A 24 mW 5.7 Gbps dual frequency conversion demodulator for impulse radio with the first sidelobe

Kaoru Kohira; Naoki Kitazawa; Hiroki Ishikuro

doi:10.1587/transele.E99.C.1164

A 24 mW 5.7 Gbps dual frequency conversion demodulator for impulse radio with the first sidelobe

Kaoru Kohira, Naoki Kitazawa, Hiroki Ishikuro

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

Abstract

This paper presents a modulation scheme for impulse radio that uses the first sidelobe for transmitting a non-return-to-zero baseband signal and the implementation of a dual frequency conversion demodulator. The proposed modulation technique realizes two times higher frequency efficiency than that realized by binary phase-shift keying modulation and does not require an up-converter in the transmitter. The dual frequency conversion demodulator compensates for the spectrum distortion caused by the frequency response of the circuits and channel. The effect of frequency compensation is analytically studied. The fabricated demodulator test chip of 65 nm CMOS achieves clock and data recovery at 5.7 Gbps with a power consumption of 24 mW.

Original language	English
Pages (from-to)	1164-1173
Number of pages	10
Journal	IEICE Transactions on Electronics
Volume	E99C
Issue number	10
DOIs	https://doi.org/10.1587/transele.E99.C.1164
Publication status	Published - 2016 Oct 1

Keywords

Clock recovery
Impulse radio
Sidelobe
UWB

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Electrical and Electronic Engineering

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10.1587/transele.E99.C.1164

Cite this

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abstract = "This paper presents a modulation scheme for impulse radio that uses the first sidelobe for transmitting a non-return-to-zero baseband signal and the implementation of a dual frequency conversion demodulator. The proposed modulation technique realizes two times higher frequency efficiency than that realized by binary phase-shift keying modulation and does not require an up-converter in the transmitter. The dual frequency conversion demodulator compensates for the spectrum distortion caused by the frequency response of the circuits and channel. The effect of frequency compensation is analytically studied. The fabricated demodulator test chip of 65 nm CMOS achieves clock and data recovery at 5.7 Gbps with a power consumption of 24 mW.",

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Y1 - 2016/10/1

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AB - This paper presents a modulation scheme for impulse radio that uses the first sidelobe for transmitting a non-return-to-zero baseband signal and the implementation of a dual frequency conversion demodulator. The proposed modulation technique realizes two times higher frequency efficiency than that realized by binary phase-shift keying modulation and does not require an up-converter in the transmitter. The dual frequency conversion demodulator compensates for the spectrum distortion caused by the frequency response of the circuits and channel. The effect of frequency compensation is analytically studied. The fabricated demodulator test chip of 65 nm CMOS achieves clock and data recovery at 5.7 Gbps with a power consumption of 24 mW.

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KW - Sidelobe

KW - UWB

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A 24 mW 5.7 Gbps dual frequency conversion demodulator for impulse radio with the first sidelobe

Abstract

Keywords

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