A fractional-sampling-rate ADC-based CDR with feedforward architecture in 65nm CMOS

2010 IEEE International Solid-State Circuits Conference - (ISSCC) Pub Date : 2010-03-18 DOI:10.1109/ISSCC.2010.5434004

Oleksiy Tyshchenko, A. Sheikholeslami, H. Tamura, Y. Tomita, H. Yamaguchi, M. Kibune, T. Yamamoto

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引用次数: 10

Abstract

ADC-based CDRs take digital samples of the received signal to recover the clock and data. Digital representation of the signal allows for extensive channel equalization in the digital domain. Recently-reported ADC-based CDRs sample the signal at 1× or 2× the baud rate. The 1× CDR aligns the sampling clock with the signal using a phase-tracking feedback loop [1–2], which requires a voltage-controlled oscillator or phase interpolator, both analog circuits, to adjust the phase of the sampling clock. To eliminate these analog circuits (and their phase control) in favor of an all-digital implementation, a blind-sampling ADC-based CDR (top of Fig. 8.6.1) samples the received signal at 2× without phase locking to the signal. The CDR then interpolates between the blind samples to obtain a new set of samples in order to recover the phase and data [3–4]. The doubling of the sampling rate, however, increases the ADC power consumption or, equivalently, reduces the maximum baud rate due to the conversion-rate limitations of ADCs.

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一种基于分数采样率adc的65nm CMOS前馈CDR

基于adc的话单采集接收信号的数字采样来恢复时钟和数据。信号的数字表示允许在数字域中进行广泛的信道均衡。最近报道的基于adc的话单以1倍或2倍波特率采样信号。1x CDR使用相位跟踪反馈回路[1-2]将采样时钟与信号对齐，这需要电压控制振荡器或相位插值器，两者都是模拟电路，以调整采样时钟的相位。为了消除这些模拟电路(及其相位控制)，采用全数字实现，基于adc的盲采样CDR(图8.6.1顶部)以2倍的频率对接收信号进行采样，而不锁定信号的相位。然后，CDR在盲样本之间进行插值，以获得一组新的样本，以恢复相位和数据[3-4]。然而，采样率的加倍增加了ADC的功耗，或者，由于ADC的转换速率限制，降低了最大波特率。

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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2010 IEEE International Solid-State Circuits Conference - (ISSCC)

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