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快速建立时间的自适应锁相环 被引量:7

An Adaptive PLL Architecture to Achieve Fast Settling Time
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摘要 该文简要讨论了环路性能(建立时间,相位噪声和杂散信号)和环路参数(带宽,相位裕度等)的相互关系。提出并分析了一种自适应的具有快速建立时间的锁相环结构及其关键模块(鉴相鉴频器和电荷泵)。该结构基于两个环路:粗调谐环路和精调谐环路。粗调谐环路用于快速收敛,而精调谐环路用于精细的调整。环路参数调整连续发生,无需切换环路滤波器元件和外面的控制信号。基于SMIC0.18μm1.8VCMOS工艺的Spectre仿真表明:粗调谐鉴相鉴频器能够有效地关断粗调谐回路;电荷泵上下电流具有小于0.1%的静态失配特性;在相同的环路带宽下与传统的锁相环相比,自适应锁相环能减少超过30%的建立时间。 The relationships between loop performance (settling time, phase noise and spur signal) and loop parameters (bandwidth and phase margin) are briefly discussed in the paper. An adaptive Phase-Locked Loop (PLL) with a fast settling time and its key blocks including Phase-Frequency Detector (PFD) and charge pump are then proposed and analyzed. The proposed architecture is based on two tuning loops: a coarse-tuning loop and a fine-tuning loop. The coarse-tuning loop is used for fast convergence and the fine-tuning loop is used to complete fine adjustments. Adaptation of loop parameters occurs continuously, without switching of loop filter components, and without interaction from outside control signal. Spectre simulation based on SMIC 0.18μm 1.8V supply voltage CMOS technology shows that coarse-tuning PFD can effectively cut off coarse-tuning loop, and the charge pump has a 〈0.1% up/down current mismatching characteristic. The adaptive PLL can reduce settling time over 30% in comparison to the conventional PLL in the same loop bandwidth.
作者 黄水龙 王志华
机构地区 清华大学电子工程系 清华大学深圳研究生院
出处 《电子与信息学报》 EI CSCD 北大核心 2007年第6期1492-1495,共4页 Journal of Electronics & Information Technology
基金 国家高技术研究发展计划(60475018) 国家重点基础研究发展规划(G2000036508)资助课题
关键词 锁相环 鉴相鉴频器 电荷泵 PLL PFD Charge pump
分类号 TN763.2 [电子电信—电路与系统]
  • 相关文献

参考文献7

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二级参考文献6

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共引文献5

同被引文献31

  • 1刘建宇.频率综合器跳频时间测试[J].上海航天,2005,22(4):56-59. 被引量:3
  • 2李仲秋,胡锦,陈迪平.三阶电荷泵锁相环的稳定性分析[J].电子器件,2006,29(2):483-485. 被引量:5
  • 3陈永聪.集成CMOS锁相环中抑制参考杂散的设计方法[J].Journal of Semiconductors,2006,27(12):2196-2202. 被引量:4
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  • 9Kim Deok-soo, Song Heesoo, and Kim Taeho. A 0.3-1.4 GHz all-digital fractional-N PLL with adaptive loop gain controller[J]. IEEE Journal of Solid-State Circuits, 2010, 45(11): 2300-2311.
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引证文献7

二级引证文献12

电子与信息学报
2007年 第6期

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