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Stability analysis and voltage control method based on virtual resistor and proportional voltage feedback loop for cascaded DC-DC converters

This paper proposes a voltage control method based on virtual resistor and proportional voltage feedback loop for cascaded DC-DC converters. The closed-loop DC-DC converter would act as negative impedance load for the front-end converter and might lead to system instability. Based on the analysis of...

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Main Authors:	Wen Cai, Fahimi, Babak, Cosoroaba, Eva, Fan Yi
Format:	Conference Proceeding
Language:	English
Subjects:	Capacitors DC-DC power converters Impedance Inductors Resistors Stability analysis Voltage control
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creator	Wen Cai Fahimi, Babak Cosoroaba, Eva Fan Yi
description	This paper proposes a voltage control method based on virtual resistor and proportional voltage feedback loop for cascaded DC-DC converters. The closed-loop DC-DC converter would act as negative impedance load for the front-end converter and might lead to system instability. Based on the analysis of DC-DC converter with distributed parameters, a modified voltage control strategy based on virtual resistor is proposed which is to only add a proportional feedback of inductor current in the control block. Thus, no extra power loss would be generated. However, under some conditions, this method cannot achieve system stabilization. Then, an additional output voltage feedback loop is introduced which can not only stabilize the system under different cases but also improve system performance. Experimental results verified theoretical analysis and feasibility of the proposed control methods.
doi_str_mv	10.1109/ECCE.2014.6953810
format	conference_proceeding
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The closed-loop DC-DC converter would act as negative impedance load for the front-end converter and might lead to system instability. Based on the analysis of DC-DC converter with distributed parameters, a modified voltage control strategy based on virtual resistor is proposed which is to only add a proportional feedback of inductor current in the control block. Thus, no extra power loss would be generated. However, under some conditions, this method cannot achieve system stabilization. Then, an additional output voltage feedback loop is introduced which can not only stabilize the system under different cases but also improve system performance. 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The closed-loop DC-DC converter would act as negative impedance load for the front-end converter and might lead to system instability. Based on the analysis of DC-DC converter with distributed parameters, a modified voltage control strategy based on virtual resistor is proposed which is to only add a proportional feedback of inductor current in the control block. Thus, no extra power loss would be generated. However, under some conditions, this method cannot achieve system stabilization. Then, an additional output voltage feedback loop is introduced which can not only stabilize the system under different cases but also improve system performance. 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The closed-loop DC-DC converter would act as negative impedance load for the front-end converter and might lead to system instability. Based on the analysis of DC-DC converter with distributed parameters, a modified voltage control strategy based on virtual resistor is proposed which is to only add a proportional feedback of inductor current in the control block. Thus, no extra power loss would be generated. However, under some conditions, this method cannot achieve system stabilization. Then, an additional output voltage feedback loop is introduced which can not only stabilize the system under different cases but also improve system performance. Experimental results verified theoretical analysis and feasibility of the proposed control methods.</abstract><pub>IEEE</pub><doi>10.1109/ECCE.2014.6953810</doi><tpages>7</tpages></addata></record>
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identifier	ISSN: 2329-3721
ispartof	2014 IEEE Energy Conversion Congress and Exposition (ECCE), 2014, p.3016-3022
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source	IEEE Xplore All Conference Series
subjects	Capacitors DC-DC power converters Impedance Inductors Resistors Stability analysis Voltage control
title	Stability analysis and voltage control method based on virtual resistor and proportional voltage feedback loop for cascaded DC-DC converters
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