Physically Plausible Wrench Decomposition for Multieffector Object Manipulation

Philine Donner, Satoshi Endo, Martin Buss

Research output: Contribution to journalArticlepeer-review

8 Scopus citations

Abstract

When manipulating an object with multiple effectors such as in multidigit grasping or multiagent collaboration, forces and torques (i.e., wrench) applied to the object at different contact points generally do not fully contribute to the resultant object wrench, but partly compensate each other. The current literature, however, lacks a physically plausible decomposition of the applied wrench into its manipulation and internal components. We formulate the wrench decomposition as a convex optimization problem, minimizing the Euclidean norms of manipulation forces and torques. Physical plausibility in the optimization solution is ensured by constraining the internal and manipulation wrench by the applied wrench. We analyze specific cases of three-fingered grasping and 2-D beam manipulation, and show the applicability of our method to general object manipulation with multiple effectors. The wrench decomposition method is then extended to quantification of measures that are important in evaluating physical human-human and human-robot interaction tasks. We validate our approach via comparison to the state of the art in simulation and via application to a human-human object transport study.

Original languageEnglish
Article number8375105
Pages (from-to)1053-1067
Number of pages15
JournalIEEE Transactions on Robotics
Volume34
Issue number4
DOIs
StatePublished - Aug 2018

Keywords

  • Cooperative manipulators
  • force decomposition
  • grasping
  • haptics and haptic interfaces
  • internal force
  • physical human-robot interaction

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