Enhanced bootstrapped CMOS driver for large RC-load and ultra-low voltage VLSI

Hyeon Jun Kim; Jong Woo Kim; Bai Sun Kong

doi:10.1587/elex.9.1208

Enhanced bootstrapped CMOS driver for large RC-load and ultra-low voltage VLSI

Hyeon Jun Kim
, Jong Woo Kim
, Bai Sun Kong

Department of Semiconductor Systems Engineering

Sungkyunkwan University

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

2 Scopus citations

Abstract

This letter describes a novel bootstrapped CMOS driver for driving a large RC load in ultra-low voltage VLSI. The proposed driver eliminates the leakage from boosted nodes during bootstrapping operations, resulting in lower power consumption and higher switching speed. Since the proposed driver requires no additional transistors for eliminating the leakage, further improvements on switching speed and power consumption as well as layout area are achieved. Comparison results in a 0.13 μm CMOS technology indicated that the proposed bootstrapped CMOS driver achieved 82%~18% improvements in terms of power consumption as compared to conventional bootstrapped CMOS drivers. They also indicated that the proposed driver achieved 42%~11% improvements in terms of switching speed. Improvement on power-delay product (PDP) is as much as 160%~30% as compared to conventional bootstrapped drivers.

Original language	English
Pages (from-to)	1208-1213
Number of pages	6
Journal	IEICE Electronics Express
Volume	9
Issue number	14
DOIs	https://doi.org/10.1587/elex.9.1208
State	Published - 2012

Keywords

Bootstrapped driver
CMOS driver
Sub-threshold driver
Ultra low-voltage

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10.1587/elex.9.1208

Cite this

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title = "Enhanced bootstrapped CMOS driver for large RC-load and ultra-low voltage VLSI",

abstract = "This letter describes a novel bootstrapped CMOS driver for driving a large RC load in ultra-low voltage VLSI. The proposed driver eliminates the leakage from boosted nodes during bootstrapping operations, resulting in lower power consumption and higher switching speed. Since the proposed driver requires no additional transistors for eliminating the leakage, further improvements on switching speed and power consumption as well as layout area are achieved. Comparison results in a 0.13 μm CMOS technology indicated that the proposed bootstrapped CMOS driver achieved 82\%\textasciitilde{}18\% improvements in terms of power consumption as compared to conventional bootstrapped CMOS drivers. They also indicated that the proposed driver achieved 42\%\textasciitilde{}11\% improvements in terms of switching speed. Improvement on power-delay product (PDP) is as much as 160\%\textasciitilde{}30\% as compared to conventional bootstrapped drivers.",

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AB - This letter describes a novel bootstrapped CMOS driver for driving a large RC load in ultra-low voltage VLSI. The proposed driver eliminates the leakage from boosted nodes during bootstrapping operations, resulting in lower power consumption and higher switching speed. Since the proposed driver requires no additional transistors for eliminating the leakage, further improvements on switching speed and power consumption as well as layout area are achieved. Comparison results in a 0.13 μm CMOS technology indicated that the proposed bootstrapped CMOS driver achieved 82%~18% improvements in terms of power consumption as compared to conventional bootstrapped CMOS drivers. They also indicated that the proposed driver achieved 42%~11% improvements in terms of switching speed. Improvement on power-delay product (PDP) is as much as 160%~30% as compared to conventional bootstrapped drivers.

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Enhanced bootstrapped CMOS driver for large RC-load and ultra-low voltage VLSI

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Keywords

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