Passivitätsbasierte Kraft- und Impedanzregelung für Roboter mit starren Gelenken mittels Energietanks

Sami Haddadin

doi:10.1515/auto-2016-0108

Passivitätsbasierte Kraft- und Impedanzregelung für Roboter mit starren Gelenken mittels Energietanks

Translated title of the contribution: Passivity-based unification of force and impedance control via energy tanks for rigid joint robots

Sami Haddadin

Leibniz Universität Hannover

Research output: Contribution to journal › Article › peer-review

Abstract

In this paper a novel hybrid Cartesian force/impedance controller is porposed that is equipped with energy tanks to preserve passivity. The approach overcomes the problems of (hybrid) force control, impedance control and set-point based indirect force control. It simultaneously allows accurate force tracking, full compliant impedance behavior and safe contact resemblance by introducing a controller shaping function. This robustly handles unexpected contact loss and avoids chattering behavior that other switching based approaches suffer from. Furthermore, a constructive way to initiate energy tanks via the concept of task energy is proposed, where the energy consumption of a given force control task is estimated prior to execution. To show the validity of our approach, several simulations and experiments with a 7-degree-of-freedom robot are carried out.

Translated title of the contribution	Passivity-based unification of force and impedance control via energy tanks for rigid joint robots
Original language	German
Pages (from-to)	124-133
Number of pages	10
Journal	At-Automatisierungstechnik
Volume	65
Issue number	2
DOIs	https://doi.org/10.1515/auto-2016-0108
State	Published - 28 Feb 2017
Externally published	Yes

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title = "Passivit{\"a}tsbasierte Kraft- und Impedanzregelung f{\"u}r Roboter mit starren Gelenken mittels Energietanks",

abstract = "In this paper a novel hybrid Cartesian force/impedance controller is porposed that is equipped with energy tanks to preserve passivity. The approach overcomes the problems of (hybrid) force control, impedance control and set-point based indirect force control. It simultaneously allows accurate force tracking, full compliant impedance behavior and safe contact resemblance by introducing a controller shaping function. This robustly handles unexpected contact loss and avoids chattering behavior that other switching based approaches suffer from. Furthermore, a constructive way to initiate energy tanks via the concept of task energy is proposed, where the energy consumption of a given force control task is estimated prior to execution. To show the validity of our approach, several simulations and experiments with a 7-degree-of-freedom robot are carried out.",

keywords = "Impedance control, energy tanks, force control, loss of contact stabilization",

author = "Sami Haddadin",

note = "Publisher Copyright: {\textcopyright} 2017 Walter de Gruyter Berlin/Boston.",

year = "2017",

month = feb,

day = "28",

doi = "10.1515/auto-2016-0108",

language = "Deutsch",

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N2 - In this paper a novel hybrid Cartesian force/impedance controller is porposed that is equipped with energy tanks to preserve passivity. The approach overcomes the problems of (hybrid) force control, impedance control and set-point based indirect force control. It simultaneously allows accurate force tracking, full compliant impedance behavior and safe contact resemblance by introducing a controller shaping function. This robustly handles unexpected contact loss and avoids chattering behavior that other switching based approaches suffer from. Furthermore, a constructive way to initiate energy tanks via the concept of task energy is proposed, where the energy consumption of a given force control task is estimated prior to execution. To show the validity of our approach, several simulations and experiments with a 7-degree-of-freedom robot are carried out.

AB - In this paper a novel hybrid Cartesian force/impedance controller is porposed that is equipped with energy tanks to preserve passivity. The approach overcomes the problems of (hybrid) force control, impedance control and set-point based indirect force control. It simultaneously allows accurate force tracking, full compliant impedance behavior and safe contact resemblance by introducing a controller shaping function. This robustly handles unexpected contact loss and avoids chattering behavior that other switching based approaches suffer from. Furthermore, a constructive way to initiate energy tanks via the concept of task energy is proposed, where the energy consumption of a given force control task is estimated prior to execution. To show the validity of our approach, several simulations and experiments with a 7-degree-of-freedom robot are carried out.

KW - Impedance control

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KW - force control

KW - loss of contact stabilization

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ER -

Passivitätsbasierte Kraft- und Impedanzregelung für Roboter mit starren Gelenken mittels Energietanks

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