Analysis of stepwise charging limits and its implementation for efficiency improvement in switched capacitor DC–DC converters

Francisco Veirano; Pablo Castro Lisboa; Pablo Pérez-Nicoli; Lirida Naviner; Fernando Silveira

doi:10.1007/s10470-021-01810-5

Analysis of stepwise charging limits and its implementation for efficiency improvement in switched capacitor DC–DC converters

Francisco Veirano, Pablo Castro Lisboa, Pablo Pérez-Nicoli, Lirida Naviner, Fernando Silveira

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

Abstract

In this work we analysed the stepwise charging technique to find the limits from which it is beneficial in terms of load capacitance and charge–discharge frequency. We included in the analysis practical limitations such as the consumption of auxiliary logic needed to implement the technique and the minimum size of auxiliary switches imposed by the technology. We proposed an ultra-low-power logic block to push these limits and to obtain benefits from this technique in small capacitances. Finally, we proposed to use a stepwise driver in the driving of the gate capacitance of power switches in switched-capacitor (SC) DC–DC converters. We designed and manufactured, in a 130 nm process, a SC DC–DC converter and measured a 29% energy reduction in the gate-drive losses of the converter. This accounts for an improvement of 4% (from 69 to 73%) in the overall converter efficiency.

Original language	English
Pages (from-to)	271-282
Number of pages	12
Journal	Analog Integrated Circuits and Signal Processing
Volume	109
Issue number	2
DOIs	https://doi.org/10.1007/s10470-021-01810-5
Publication status	Published - 1 Nov 2021
Externally published	Yes

Keywords

Charge recycling
Stepwise charging
Ultra-low power switched capacitor DC–DC converter

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10.1007/s10470-021-01810-5

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title = "Analysis of stepwise charging limits and its implementation for efficiency improvement in switched capacitor DC–DC converters",

abstract = "In this work we analysed the stepwise charging technique to find the limits from which it is beneficial in terms of load capacitance and charge–discharge frequency. We included in the analysis practical limitations such as the consumption of auxiliary logic needed to implement the technique and the minimum size of auxiliary switches imposed by the technology. We proposed an ultra-low-power logic block to push these limits and to obtain benefits from this technique in small capacitances. Finally, we proposed to use a stepwise driver in the driving of the gate capacitance of power switches in switched-capacitor (SC) DC–DC converters. We designed and manufactured, in a 130 nm process, a SC DC–DC converter and measured a 29\% energy reduction in the gate-drive losses of the converter. This accounts for an improvement of 4\% (from 69 to 73\%) in the overall converter efficiency.",

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author = "Francisco Veirano and Lisboa, \{Pablo Castro\} and Pablo P{\'e}rez-Nicoli and Lirida Naviner and Fernando Silveira",

note = "Publisher Copyright: {\textcopyright} 2021, The Author(s), under exclusive licence to Springer Science+Business Media, LLC part of Springer Nature.",

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doi = "10.1007/s10470-021-01810-5",

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AU - Veirano, Francisco

AU - Lisboa, Pablo Castro

AU - Pérez-Nicoli, Pablo

AU - Naviner, Lirida

AU - Silveira, Fernando

PY - 2021/11/1

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AB - In this work we analysed the stepwise charging technique to find the limits from which it is beneficial in terms of load capacitance and charge–discharge frequency. We included in the analysis practical limitations such as the consumption of auxiliary logic needed to implement the technique and the minimum size of auxiliary switches imposed by the technology. We proposed an ultra-low-power logic block to push these limits and to obtain benefits from this technique in small capacitances. Finally, we proposed to use a stepwise driver in the driving of the gate capacitance of power switches in switched-capacitor (SC) DC–DC converters. We designed and manufactured, in a 130 nm process, a SC DC–DC converter and measured a 29% energy reduction in the gate-drive losses of the converter. This accounts for an improvement of 4% (from 69 to 73%) in the overall converter efficiency.

KW - Charge recycling

KW - Stepwise charging

KW - Ultra-low power switched capacitor DC–DC converter

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DO - 10.1007/s10470-021-01810-5

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Analysis of stepwise charging limits and its implementation for efficiency improvement in switched capacitor DC–DC converters

Abstract

Keywords

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