Comparison and design of VCOs for ultra-low power CMOS temperature sensors

2015 International Conference on Communications, Signal Processing, and their Applications (ICCSPA'15) Pub Date : 2015-04-09 DOI:10.1109/ICCSPA.2015.7081297

Waseem Arshad, R. Ramzan, A. Beg, Nabil Bastaki

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引用次数: 5

Abstract

Voltage controller oscillator (VCO) based CMOS temperature sensors are capable of lower power operation (albeit at the cost of sensitivity and resolution) than their BJT counterparts. The power consumption of the sense and conversion blocks is much lower than the VCO itself and hence any further power reduction would be a daunting task. In this work, we compare the performance of three types of VCOs that are suitable for ultra-low power CMOS temperature sensing. The proposed VCOs have been implemented in 150 nm standard CMOS technology, and are biased in sub-threshold region to ensure ultra-low power operation. The frequency of operation for the VCOs is purposely kept low in order to reduce the switching losses. The Differential Cross Coupled (DCC) VCO shows the sensitivity of 1.66Hz/°C with power consumption of 2.5nW. While the Current Starved VCO shows better sensitivity, which is 3.66Hz/°C with power consumption of 12nW. The Transmission Gate-based VCO has the worst sensitivity of 0.28Hz/°C with power consumption of 3nW. Based on extensive simulations, we conclude that the DCC-based VCO is the best choice based on its medium sensitivity and ultra-low power consumption.

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超低功耗CMOS温度传感器压控振荡器的比较与设计

基于电压控制振荡器(VCO)的CMOS温度传感器能够比其BJT同类产品更低的功耗运行(尽管以灵敏度和分辨率为代价)。感测和转换模块的功耗远低于VCO本身，因此进一步降低功耗将是一项艰巨的任务。在这项工作中，我们比较了适合超低功耗CMOS温度传感的三种类型的压控振荡器的性能。所提出的vco已在150nm标准CMOS技术上实现，并在亚阈值区域偏置，以确保超低功耗工作。为了减少开关损耗，vco的工作频率故意保持在较低的水平。差分交叉耦合(DCC)压控振荡器灵敏度为1.66Hz/°C，功耗为2.5nW。而电流饥渴VCO则表现出更好的灵敏度，为3.66Hz/°C，功耗为12nW。基于传输门的VCO灵敏度最差，为0.28Hz/°C，功耗为3nW。通过大量的仿真，我们得出结论，基于直流控制的压控振荡器具有中等灵敏度和超低功耗的优点，是最佳选择。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2015 International Conference on Communications, Signal Processing, and their Applications (ICCSPA'15)

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