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Output-Sensitive Computation of Force-Closure Grasps of a Semi-Algebraic Object

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3 Author(s)
Jae-Sook Cheong ; Creative & Challenging Res. Div., Electron. & Telecommun. Res. Inst., Daejeon, South Korea ; Kruger, H. ; van der Stappen, A.F.

We propose a technique which significantly simplifies the computation of frictionless force-closure grasps of a curved planar part P. We use a colored projection scheme from the three-dimensional wrench space to two-dimensional screens, which allows us to reduce the problem of identifying combinations of arcs and concave vertices of P that admit frictionless force-closure grasps, to colored intersection searching problems in the screens. We show how to combine this technique with existing intersection searching algorithms to obtain efficient, output-sensitive algorithms to compute all force-closure grasps of P, where at most four hard, frictionless point contacts exert exactly four wrenches on P. If the boundary of P consists of n algebraic arcs of constant complexity and m concave vertices, we show how to compute all force-closure grasps with: (1) four contacts along four arcs in O(n8/3log1/3n+K) time; (2) four contacts along three arcs in O(n5/2+ε + K) time; (3) one contact at a concave vertex and two contacts along two arcs in O(n2m1/2+ε + K) time; (4) one contact at a concave vertex and two contacts along a single arc in O(nm) or O(n3/2+ε + K) time (depending on the size of m); where ε is an arbitrarily small positive constant and K is the output size-that is, the number of combinations of arcs and vertices of each type, that actually admit frictionless force-closure grasps.

Published in:

Automation Science and Engineering, IEEE Transactions on  (Volume:8 ,  Issue: 3 )

Date of Publication:

July 2011

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