120nW 18.5kHz RC振荡器,比较器偏移抵消,温度稳定性为±0.25%

A. Paidimarri, D. Griffith, Alice Wang, A. Chandrakasan, G. Burra
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引用次数: 101

摘要

集成低频振荡器可以取代晶体振荡器作为睡眠模式定时器,以减小无线传感器的尺寸和成本[1]。由于定时器是为数不多的连续工作的电路之一,最大限度地减少其功耗可以大大降低高占空比系统的睡眠模式功率。为了最大限度地减少定时不确定性和无线电保护时间,从而最大化睡眠时间,振荡器的温度稳定性非常重要。在[2]中描述的电压平均反馈方法在MHz频率内实现了高稳定性,但当缩放到kHz范围时,需要非常大的滤波器。另一方面,基于栅极泄漏的定时器被设计用于亚nw功耗,但在亚hz频率下工作[3]。过去,在kHz范围内的高精度RC振荡器被设计为前馈校正[1]和自斩波操作[4]。在这项工作中,偏移抵消架构在低功率下工作时实现了长期的频率稳定性和温度稳定性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A 120nW 18.5kHz RC oscillator with comparator offset cancellation for ±0.25% temperature stability
Integrated low-frequency oscillators can replace crystal oscillators as sleep-mode timers to reduce the size and cost of wireless sensors [1]. Since the timer is one of the few continuously functioning circuits, minimizing its power consumption can greatly reduce sleep-mode power of highly duty-cycled systems. Temperature stability of the oscillator is important in order to minimize timing uncertainly and guard time for the radios, and thus maximizing sleep time. The voltage-averaging feedback method described in [2] achieves high stability in the MHz frequencies, but when scaled to the kHz range, requires very large filters. On the other extreme, gate leakage-based timers have been designed for sub-nW power consumption, but operate in the sub-Hz frequencies [3]. In the past, high accuracy RC oscillators in the kHz range have been designed with feed-forward correction [1] and self-chopped operation [4]. In this work, an offset cancellation architecture achieves long-term frequency stability and temperature stability while operating at lower power.
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