5.1 A 1.5μW 0.135pJ·%RH2 CMOS Humidity Sensor Using Adaptive Range-Shift Zoom CDC and Power-Aware Floating Inverter Amplifier Array

2021 IEEE International Solid- State Circuits Conference (ISSCC) Pub Date : 2021-02-13 DOI:10.1109/ISSCC42613.2021.9365931
Heyi Li, Z. Tan, Yuanxin Bao, Han Xiao, Hao Zhang, Kaixuan Du, Yihan Zhang, Le Ye, Ru Huang
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引用次数: 6

Abstract

Capacitive sensors are widely deployed in low-power IoT nodes, where power consumption is stringently limited by the batteries or energy harvesters. Energy-efficient interface circuits that convert sensing information into digital code are important for successful application of such sensors. Two humidity sensors based on a frequencylocking loop (FLL) [1] and a delta-sigma modulator (DSM) [2] achieve high resolution, but at the expense of high power consumption of 10.32μW and 15.6μW, respectively. The Zoom-based humidity sensor in [3] and capacitor-to-digital converters (CDC) in [3,4] exhibit a significantly improved dynamic range (DR). However, the DSM in the Zoom scheme typically entails large redundancy to cover the SAR conversion error due to noise or interference. Further, the OTA current budget is set to drive the maximum input capacitance, thus wasting power when driving typically small capacitance in most cases.
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5.1采用自适应变焦CDC和功率感知浮动逆变放大器阵列的1.5μW 0.135pJ·%RH2 CMOS湿度传感器
电容式传感器广泛部署在低功耗物联网节点中,这些节点的功耗受到电池或能量收集器的严格限制。将传感信息转换为数字代码的节能接口电路对于此类传感器的成功应用至关重要。两种基于锁频环(FLL)[1]和δ - σ调制器(DSM)[2]的湿度传感器实现了高分辨率,但功耗分别为10.32μW和15.6μW。[3]中基于变焦的湿度传感器和[3,4]中的电容-数字转换器(CDC)表现出显著改善的动态范围(DR)。然而,在变焦方案中,DSM通常需要大量的冗余来覆盖由于噪声或干扰引起的SAR转换误差。此外,OTA电流预算被设置为驱动最大输入电容,因此在大多数情况下驱动典型的小电容时会浪费功率。
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2021 IEEE International Solid- State Circuits Conference (ISSCC)
2021 IEEE International Solid- State Circuits Conference (ISSCC)
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