Single-Stage LED Driver Achieves Electrolytic Capacitor-Less and Flicker-Free Operation with Unidirectional Current Compensator

Peng Fang; Samuel Webb; Yan Fei Liu; Paresh C. Sen

doi:10.1109/TPEL.2018.2874999

Single-Stage LED Driver Achieves Electrolytic Capacitor-Less and Flicker-Free Operation with Unidirectional Current Compensator

Peng Fang, Samuel Webb, Yan Fei Liu, Paresh C. Sen

Research output: Contribution to journal › Article › peer-review

42 Scopus citations

Abstract

AC-connected light emitting diode (LED) drivers experience imbalanced energy between input and output in a half-line cycle. To achieve the flicker-free operation, the imbalanced energy needs to be buffered, often by energy-dense electrolytic capacitors. However, electrolytic capacitors are also well-known for their short lifespan. These capacitors are the limiting factor of an LED drivers' lifespan. High voltage film capacitors and a buck converter have been used in the proposed LED driver to buffer the imbalanced energy. When P _in > P _LED , the extra energy is transferred from the ac input directly to the high voltage film capacitors. When P _in < P _LED , the energy is transferred from the high voltage film capacitors to the output by the buck converter. The imbalanced energy goes through two power conversion steps in the proposed LED driver, which is one time less than other comparable electrolytic capacitor-less designs, enabling a higher efficiency to be achieved. A 28 W flyback topology based experimental prototype had been built and tested to verify the proposed design.

Original language	English (US)
Article number	8486664
Pages (from-to)	6760-6776
Number of pages	17
Journal	IEEE Transactions on Power Electronics
Volume	34
Issue number	7
DOIs	https://doi.org/10.1109/TPEL.2018.2874999
State	Published - Jul 2019
Externally published	Yes

Bibliographical note

Funding Information:
Manuscript received February 10, 2018; revised June 5, 2018 and August 17, 2018; accepted September 20, 2018. Date of publication October 8, 2018; date of current version May 2, 2019. This work was supported by the Natural Sciences and Engineering Research Council of Canada. Recommended for publication by Associate Editor J. Lam. (Corresponding author: Yan-Fei Liu.) P. Fang was with Queen’s University, Kingston, ON K7M 3N6, Canada. He is now with the University of Minnesota, Duluth, MN 55813 USA (e-mail:, fangp@d.umn.edu).

Publisher Copyright:
© 1986-2012 IEEE.

Keywords

AC-connected light emitting diode (LED) driver
electrolytic capacitor-less
energy buffering
flicker-free operation
high power factor

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title = "Single-Stage LED Driver Achieves Electrolytic Capacitor-Less and Flicker-Free Operation with Unidirectional Current Compensator",

abstract = " AC-connected light emitting diode (LED) drivers experience imbalanced energy between input and output in a half-line cycle. To achieve the flicker-free operation, the imbalanced energy needs to be buffered, often by energy-dense electrolytic capacitors. However, electrolytic capacitors are also well-known for their short lifespan. These capacitors are the limiting factor of an LED drivers' lifespan. High voltage film capacitors and a buck converter have been used in the proposed LED driver to buffer the imbalanced energy. When P in > P LED , the extra energy is transferred from the ac input directly to the high voltage film capacitors. When P in < P LED , the energy is transferred from the high voltage film capacitors to the output by the buck converter. The imbalanced energy goes through two power conversion steps in the proposed LED driver, which is one time less than other comparable electrolytic capacitor-less designs, enabling a higher efficiency to be achieved. A 28 W flyback topology based experimental prototype had been built and tested to verify the proposed design. ",

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Single-Stage LED Driver Achieves Electrolytic Capacitor-Less and Flicker-Free Operation with Unidirectional Current Compensator

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