Robot Precision Assembly Combining With Passive and Active Compliant Motions

Precision assembly is one of the primary goals of robots in manufacturing. Assembly strategies combining active and passive compliant control are presented herein. In this article, we construct a high-dimensional configuration space of robot assembly and then divide the configuration space to its su...

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Veröffentlicht in:	IEEE transactions on industrial electronics (1982) 2022-08, Vol.69 (8), p.8157-8167
Hauptverfasser:	Su, Jianhua, Liu, Chuankai, Li, Rui
Format:	Artikel
Sprache:	eng
Schlagworte:	Active control Assembly compliant motion Configurations constraint region Control systems design Force force controller Force feedback Manipulators Robot kinematics Robot sensing systems Robots Subspaces Trajectory Uncertainty
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container_title	IEEE transactions on industrial electronics (1982)
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creator	Su, Jianhua Liu, Chuankai Li, Rui
description	Precision assembly is one of the primary goals of robots in manufacturing. Assembly strategies combining active and passive compliant control are presented herein. In this article, we construct a high-dimensional configuration space of robot assembly and then divide the configuration space to its subspaces. We further map the active compliant motion and the passive compliant motion of the manipulator into different subspaces. In one subspace, we construct the constraint function and design the passive compliant motion of the manipulator in the constraint region, where the uncertainties of the system should be eliminated by the environment constraints. In another subspace, we design a force controller based on the low-resolution force sensory information to control the position of the robot. The proposed method avoids the design of precision mechanism systems and the usage of high-quality sensors. Several experiments pertaining to peg-in-hole insertions are conducted to demonstrate the efficiency of the proposed method.
doi_str_mv	10.1109/TIE.2021.3108710
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Assembly strategies combining active and passive compliant control are presented herein. In this article, we construct a high-dimensional configuration space of robot assembly and then divide the configuration space to its subspaces. We further map the active compliant motion and the passive compliant motion of the manipulator into different subspaces. In one subspace, we construct the constraint function and design the passive compliant motion of the manipulator in the constraint region, where the uncertainties of the system should be eliminated by the environment constraints. In another subspace, we design a force controller based on the low-resolution force sensory information to control the position of the robot. The proposed method avoids the design of precision mechanism systems and the usage of high-quality sensors. 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subjects	Active control Assembly compliant motion Configurations constraint region Control systems design Force force controller Force feedback Manipulators Robot kinematics Robot sensing systems Robots Subspaces Trajectory Uncertainty
title	Robot Precision Assembly Combining With Passive and Active Compliant Motions
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