A reconfigurable distributed all-digital clock generator core with SSC and skew correction in 22nm high-k tri-gate LP CMOS

2012 IEEE International Solid-State Circuits Conference Pub Date : 2012-04-03 DOI:10.1109/ISSCC.2012.6176934

Yee William Li, C. Ornelas, Hyung Seok Kim, H. Lakdawala, A. Ravi, K. Soumyanath

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引用次数: 27

Abstract

Diverse spread spectrum clocking (SSC) generation requirements necessitate multiple reference clocks, extra pins, and off-chip components. With analog integer-n PLL-based clock generators, it is difficult to meet all these needs with a common reference clock. One disadvantage is that the frequency resolution in an integer-n PLL is limited by the reference frequency. A lower reference frequency limits the bandwidth and lock time, amplifies jitter from the reference, and increases the loop filter area. Additionally, analog PLLs suffer from unpredictable loop dynamics and clock skews with PVT, mismatch, and transistor leakage, further exacerbated by process scaling. Turning off and waking up an analog PLL requires charging or discharging loop filter capacitors which is inherently slow. This paper presents an all-digital clock generation architecture which (1) provides fractional-n capability in the digital domain; (2) implements SSC within the PLL loop; (3) performs digital clock deskew; and (4) provides dynamic loop bandwidth adjustment to shorten lock time.

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在22nm高k三栅极LP CMOS中具有SSC和倾斜校正的可重构分布式全数字时钟发生器核心

不同的扩频时钟(SSC)生成要求需要多个参考时钟、额外的引脚和片外组件。基于模拟整数锁相环的时钟发生器很难用一个通用的参考时钟来满足所有这些需求。一个缺点是整数锁相环的频率分辨率受到参考频率的限制。较低的参考频率限制了带宽和锁定时间，放大了参考频率的抖动，并增加了环路滤波器的面积。此外，模拟锁相环还会受到不可预测的环路动力学和时钟偏差(PVT)、失配和晶体管泄漏的影响，而工艺缩放会进一步加剧这些问题。关闭和唤醒模拟锁相环需要充电或放电环路滤波电容器，这本身就很慢。本文提出了一种全数字时钟生成体系结构，该体系结构(1)在数字域提供分数n能力;(2)在锁相环内实现SSC;(3)执行数字时钟桌面;(4)提供动态环路带宽调节，缩短锁定时间。

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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2012 IEEE International Solid-State Circuits Conference

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