Power-Based Setpoint Control: Experimental Results on a Planar Manipulator

D. A. Dirksz; J. M. A. Scherpen

doi:10.1109/TCST.2011.2163514

Power-Based Setpoint Control: Experimental Results on a Planar Manipulator

D. A. Dirksz^*, J. M. A. Scherpen

^*Corresponding author voor dit werk

Onderzoeksoutput: Article › Academic › peer review

11 Citaten (Scopus)

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In the last years the power-based modeling framework, developed in the sixties to model nonlinear electrical RLC networks, has been extended for modeling and control of a larger class of physical systems. In this brief we apply power-based integral control to a planar manipulator experimental setup. An integrator is known to compensate for steady-state errors, which usually occur in real applications. Recent developments in power-based control have shown the possibility of applying integral control to globally asymptotically stabilize a nonlinear system, without losing the original structure. In contrast, the more common PI or PID controllers do not provide such global properties. Both simulation and experimental results show an improvement in transient performance compared to PID control.

Originele taal-2	English
Pagina's (van-tot)	1384-1391
Aantal pagina's	8
Tijdschrift	IEEE Transactions on Control Systems Technology
Volume	20
Nummer van het tijdschrift	5
DOI's	https://doi.org/10.1109/TCST.2011.2163514
Status	Published - sep.-2012

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title = "Power-Based Setpoint Control: Experimental Results on a Planar Manipulator",

abstract = "In the last years the power-based modeling framework, developed in the sixties to model nonlinear electrical RLC networks, has been extended for modeling and control of a larger class of physical systems. In this brief we apply power-based integral control to a planar manipulator experimental setup. An integrator is known to compensate for steady-state errors, which usually occur in real applications. Recent developments in power-based control have shown the possibility of applying integral control to globally asymptotically stabilize a nonlinear system, without losing the original structure. In contrast, the more common PI or PID controllers do not provide such global properties. Both simulation and experimental results show an improvement in transient performance compared to PID control.",

keywords = "Brayton-Moser systems, integral control, mechanical systems, nonlinear control, Port-Hamiltonian systems, power-shaping, CONTROLLED HAMILTONIAN-SYSTEMS, NONLINEAR RLC CIRCUITS, PASSIVITY, ENERGY",

author = "Dirksz, {D. A.} and Scherpen, {J. M. A.}",

year = "2012",

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AB - In the last years the power-based modeling framework, developed in the sixties to model nonlinear electrical RLC networks, has been extended for modeling and control of a larger class of physical systems. In this brief we apply power-based integral control to a planar manipulator experimental setup. An integrator is known to compensate for steady-state errors, which usually occur in real applications. Recent developments in power-based control have shown the possibility of applying integral control to globally asymptotically stabilize a nonlinear system, without losing the original structure. In contrast, the more common PI or PID controllers do not provide such global properties. Both simulation and experimental results show an improvement in transient performance compared to PID control.

KW - Brayton-Moser systems

KW - integral control

KW - mechanical systems

KW - nonlinear control

KW - Port-Hamiltonian systems

KW - power-shaping

KW - CONTROLLED HAMILTONIAN-SYSTEMS

KW - NONLINEAR RLC CIRCUITS

KW - PASSIVITY

KW - ENERGY

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DO - 10.1109/TCST.2011.2163514

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JO - IEEE Transactions on Control Systems Technology

JF - IEEE Transactions on Control Systems Technology

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Power-Based Setpoint Control: Experimental Results on a Planar Manipulator

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