Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit

Today's technology in microprocessors has significantly improved as operation above Mhz range for microcontroller and digital signal processing (DSP) are easy to obtain and inexpensive to own. Since reactive components such as transformers, capacitors, and inductors are frequency dependent devi...

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Main Authors: Jabbar A.F., Mansor M., Rahim N.A.
Other Authors: 57190137793
Format: Conference paper
Published: IEEE Computer Society 2023
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Institution: Universiti Tenaga Nasional
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spelling my.uniten.dspace-294102023-12-28T12:12:57Z Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit Jabbar A.F. Mansor M. Rahim N.A. 57190137793 6701749037 35580738100 active auxiliary Full bridge variable load. (key words) zero-voltage-switching DC-DC converters Electromagnetic pulse Power supply circuits Signal processing active auxiliary Digital signal processing (DSP) Frequency dependent Full bridge Full bridge converters Key words Reactive components Soft-switching technique Zero voltage switching Today's technology in microprocessors has significantly improved as operation above Mhz range for microcontroller and digital signal processing (DSP) are easy to obtain and inexpensive to own. Since reactive components such as transformers, capacitors, and inductors are frequency dependent devices, using higher frequency will significantly reduce the component size. This leads to many developments of smaller converters with higher power density at cheaper cost. However, these advantages are limited by the present of hard-switching loss. Hard-switching loss is undesirable because it leads to higher power loss, excessive heat, and electromagnetic interference (EMI). To overcome these problems, researchers have developed soft-switching techniques which are capable of eliminating hard-switching loss. This paper presents a study of active auxiliary circuit with zero-voltage-switching (ZVS) in a 500W DC-DC full bridge converter. Simulation base experiment will be conducted at variant input source and different load conditions. � 2013 IEEE. Final 2023-12-28T04:12:57Z 2023-12-28T04:12:57Z 2013 Conference paper 10.1109/CEAT.2013.6775612 2-s2.0-84898814278 https://www.scopus.com/inward/record.uri?eid=2-s2.0-84898814278&doi=10.1109%2fCEAT.2013.6775612&partnerID=40&md5=bb6e93429774a06b00b74b4175f083e1 https://irepository.uniten.edu.my/handle/123456789/29410 6775612 124 127 IEEE Computer Society Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
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continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic active auxiliary
Full bridge
variable load. (key words)
zero-voltage-switching
DC-DC converters
Electromagnetic pulse
Power supply circuits
Signal processing
active auxiliary
Digital signal processing (DSP)
Frequency dependent
Full bridge
Full bridge converters
Key words
Reactive components
Soft-switching technique
Zero voltage switching
spellingShingle active auxiliary
Full bridge
variable load. (key words)
zero-voltage-switching
DC-DC converters
Electromagnetic pulse
Power supply circuits
Signal processing
active auxiliary
Digital signal processing (DSP)
Frequency dependent
Full bridge
Full bridge converters
Key words
Reactive components
Soft-switching technique
Zero voltage switching
Jabbar A.F.
Mansor M.
Rahim N.A.
Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit
description Today's technology in microprocessors has significantly improved as operation above Mhz range for microcontroller and digital signal processing (DSP) are easy to obtain and inexpensive to own. Since reactive components such as transformers, capacitors, and inductors are frequency dependent devices, using higher frequency will significantly reduce the component size. This leads to many developments of smaller converters with higher power density at cheaper cost. However, these advantages are limited by the present of hard-switching loss. Hard-switching loss is undesirable because it leads to higher power loss, excessive heat, and electromagnetic interference (EMI). To overcome these problems, researchers have developed soft-switching techniques which are capable of eliminating hard-switching loss. This paper presents a study of active auxiliary circuit with zero-voltage-switching (ZVS) in a 500W DC-DC full bridge converter. Simulation base experiment will be conducted at variant input source and different load conditions. � 2013 IEEE.
author2 57190137793
author_facet 57190137793
Jabbar A.F.
Mansor M.
Rahim N.A.
format Conference paper
author Jabbar A.F.
Mansor M.
Rahim N.A.
author_sort Jabbar A.F.
title Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit
title_short Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit
title_full Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit
title_fullStr Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit
title_full_unstemmed Pulse-width control scheme for fixed-frequency ZVS DC-DC converter with active auxiliary circuit
title_sort pulse-width control scheme for fixed-frequency zvs dc-dc converter with active auxiliary circuit
publisher IEEE Computer Society
publishDate 2023
_version_ 1806426181482840064