A control system for a low power bidirectional front-end for resonating sensors

2017 IEEE 14th International Conference on Networking, Sensing and Control (ICNSC) Pub Date : 2017-05-01 DOI:10.1109/ICNSC.2017.8000112

L. Marchetti, Y. Berg, O. Mirmotahari, M. Azadmehr

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引用次数: 3

Abstract

In this paper, we propose a digital control system to automatize the operation of a bidirectional front-end for resonating sensors. Due to the simplicity, the control system is power conservative and compact. The main source of power consumption in the bidirectional front-end is the amplifier used to read-out the sensor. Power can be saved by turning off the amplifier after a few periods of the oscillating signal, which is enough to detect the resonant frequency of the sensor. The concept was initially proved by performing simulations in SPICE by using AMS-350nm CMOS technology model. A prototype was realized with discrete components on a PCB and tested with a power supply of 5V. The reading cycle was fixed at 10kHz and a RLC load has been used as model of a MEMS resonant sensor. The values for the RLC components used for the tests are 100Ω, 270pF, 10mH. The nominal power consumption of the front-end without the support of the sleeping mode is 1.7mW while the sleeping mode with reading one oscillation period reduces the power dissipation to 270µW(15.88% of 1.7mW).

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一种用于谐振传感器的低功耗双向前端控制系统

在本文中，我们提出了一个数字控制系统，以实现谐振传感器双向前端的自动化操作。由于其简单性，控制系统具有功率保守性和紧凑性。双向前端功耗的主要来源是用于读出传感器的放大器。可以通过在振荡信号的几个周期后关闭放大器来节省功率，这足以检测传感器的谐振频率。该概念最初是通过在SPICE中使用AMS-350nm CMOS技术模型进行模拟来验证的。在PCB上用分立元件实现了原型，并在5V电源下进行了测试。将读取周期固定在10kHz，并采用RLC负载作为MEMS谐振传感器的模型。用于测试的RLC组件的值为100Ω， 270pF, 10mH。不支持休眠模式的前端标称功耗为1.7mW，而读取一个振荡周期的休眠模式将功耗降低至270µW(1.7mW的15.88%)。

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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来源期刊

2017 IEEE 14th International Conference on Networking, Sensing and Control (ICNSC)

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