A 103 fJ/b/dB, 10&#x2013;26 Gb/s Receiver With a Dual Feedback Nested Loop CDR for Wide Bandwidth Jitter Tolerance Enhancement

Yao Chia Liu; Wei Zen Chen; Yuan Sheng Lee; Yu Hsiang Chen; Shawn Ming; Ying Hsi Lin

doi:10.1109/JSSC.2023.3278622

A 103 fJ/b/dB, 10–26 Gb/s Receiver With a Dual Feedback Nested Loop CDR for Wide Bandwidth Jitter Tolerance Enhancement

Yao Chia Liu, Wei Zen Chen, Yuan Sheng Lee, Yu Hsiang Chen, Shawn Ming, Ying Hsi Lin

電子研究所

研究成果: Article › 同行評審

摘要

A 10–26 Gb/s energy-efficient receiver incorporating a dual-feedback nested loop clock and data recovery circuit (DF-CDR) is proposed. Combining a direct modulation path on voltage-controlled oscillator (VCO) and phase interpolator (PI)-based phase rotator inside a phase locked loop (PLL), it improves high-frequency jitter tolerance by 0.15 UI. An edge-first equalization scheme is proposed to reduce power and hardware overhead of decision feedback equalizers. Meanwhile, it facilitates adaptive equalization of continuous time linear equalizer, and background offset calibration of the receiver frontend. A three-stage latch comparator is adopted to enable high-speed direct feedback equalizer. By applying PRBS-31 test pattern through a 32 dB loss channel, the receiver is error-free and features the best energy efficiency of 103 fJ/b/dB at 26 Gb/s.

原文	English
頁（從 - 到）	1-11
頁數	11
期刊	IEEE Journal of Solid-State Circuits
DOIs	https://doi.org/10.1109/JSSC.2023.3278622
出版狀態	Accepted/In press - 2023

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10.1109/JSSC.2023.3278622

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引用此

@article{790da5c267cb4feab36ab49399796c0d,

title = "A 103 fJ/b/dB, 10–26 Gb/s Receiver With a Dual Feedback Nested Loop CDR for Wide Bandwidth Jitter Tolerance Enhancement",

abstract = "A 10–26 Gb/s energy-efficient receiver incorporating a dual-feedback nested loop clock and data recovery circuit (DF-CDR) is proposed. Combining a direct modulation path on voltage-controlled oscillator (VCO) and phase interpolator (PI)-based phase rotator inside a phase locked loop (PLL), it improves high-frequency jitter tolerance by 0.15 UI. An edge-first equalization scheme is proposed to reduce power and hardware overhead of decision feedback equalizers. Meanwhile, it facilitates adaptive equalization of continuous time linear equalizer, and background offset calibration of the receiver frontend. A three-stage latch comparator is adopted to enable high-speed direct feedback equalizer. By applying PRBS-31 test pattern through a 32 dB loss channel, the receiver is error-free and features the best energy efficiency of 103 fJ/b/dB at 26 Gb/s.",

keywords = "Bandwidth, Clock and data recovery circuit (CDR), Clocks, decision feedback equalizer (DFE), Delays, Jitter, jitter tolerance (JToL), phase locked loop (PLL), Phase locked loops, Receivers, Voltage-controlled oscillators",

author = "Liu, {Yao Chia} and Chen, {Wei Zen} and Lee, {Yuan Sheng} and Chen, {Yu Hsiang} and Shawn Ming and Lin, {Ying Hsi}",

note = "Publisher Copyright: IEEE",

year = "2023",

doi = "10.1109/JSSC.2023.3278622",

language = "English",

pages = "1--11",

journal = "IEEE Journal of Solid-State Circuits",

issn = "0018-9200",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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T1 - A 103 fJ/b/dB, 10–26 Gb/s Receiver With a Dual Feedback Nested Loop CDR for Wide Bandwidth Jitter Tolerance Enhancement

AU - Liu, Yao Chia

AU - Chen, Wei Zen

AU - Lee, Yuan Sheng

AU - Chen, Yu Hsiang

AU - Ming, Shawn

AU - Lin, Ying Hsi

N1 - Publisher Copyright: IEEE

PY - 2023

Y1 - 2023

N2 - A 10–26 Gb/s energy-efficient receiver incorporating a dual-feedback nested loop clock and data recovery circuit (DF-CDR) is proposed. Combining a direct modulation path on voltage-controlled oscillator (VCO) and phase interpolator (PI)-based phase rotator inside a phase locked loop (PLL), it improves high-frequency jitter tolerance by 0.15 UI. An edge-first equalization scheme is proposed to reduce power and hardware overhead of decision feedback equalizers. Meanwhile, it facilitates adaptive equalization of continuous time linear equalizer, and background offset calibration of the receiver frontend. A three-stage latch comparator is adopted to enable high-speed direct feedback equalizer. By applying PRBS-31 test pattern through a 32 dB loss channel, the receiver is error-free and features the best energy efficiency of 103 fJ/b/dB at 26 Gb/s.

AB - A 10–26 Gb/s energy-efficient receiver incorporating a dual-feedback nested loop clock and data recovery circuit (DF-CDR) is proposed. Combining a direct modulation path on voltage-controlled oscillator (VCO) and phase interpolator (PI)-based phase rotator inside a phase locked loop (PLL), it improves high-frequency jitter tolerance by 0.15 UI. An edge-first equalization scheme is proposed to reduce power and hardware overhead of decision feedback equalizers. Meanwhile, it facilitates adaptive equalization of continuous time linear equalizer, and background offset calibration of the receiver frontend. A three-stage latch comparator is adopted to enable high-speed direct feedback equalizer. By applying PRBS-31 test pattern through a 32 dB loss channel, the receiver is error-free and features the best energy efficiency of 103 fJ/b/dB at 26 Gb/s.

KW - Bandwidth

KW - Clock and data recovery circuit (CDR)

KW - Clocks

KW - decision feedback equalizer (DFE)

KW - Delays

KW - Jitter

KW - jitter tolerance (JToL)

KW - phase locked loop (PLL)

KW - Phase locked loops

KW - Receivers

KW - Voltage-controlled oscillators

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U2 - 10.1109/JSSC.2023.3278622

DO - 10.1109/JSSC.2023.3278622

M3 - Article

AN - SCOPUS:85161024450

SN - 0018-9200

SP - 1

EP - 11

JO - IEEE Journal of Solid-State Circuits

JF - IEEE Journal of Solid-State Circuits

ER -

A 103 fJ/b/dB, 10&#x2013;26 Gb/s Receiver With a Dual Feedback Nested Loop CDR for Wide Bandwidth Jitter Tolerance Enhancement

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A 103 fJ/b/dB, 10–26 Gb/s Receiver With a Dual Feedback Nested Loop CDR for Wide Bandwidth Jitter Tolerance Enhancement