Experimental Characterization of Narrowband Power Optimized Waveforms

2019 IEEE Wireless Power Transfer Conference (WPTC) Pub Date : 2019-06-01 DOI:10.1109/WPTC45513.2019.9055570

T. Ikeuchi, Y. Kawahara, Joshua R. Smith

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引用次数: 1

Abstract

Low power devices driven by energy harvesting are limited in working range by transmit power restrictions. Power optimized waveforms (POWs) have been proposed as a way to achieve a longer working range without increasing average transmit power. In the ultra high frequency (UHF) band, bandwidth occupancy needs to be small enough to satisfy relevant regulations: thus the wideband POWs explored in some prior work may be less practical than narrowband POWs. This paper experimentally evaluates the performance of narrowband multi-sine based POWs, varying number of sines from 2 to 20 and occupied bandwidth of 10 kHz, 100 kHz, and 1 MHz-all narrowband from a regulatory perspective. Our key result is that additional sine waves improve voltage sensitivity, but not Power Conversion Efficiency. In our experiments, we observed the voltage sensitivity benefits of the multi-sine POWs to be most pronounced at a power level of -13 dBm; at signal levels significantly below (-30 dBm) or above (0 dBm) this level, their benefits diminish. Finally, we also observe that in a real system (the WISP 5.1, which includes a rectifier and DC-DC converter), voltage sensitivity is a much more complex function of waveform and signal power than in simpler idealized rectifiers. The sensitivity is a non-monotonic and complex function of the number of sines, occupied bandwidth, and signal strength.

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窄带功率优化波形的实验表征

能量收集驱动的低功率器件受发射功率限制，工作范围受到限制。功率优化波形(pow)是在不增加平均发射功率的情况下实现更长的工作范围的一种方法。在超高频(UHF)频段，带宽占用需要足够小以满足相关规定，因此一些先前工作中探索的宽带pow可能不如窄带pow实用。本文实验评估了基于多正弦的窄带pow的性能，从2到20的正弦数变化，占用的带宽为10 kHz, 100 kHz和1 mhz -从监管的角度来看都是窄带的。我们的关键结果是，额外的正弦波提高了电压灵敏度，但没有提高功率转换效率。在我们的实验中，我们观察到在-13 dBm的功率水平下，多正弦pow的电压灵敏度优势最为明显;当信号水平明显低于(- 30dbm)或高于(0dbm)这个水平时，它们的优势就会减弱。最后，我们还观察到，在实际系统(WISP 5.1，其中包括整流器和DC-DC转换器)中，电压灵敏度是波形和信号功率的复杂函数，而不是简单的理想整流器。灵敏度是正弦数、占用带宽和信号强度的非单调复函数。

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

2019 IEEE Wireless Power Transfer Conference (WPTC)

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