Open AccessTeleoperation with virtual force feedback
Author(s) -
Robert J. Anderson
Publication year - 1994
Publication title -
lecture notes in control and information sciences
Language(s) - English
Resource type - Book series
SCImago Journal Rank - 0.173
H-Index - 49
eISSN - 1610-7411
pISSN - 0170-8643
ISBN - 3-540-19905-5
DOI - 10.1007/bfb0027608
Subject(s) - teleoperation , control theory (sociology) , task (project management) , engineering , nonlinear system , haptic technology , telerobotics , simulation , regular polygon , virtual machine , object (grammar) , trajectory , computer science , control engineering , algorithm , computer vision , robot , artificial intelligence , mathematics , mobile robot , physics , geometry , control (management) , systems engineering , operating system , quantum mechanics , astronomy
In this paper we describe an algorithm for generating virtual forces in a bilateral teleoperator system. The virtual forces are generated from a world model and are used to provide real-time obstacle avoidance and guidance capabilities. The algorithm requires that the slave's tool and every object in the environment be decomposed into convex polyhedral primitives. Intrusion distance and extraction vectors are then derived at every time step by applying Gilbert's polyhedra distance algorithm, which has been adapted for the task. This information is then used to determine the compression and location of nonlinear virtual spring-dampers whose total force is summed and applied to the manipulator/teleoperator system. Experimental results validate the whole approach, showing that it is possible to compute the algorithm and generate realistic, useful psuedo forces for a bilateral teleoperator system using standard VME bus hardware.
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