0.022mm2 970µW双环注入锁相环,−243dB FOM,采用可合成全数字PVT校准电路

W. Deng, A. Musa, T. Siriburanon, M. Miyahara, K. Okada, A. Matsuzawa
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引用次数: 41

摘要

对于现代SoC系统,对片上时钟发生器的严格要求包括低面积,低功耗,环境不敏感和尽可能低的抖动性能。乘法延迟锁环(MDLL)[1-2]、次谐波注入锁定技术[3]和次采样技术[4-5]可以显著改善时钟发生器的随机抖动特性。然而,为了保证它们在过程电压-温度(PVT)变化下的正确运行和最佳性能,每种方法都需要额外的校准电路,这带来了难以满足的时序约束。在注入锁定锁相环(IL-PLL)的情况下,需要进行自由运行频率校准。然而,注入锁定振荡器的输出总是固定在期望的频率上,因此自由运行频率的移位(例如由温度和电压变化引起的)不能简单地通过使用锁频环(FLL)来补偿。因此,我们建议使用双环拓扑,其中一个自由运行的压控振荡器(VCO)作为放置在FLL内的复制VCO,用于跟踪温度和电压漂移。另一个VCO(主VCO)被注入锁定以产生低抖动时钟,而自由运行的频移可以由复制环路补偿。该方法在温度和电压变化时提供鲁棒输出。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A 0.022mm2 970µW dual-loop injection-locked PLL with −243dB FOM using synthesizable all-digital PVT calibration circuits
For modern SoC systems, stringent requirements on on-chip clock generators include low area, low power consumption, environmental insensitivity, and the lowest possible jitter performance. Multiplying Delay-Locked Loop (MDLL) [1-2], subharmonically injection-locked techniques [3], and sub-sampling techniques [4-5] can significantly improve the random jitter characteristics of a clock generator. However, in order to guarantee their correct operation and optimal performance over process-voltage-temperature (PVT) variations, each method requires additional calibration circuits, which impose difficult-to-meet timing constraints. In the case of an injection-locked PLL (IL-PLL), a free-running frequency calibration is required. However, the output of an injection-locked oscillator is always fixed at the desired frequency, so a shift in the free-running frequency (e.g. caused by temperature and voltage variations) cannot be simply compensated for by using a frequency-locked loop (FLL). Therefore, we propose the use of a dual-loop topology with one free-running voltage-controlled oscillator (VCO) as a replica VCO placed inside a FLL for tracking temperature and voltage drift. The other VCO (the main VCO) is injection locked for producing a low-jitter clock, while the free-running frequency shift can be compensated for by the replica loop. The method provides robust output over temperature and voltage variations.
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