一种带校准四倍频器的9GHz 72fs全集成抖动分数n数字锁相环

2022 IEEE Custom Integrated Circuits Conference (CICC) Pub Date : 2022-04-01 DOI:10.1109/CICC53496.2022.9772796

Francesco Buccoleri, S. M. Dartizio, F. Tesolin, Luca Avallone, Alessio Santiccioli, Agata Lesurum, Giovanni Steffan, A. Bevilacqua, L. Bertulessi, Dmytro Cherniak, C. Samori, A. Lacaita, S. Levantino

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引用次数: 4

摘要

现代无线标准如5G[1]要求在数十GHz范围内使用低于100fs的分数n锁相环。限制数字锁相环(DPLL)抖动和点噪声的主要因素一方面是数字控制振荡器(DCO)的相位噪声，另一方面是DCO频率粒度引入的量化噪声。虽然已经探索了几种方法，如多核振荡器[2]，[3]或多核锁相环[4]来权衡功耗与相位噪声，但在实践中，每增加一倍的核数，理论上的相位噪声降低3dB从未完全实现。在DCO模拟/数字域交叉中引入的QN的第二个问题原则上可以通过增加DCO分辨率来解决，但这是以大量DCO位为代价的，这需要更高的设计复杂性和更大的面积占用。或者，可以使用$\Delta\Sigma$调制器驱动DCO对QN及其相对于参考频率过采样的时钟进行高通整形，以将频谱中的QN碰撞移动到更高的频率。先前生成$\Delta\Sigma$时钟的解决方案要么基于一个辅助锁相环乘以参考时钟频率，要么基于一个高速分频器除以DCO输出[3]。在第一种情况下，辅助锁相环和主锁相环之间的拉扯现象会使性能恶化，而在第二种情况下，分频器可能会消耗大量功率，并且必须解决两个非同步时钟域之间交叉的亚稳态问题。这项工作提出了一种9GHz分数n数字砰砰声锁相环(BBPLL)，在近整数通道下实现72fs rms的总集成抖动(包括杂散)，在10MHz偏移量下实现-140.7dBc/Hz的点相位噪声水平。该锁相环采用背景数字周期平均(DPA)算法校准的低功耗四倍器来降低$\Delta\Sigma$ DCO的QN，并采用低噪声的真相合成器(TIPC)将两个锁相环核心组合在一起以降低相位噪声。

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A 9GHz 72fs-Total-lntegrated-Jitter Fractional-N Digital PLL with Calibrated Frequency Quadrupler

Sub-100fs fractional-N PLLs in the tens of GHz range are required by modern wireless standards such as 5G [1]. The main factors limiting jitter and spot-noise in a digital PLL (DPLL) are on one hand the phase noise of the digitally controlled oscillator (DCO) and, on the other hand, the quantization noise (QN) introduced by the DCO frequency granularity. Though several approaches, such as multi-core oscillators [2], [3] or multi-core PLLs [4] have been explored to trade power consumption against phase noise, the theoretical phase-noise reduction of 3dB per each doubling of the number of cores is never fully obtained in practice. The second issue of the QN introduced at the DCO analog/digital domain crossing could be in principle solved by increasing DCO resolution, but this comes at the cost of a larger number of DCO bits which entails higher design complexity and larger area occupation. Alternatively, a $\Delta\Sigma$ modulator driving the DCO can be used to high-pass-shape the QN and its clock oversampled with respect to the reference frequency to move the QN bump in the spectrum to higher frequency. Prior solutions to generate the $\Delta\Sigma$ clock are based either on an auxiliary PLL which multiplies the reference clock frequency or a high-speed frequency divider that divides the DCO output [3]. While in the first case pulling phenomena between auxiliary and main PLL are observed to worsen performance, in the second case, the frequency divider may consume large power and metastability in the crossing between the two non-synchronous clock domains has to be addressed. This work presents a 9GHz fractional-N digital bang-bang PLL (BBPLL) achieving 72fs rms total integrated jitter (including spurs) at near-integer channels and -140.7dBc/Hz spot phase-noise level at 10MHz offset. The PLL relies on a low-power quadrupler calibrated by a background digital-period-averaging (DPA) algorithm to reduce the QN of the $\Delta\Sigma$ DCO, and on a low-noise true-in-phase combiner (TIPC) which combines two PLL cores to reduce phase noise.

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2022 IEEE Custom Integrated Circuits Conference (CICC)

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