Haptic Display of Constrained Dynamic Systems via Admittance Displays

In the Cobotic Hand Controller, we have introduced an admittance display that can render very high impedances (up to its own structural stiffness). This is due to its use of infinitely variable transmissions. While admittance displays typically excel at rendering high impedances, the incorporation o...

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Veröffentlicht in:	IEEE transactions on robotics 2007-02, Vol.23 (1), p.101-111
Hauptverfasser:	Faulring, E.L., Lynch, K.M., Colgate, J.E., Peshkin, M.A.
Format:	Artikel
Sprache:	eng
Schlagworte:	Admittance Admittance display Algorithms Applied sciences cobots Collaboration Computer displays Computer science control theory systems constrained dynamic systems Control algorithms Control systems Control theory. Systems Controllers Couplings Dynamic range Dynamical systems Dynamics Electrical impedance Exact sciences and technology Haptic interfaces haptics Motion control nonholonomic Rendering Rigid-body dynamics Robot sensing systems Robotics Robots Surface impedance Tangents Torque control
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container_title	IEEE transactions on robotics
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creator	Faulring, E.L. Lynch, K.M. Colgate, J.E. Peshkin, M.A.
description	In the Cobotic Hand Controller, we have introduced an admittance display that can render very high impedances (up to its own structural stiffness). This is due to its use of infinitely variable transmissions. While admittance displays typically excel at rendering high impedances, the incorporation of infinitely variable transmissions in the Cobotic Hand Controller allows the stable display of a wide dynamic range, including low impedances. The existence of a display that excels at rendering high-impedance constraints, but has high-fidelity control of low impedances tangent to those constraints, has led us to describe an admittance control architecture not often examined in the haptics community. In this paper, we develop a comprehensive approach that enables rendering of rigid motion constraints while simultaneously preserving the physical integrity of the intended inertial dynamics tangent to those constraints. This is in contrast to conventional impedance-control algorithms that focus primarily on rendering reaction forces along contact normals with constraints. We present this algorithm here, which is general to all admittance displays, and report on its implementation with the Cobotic Hand Controller. We offer examples of rigid bodies and linkages subject to holonomic and/or nonholonomic constraints
doi_str_mv	10.1109/TRO.2006.886837
format	Article
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subjects	Admittance Admittance display Algorithms Applied sciences cobots Collaboration Computer displays Computer science control theory systems constrained dynamic systems Control algorithms Control systems Control theory. Systems Controllers Couplings Dynamic range Dynamical systems Dynamics Electrical impedance Exact sciences and technology Haptic interfaces haptics Motion control nonholonomic Rendering Rigid-body dynamics Robot sensing systems Robotics Robots Surface impedance Tangents Torque control
title	Haptic Display of Constrained Dynamic Systems via Admittance Displays
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