Geometric reasoning for fine motion planning

Author

Cervera, Enrique ; Del Pobil, Angel P.

Author_Institution

Dept. of Comput. Sci., Jaume I Univ., Castello, Spain

fYear

1995

fDate

10-11 Aug 1995

Firstpage

154

Lastpage

159

Abstract

In an assembly plan, a sequence of subtasks has to be determined, which require a lower level plan involving fine motion. The need for combining task-level knowledge and sensor-based information is unavoidable, since the use of force and torque sensor signals allows us to identify the contact state in the real world and verify whether the predictions of the task planner are correct or not. This paper builds upon previous results regarding error detection for plan monitoring. We extend them by deriving a geometric-reasoning world model for the peg-in-hole insertion task, and integrating it with a perception-based model obtained using neural networks. A novel learning scheme to identify contact states is also presented. As a result, an integrated approach to fine motion planning for assembly is developed, including perception, robotics and artificial intelligence techniques

Keywords

assembling; industrial robots; neural nets; path planning; production control; robots; spatial reasoning; assembly planning; error detection; fine motion planning; geometric-reasoning; neural networks; peg-in-hole insertion; perception-based model; robot assembly; world model; Artificial neural networks; Force sensors; Intelligent robots; Learning; Monitoring; Motion planning; Robotic assembly; Signal processing; Solid modeling; Torque;

fLanguage

English

Publisher

ieee

Conference_Titel

Assembly and Task Planning, 1995. Proceedings., IEEE International Symposium on

Conference_Location

Pittsburgh, PA

Print_ISBN

0-8186-6995-0

Type

conf

DOI

10.1109/ISATP.1995.518765

Filename

518765