Low Power Clock Generator Design With CMOS Signaling

IEEE Open Journal of the Solid-State Circuits Society Pub Date : 2021-10-07 DOI:10.1109/OJSSCS.2021.3118339

Yongping Fan;Ian A. Young

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引用次数: 2

Abstract

The requirements for computing with higher energy efficiency in the datacenter and for longer battery life in laptop computers, cell phones, and other IoT devices while increasing performance with higher frequency and more cores, drive the needs for more clock generators with increased performance (frequency and jitter) and lower power budgets. The traditional current mode low swing clock generators were used widely in industry about 10 years ago. Although it had the advantage of higher supply noise rejection due to the differential nature of the architectures, however, it had the disadvantages of high-power consumption, large layout area, and not friendly to process scaling. Contrary to current mode low swing design, clock generator architectures with CMOS large swing signaling, which have advantages of low power consumption, small area, and based on circuits friendly to process scaling, have been widely adopted for clocking generation in the industry since 2009. In this paper, phase locked loops, delay locked loops, phase interpolators, high resolution digital to time converter and clock distribution techniques with CMOS large swing signaling will be discussed and reviewed.

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低功耗CMOS信号时钟发生器的设计

数据中心对更高能效的计算以及笔记本电脑、手机和其他物联网设备对更长电池寿命的要求，同时通过更高的频率和更多的内核来提高性能，这推动了对更多性能（频率和抖动）更高、功率预算更低的时钟发生器的需求。传统的电流模式低摆幅时钟发生器在10年前就在工业上得到了广泛的应用。尽管由于体系结构的差异性，它具有较高的电源噪声抑制率的优点，但它也存在功耗大、布局面积大、不利于工艺扩展等缺点。与当前模式的低摆幅设计相反，自2009年以来，具有CMOS大摆幅信号的时钟发生器架构已被业界广泛采用，该架构具有低功耗、小面积和基于易于工艺扩展的电路的优点。本文将讨论和评述CMOS大摆幅信号的锁相环、延迟锁相环、相位插值器、高分辨率数时转换器和时钟分配技术。

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IEEE Open Journal of the Solid-State Circuits Society

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