A Polynomial Model to Calculate Steady-State Set Point in the PRC-LCC Topology With a Capacitor as Output Filter

A Polynomial Model to Calculate Steady-State Set Point in the PRC-LCC Topology With a Capacitor as Output Filter

The behavior of the series-parallel resonant converter with a capacitor as output filter is analyzed when operating under optimum switching conditions. A polynomial is deduced to quickly compute what switching frequency and duty cycle are necessary at the control to obtain the desired output voltage...

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Veröffentlicht in:IEEE transactions on industry applications 2015-05, Vol.51 (3), p.2520-2527
Hauptverfasser: Martin-Ramos, Juan A., Diaz, Juan, Nuno, Fernando, Villegas, Pedro Jose, Lopez-Hernandez, Agustin, Gutierrez-Delgado, J. Francisco
Format: Artikel
Sprache:eng
Schlagworte:
AC-DC-conversion
control
high voltage
Least squares approximations
Mathematical model
modeling
Polynomials
resonant conversion
Switching frequency
Topology
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Zusammenfassung:The behavior of the series-parallel resonant converter with a capacitor as output filter is analyzed when operating under optimum switching conditions. A polynomial is deduced to quickly compute what switching frequency and duty cycle are necessary at the control to obtain the desired output voltage and power in the converter. This polynomial is so simple that it is suitable for being implemented in low-cost digital processors. It could provide, for instance, a start-up strategy guiding the power supply to a known set point, or it could generate alarms if the currents or voltages measured are larger than expected. In this paper, the steps to obtain such a model are described in detail. As an example, the coefficients of the polynomials are deduced when the series and the parallel capacitor are the same. The grade of accuracy of the model has been demonstrated through experimentation on a prototype.
ISSN:0093-9994
1939-9367
DOI:10.1109/TIA.2014.2362962