Design of an All-SiC Radio-frequency Controlled Parallel DC-DC Converter Unit

Design of an All-SiC Radio-frequency Controlled Parallel DC-DC Converter Unit

We demonstrate the feasibility of radio-frequency (RF) communication based wireless load-sharing control of a two-module parallel dc-dc (Weinberg) converter unit (DDCU) operating at a high switching frequency (0.25 MHz). The impact of time delay (due to varying network sampling rates and channel dis...

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Hauptverfasser: Mazumder, S.K., Acharya, K., Chuen Ming Tan
Format: Tagungsbericht
Sprache:eng
Schlagworte:
Communication system control
control
dc-dc converter unit (DDCU)
DC-DC power converters
Delay effects
international space station (ISS)
load sharing
network
PMAD
Radio control
Radio frequency
radio frequency (RF)
Sampling methods
SiC
Silicon carbide
stability
Switching converters
Switching frequency
time-delay
Weinberg converter
wireless
Wireless communication
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Beschreibung
Zusammenfassung:We demonstrate the feasibility of radio-frequency (RF) communication based wireless load-sharing control of a two-module parallel dc-dc (Weinberg) converter unit (DDCU) operating at a high switching frequency (0.25 MHz). The impact of time delay (due to varying network sampling rates and channel disruptions) on the stability and performance of the DDCU are analyzed leading to robust control design, which compensates for the time-varying delays. Additionally, using experimental results, we demonstrate that an all-SiC (SiC VJFET and SiC Schottky diode) based hard-switched power-stage design achieves high efficiency in spite of operating at high frequency and high temperature.
ISSN:0275-9306
2377-6617
DOI:10.1109/PESC.2007.4342468