joints.

Get full access to this article

View all access options for this article.

References

Brooks, R.A. 1983. Planning collision-free motions for pick-and-place operations . Int. J. Robot. Res. 2(4):19-44.

Buckley, C.E. 1989. A foundation for the "flexible-trajectory" approach to numeric path planning. Int. J. Robot. Res. 8(3):44-64.

Cameron, S.A. , and Culley, R.K. 1986 (San Francisco). Determining the minimum translational distance between two convex polyhedra. IEEE Int. Conf. Robotics and Automation, pp. 591-596.

Canny, J. 1987. The Complexity of Robot Motion Planning. ACM Doctoral Dissertation Award 1987. Cambridge, MA: The MIT Press.

Cohen, G. , and Dao, Li Zhu. 1984. Decomposition— coordination methods in large scale optimization problems: the non-differential case and the use of Lagrangien augmentés. Advances in Large Scale Systems Theory and Applications, Vol. 1, Cruz, J. B. (editor). JAI Press Inc., Greenwich, Connecticut .

Durand, P. , and Viette, F. 1986 (New Mexico). A robot design for teaching and research. Recent Trends in Robotics, Int. Symp. Robot Manipulators, pp. 335-344.

Edelsbrunner, H. 1987. Algorithms in Combinatorial Geometry. New York: Springer-Verlag.

Faverjon, B. 1984 (Atlanta). Obstacles avoidance using an octree in the configuration space of a manipulator. IEEE Int. Conf. Robotics and Automation, pp. 504-510.

Faverjon, B. , and Toumassoud, P. 1987. A local based approach for path planning of manipulators with a high number of degrees of freedom. IEEE Int. Conf. Robotics and Automation, pp. 1152-1159.

10.

Gilbert, E.G. , and Johnson, D.W. 1985. Distance functions and their application to robot path planning in the presence of obstacles. IEEE J. Robotics and Automation 1(1):21-30.

11.

Hollerbach, J.M. 1984. Dynamic scaling of manipulator trajectories. Trans. ASME, J. Dyn. Sys. Meas. Cont. 106(1):102-107.

12.

Khoukhi, A. , and Hamam, Y. 1990. Optimal time-energy trajectory planning for robots with hard constraints. Control-Theory and Advanced Technology 6(3):417-439.

13.

Lozano-Pérez, T. , and Wesley, M.A. 1977. An algorithm for planning collsion-free paths among polyhedral obstacles. Communications ACM 22(10):560-570.

14.

Lozano-Pérez, T. 1981. Automatic planning of manipulator transfer movements . IEEE Trans. Sys. Man Cybernetics SMC-11(10):681-698.

15.

Lozano-Pérez, T. 1983. Spatial planning: A configuration space approach . IEEE Trans. Computers C-32(2):108-120.

16.

Lozano-Pérez, T. 1988. Motion planning for simple robot manipulators. Robotics Research, Vol. 3. Cambridge, MA: MIT Press.

17.

Melhorn, K. 1984. Data Structures and Algorithms 3: Multi-dimensional Searching and Computational Geometry. New York: Springer-Verlag.

18.

Minoux, M. 1983. Programmation Mathématique. Paris: Dunod.

19.

Preparata, F.P. , and Shamos, M.I. 1985. Computational Geometry, An Introduction. New York: Springer-Verlag.

20.

Schwartz, J.T. , and Sharir, M. 1983. On the piano movers' problem: II. General techniques for computing topological properties of real algebraic manifolds. Adv. Appl. Math. 4:298-351.

21.

Schwartz, J. , Hopcroft, J. , and Sharir, M. (eds.) 1987. Planning Geometry and Complexity of Robot Motion. Ablex Publishing Co., New Jersey.

22.

Schwartz, J. , and Yap, C.K. 1987. Advances in Robotics: Algorithmic and Geometric Aspects of Robotics. Vol. 1. LEA Publishers: Hillsdale, New Jersey.

23.

Toussaint, G. 1985. Computational Geometry. Machine Intelligence and Pattern Recognition. Vol. 2. North-Holland .

24.

Udupa, S. 1977 (Cambridge, MA). Collision detection and avoidance in computer controlled manipulators. Fifth Int. Joint Conf. AI, pp. 737-748.

25.

Wang, D. , Georges, D. , and Hamam, Y. 1990 (June). Optimal path planning of manipulators with singular configurations, work-space and collision-free constraints. In Lecture Notes in Control and Information Sciences, No. 144. Proc. 9th Int. Conf. Analysis and Optimization of Systems Bensoussan, A. , and Lions, J. L. (eds.). New York: Springer-Verlag, pp. 600-610.

26.

Wang, D. 1990. Planification optimale de trajectories de robots manipulateurs avec evitement d'obstacles. Ph.D. thesis, CNAM, Paris.

Optimal Trajectory Planning of Manipulators With Collision Detection and Avoidance

Abstract

Get full access to this article

References