Virtual Flux Sensorless Control for Shunt Active Power Filters With Quasi-Resonant Compensators

This paper presents a sensorless control strategy for pulsewidth modulated active filters. The complete solution uses only two current sensors, which are located in the grid interface. The compensation is performed by the imposition of sinusoidal current references in the grid, and does not require...

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Veröffentlicht in:	IEEE transactions on power electronics 2016-07, Vol.31 (7), p.4818-4830
Hauptverfasser:	Ketzer, Marcos B., Jacobina, Cursino B.
Format:	Artikel
Sprache:	eng
Schlagworte:	Active control Active Power Filters Algorithms Compensators Controllers Data buses Distortion Electric currents Electric potential Estimating techniques Flux Harmonic analysis Mathematical model Phase locked loops Resonant Compensator Resonant frequency Sensorless Control Sensors Synchronism Synchronization Virtual Flux Voltage
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creator	Ketzer, Marcos B. Jacobina, Cursino B.
description	This paper presents a sensorless control strategy for pulsewidth modulated active filters. The complete solution uses only two current sensors, which are located in the grid interface. The compensation is performed by the imposition of sinusoidal current references in the grid, and does not require algorithms for disturbance estimation. The virtual flux concept for grid synchronization and multiple quasi-resonant compensators in the current scheme are employed for selective harmonic mitigation. A discretization analysis is presented in order to obtain a precise digital realization of the current controllers. It is proposed as a regulator for the direct-current bus voltage in the active filter, which employs only information of the modulated voltage and is compatible with the previous sensorless synchronization solution. Experimental results from a 1-kVA prototype converter are presented, covering the solution with and without the voltage sensor in the direct current bus. Analyses of stationary and transient responses are performed by using a six-pulse diode rectifier as nonlinear load.
doi_str_mv	10.1109/TPEL.2015.2487298
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The complete solution uses only two current sensors, which are located in the grid interface. The compensation is performed by the imposition of sinusoidal current references in the grid, and does not require algorithms for disturbance estimation. The virtual flux concept for grid synchronization and multiple quasi-resonant compensators in the current scheme are employed for selective harmonic mitigation. A discretization analysis is presented in order to obtain a precise digital realization of the current controllers. It is proposed as a regulator for the direct-current bus voltage in the active filter, which employs only information of the modulated voltage and is compatible with the previous sensorless synchronization solution. Experimental results from a 1-kVA prototype converter are presented, covering the solution with and without the voltage sensor in the direct current bus. 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subjects	Active control Active Power Filters Algorithms Compensators Controllers Data buses Distortion Electric currents Electric potential Estimating techniques Flux Harmonic analysis Mathematical model Phase locked loops Resonant Compensator Resonant frequency Sensorless Control Sensors Synchronism Synchronization Virtual Flux Voltage
title	Virtual Flux Sensorless Control for Shunt Active Power Filters With Quasi-Resonant Compensators
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