11.7在28nm CMOS 56Gb/s 50mW NRZ接收器

2021 IEEE International Solid- State Circuits Conference (ISSCC) Pub Date : 2021-02-13 DOI:10.1109/ISSCC42613.2021.9365997

Atharav Atharav, B. Razavi

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引用次数: 5

摘要

随着更高的数据速率和每个芯片更大数量的通道被寻求[1]-[6]，有线收发器的功耗变得越来越关键。虽然对有损信道很有吸引力，但PAM-4信令主要取决于基于adc的接收器(RXs)和相对较高的功耗[1]，[2]。另一方面，非归零(NRZ)接收器可以在模拟域实现，潜在地消耗更少的功率，但它们必须处理更大的损耗。本文介绍了一种NRZ RX，在28GHz信道损耗为25dB的情况下，其功率降低了两倍以上，而误码率< 10-12。所提出的设计可以与PAM-4竞争，并且/或在必须支持56Gb/s接收的112Gb/s系统中服务。RX架构如图11.7.1所示。数据路径由CTLE核心、DFE核心、离散时间线性均衡器(DTLE)[4]和DMUX组成。通过多种前馈和反馈路径，大大提高了接收机的性能。还提出了一种半速率“带通”CDR，它避免了加载主数据路径和使用正交vco。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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11.7 A 56Gb/s 50mW NRZ Receiver in 28nm CMOS

The power consumption of wireline transceivers has become increasingly critical as higher data rates and a larger numbers of lanes per chip are sought [1] –[6]. While attractive for lossy channels, PAM-4 signaling has mostly dictated ADC-based receivers (RXs) and relatively high power consumption [1], [2]. Non-return-to-zero (NRZ) receivers, on the other hand, can be realized in the analog domain, potentially consuming less power, but they must deal with a greater loss. This paper introduces an NRZ RX that achieves more than a twofold reduction in power while exhibiting BER < 10-12 for a channel loss of 25dB at 28GHz. The proposed design can compete with PAM-4 counterparts and/or serve in 112Gb/s systems that must also support 56Gb/s reception. Figure 11.7.1 shows the RX architecture. The data path consists of a CTLE core, a DFE core, a discrete-time linear equalizer (DTLE) [4], and a DMUX. The receiver performance is greatly improved by a number of feedforward and feedback paths. Also proposed is a half-rate “band-pass” CDR that avoids loading the main data path and the use of quadrature VCOs.

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2021 IEEE International Solid- State Circuits Conference (ISSCC)

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