带压电纳米级超声换能器的远程超声唤醒接收器

2020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS) Pub Date : 2020-01-01 DOI:10.1109/MEMS46641.2020.9056287

Pietro Simeoni, Matteo Castellani, G. Piazza

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引用次数: 3

摘要

我们报告了远程唤醒接收器(WuRx)的第一个实现，该接收器由一个积极缩放的100纳米厚氮化铝传感器实现，该传感器仅占用$100\ \mu \ mathm {m}\ \乘以\ 100\ \mu \ mathm {m}$的面积。这种压电纳米级超声换能器(pNUT)提供了与微级同类产品相同的灵敏度和特性阻抗，但由于其尺寸显着减小，因此可以实现“粉尘状”的WuRx。我们通过使用pNUT和现成的电子元件合成WuRx来验证这一概念，这些电子元件组成了电压放大器、包络检测器和比较器(图1)。我们展示了在以250Hz调制的40 kHz载波信号下工作时，在0.5 m范围内的稳健数据传输。根据这些测量结果，我们推断出设备在共振时的性能，表明在不增加WuRx面积的情况下，通信超过10米是可能的。

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Long-Rangeultrasound Wake-Up Receiver with a Piezoelectric Nanoscale Ultrasound Transducer (pNUT)

We report on the first implementation of a long-range wake-up receiver (WuRx) enabled by an aggressively scaled 100 nm thick aluminum nitride transducer that occupies an area of only $100\ \mu \mathrm{m}\ \times\ 100\ \mu \mathrm{m}$. This piezoelectric Nanoscale Ultrasound Transducer (pNUT) offers the same sensitivity and characteristic impedance of its microscale counterparts but enables “dust-like” WuRx because of its dramatically reduced size. We validate this concept by synthesizing a WuRx using a pNUT and off-the-shelf electronic components forming a voltage amplifier, an envelope detector and a comparator (Fig. 1). We demonstrate robust data transfer over a range of 0.5 m when operating with a 40 kHz carrier signal modulated at 250Hz. Based on these measurements we extrapolate the device performance at resonance to show that communication over> 10m is possible without increasing the WuRx area.

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来源期刊

2020 IEEE 33rd International Conference on Micro Electro Mechanical Systems (MEMS)

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