A 1.4psrms-period-jitter TDC-less fractional-N digital PLL with digitally controlled ring oscillator in 65nm CMOS

2010 IEEE International Solid-State Circuits Conference - (ISSCC) Pub Date : 2010-03-18 DOI:10.1109/ISSCC.2010.5433839
W. Grollitsch, R. Nonis, N. D. Dalt
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引用次数: 63

Abstract

State of the art digital PLLs can be divided in two categories, depending on the implementation of the digital phase detector. Digital clocking and wireline applications mostly use a Bang-Bang detector (BBPLLs) [1–3], offering very low jitter values in integer-N mode but not supporting fractional-N synthesis, which is desirable to implement, i.e., spread spectrum clocking (SSC) for EMI reductions. Wireless applications implement time to digital converters (TDC) [4–6] which allow fractional-N synthesis, but require high architecture complexity, need calibration routines for period normalization, and introduce analog limitations that a digital PLL should be intended to eliminate.
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基于65nm CMOS的无tdc分数n数字锁相环和数字控制环振荡器
目前的数字锁相环可以分为两类,这取决于数字鉴相器的实现。数字时钟和有线应用大多使用Bang-Bang检测器(bbpll)[1-3],在整数n模式下提供非常低的抖动值,但不支持分数n合成,这是理想的实现,即用于减少EMI的扩频时钟(SSC)。无线应用实现时间到数字转换器(TDC)[4-6],它允许分数n合成,但需要很高的架构复杂性,需要周期归一化的校准例程,并引入数字锁相环应该消除的模拟限制。
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2010 IEEE International Solid-State Circuits Conference - (ISSCC)
2010 IEEE International Solid-State Circuits Conference - (ISSCC)
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