基于tdc的初始频率误差检测与频率跟踪环路的4周期启动参考无时钟数字话单

T. Iizuka, Meikan Chin, T. Nakura, K. Asada
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引用次数: 0

摘要

本文提出了一种无参考时钟的快速启动CDR,该CDR使用带嵌入式时间数字转换器(TDC)的相位发生器从待机状态恢复,只有4位前置。相位发生器利用其内部TDC检测1-UI时间间隔,并作为自调谐数字控制延迟线工作。一旦相位发生器对恢复的时钟周期进行粗调整,那么剩余时间差就会通过一个精细的数字时间转换器(DTC)进行精细调整。由于精细DTC的调谐分辨率与用作相位检测器的TDC的时间分辨率相匹配,因此微调立即完成。在初始粗、细延迟调谐后,启动频率跟踪反馈回路,以提高CDR的连续同位(CID)容限。通过采用频率跟踪架构,该CDR实现了超过100位的CID容限。在65nm块体CMOS工艺中实现的原型以0.9 - 2.15Gbps的连续速率运行。它在工作状态下消耗5.1 ~ 8.4mA,在待机状态下从1.0V电源消耗42 μ A泄漏电流。关键词:时钟数据恢复(CDR);
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4-Cycle-Start-Up Reference-Clock-Less Digital CDR Utilizing TDC-Based Initial Frequency Error Detection with Frequency Tracking Loop
SUMMARY This paper proposes a reference-clock-less quick-start-up CDR that resumes from a stand-by state only with a 4-bit preamble utilizing a phase generator with an embedded Time-to-Digital Converter (TDC). The phase generator detects 1-UI time interval by using its internal TDC and works as a self-tunable digitally-controlled delay line. Once the phase gen- erator coarsely tunes the recovered clock period, then the residual time difference is finely tuned by a fine Digital-to-Time Converter (DTC). Since the tuning resolution of the fine DTC is matched by design with the time resolution of the TDC that is used as a phase detector, the fine tuning completes instantaneously. After the initial coarse and fine delay tuning, the feedback loop for frequency tracking is activated in order to improve Consecutive Identical Digits (CID) tolerance of the CDR. By applying the frequency tracking architecture, the proposed CDR achieves more than 100bits of CID tolerance. A prototype implemented in a 65nm bulk CMOS process operates at a 0.9 − 2.15Gbps continuous rate. It consumes 5.1 − 8.4mA in its active state and 42µA leakage current in its stand-by state from a 1.0V supply. key words: Clock-and-data recovery (CDR),
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