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A 20-Gb/s/Pin Compact Single-Ended DCC-Less DECS Transceiver With CDR-Less RX Front-End for On-Chip Links | IEEE Journals & Magazine | IEEE Xplore
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A 20-Gb/s/Pin Compact Single-Ended DCC-Less DECS Transceiver With CDR-Less RX Front-End for On-Chip Links


Abstract:

This article presents a 20-Gb/s/pin 0.0024-mm2 single-ended data-embedded clock signaling (DECS) transceiver (TRX) for short-reach on-chip links. The receiver (RX) direct...Show More

Abstract:

This article presents a 20-Gb/s/pin 0.0024-mm2 single-ended data-embedded clock signaling (DECS) transceiver (TRX) for short-reach on-chip links. The receiver (RX) directly recovers (self-slicing) and deserializes (auto-deserialization) the data from the DECS input of the RX front-end without a clock and data recovery (CDR) or clock and data alignment (CDA) circuits, while improving the timing requirement and the tolerance to duty cycle error and supply noise. At 20 Gb/s/pin, the horizontal eye was measured 0.99 UI at nominal and remained equal to or larger than 0.88 UI either when the clock duty cycle changed from 40% to 60% or when a 50-MHz 300-mV _{\mathrm {p-p}} sinusoidal supply noise was injected to the RX from a printed circuit board (PCB). In addition, the proposed RX could tolerate a 200-MHz 300-mV _{\mathrm {p-p}} sinusoidal supply noise and 200-mV _{\mathrm {p-p}} crest factor 7 (CF7) Gaussian supply noise, while achieving 0.90 UI horizontal eye size in both cases. Because complex clocking circuits were removed, the active RX core excluding on-die-terminations (ODTs) achieved the smallest area occupancy of 0.000058 mm2 and decent energy efficiency of 0.18 pJ/b. With the proposed technique, a compact high-speed short-reach on-chip link is feasible without expensive high-speed duty cycle correction (DCC), duty cycle detection (DCD), CDR, or CDA. The proposed TRX was fabricated in 28-nm CMOS low-power performance (LPP) technology.
Published in: IEEE Journal of Solid-State Circuits ( Volume: 58, Issue: 11, November 2023)
Page(s): 3253 - 3265
Date of Publication: 03 July 2023

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