A 5.7GHz RF Wireless Power Transfer Receiver Using 84.5% Efficiency 12V SIDO Buck-Boost DC-DC Converter with Internal Power Supply Mode

2021 IEEE Asian Solid-State Circuits Conference (A-SSCC) Pub Date : 2021-11-07 DOI:10.1109/A-SSCC53895.2021.9634794

Tomohiro Higuchi, D. Suzuki, R. Ishida, Y. Isshiki, Kazuki Arai, Kohei Onizuka, K. Miyaji

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引用次数: 1

Abstract

Power supply to the sensors in an IoT-era is a major concern because the number of sensors are so enormous that environmental loads and costs will be huge if wires are used. Also, battery exchange is unacceptable in many cases. RF wireless power transfer (WPT) system is a good solution for the remote power sources with a distance longer than a few meters. Figure 1 shows the 5.7GHz RFWPT system and its specification considered in this work. The TX power is controlled by beamforming using 5.7GHz frequency to reduce beam width and antenna size. The TX-RX distance ranges from 1 to 10m, thus RX RF input power PIN varies from -3 to nearly up to 30dBm $(500 \mu W \sim 1W)$. The maximum PIN is much higher than that of the typical RF energy harvesting systems can handle [1–4]. To supply multiple RX sensor nodes with a single TX module, time-division power supply is used. For such WPT system, input voltage of the DC-DC converter $(V_{IN_DC})$ needs to cover up to 10V, since the open circuit voltage VOC of the rectifier exceeds 10V at $P_{IN}=30$ dBm. On the other hand, power consumption of the controller circuit should be small to be efficient at low PIN. Furthermore, the DC-DC converter should be kept alive when there is no RF input. This interruption may last a few ms to a few seconds.

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基于84.5%效率12V SIDO Buck-Boost DC-DC转换器的5.7GHz射频无线功率传输接收器

在物联网时代，传感器的供电是一个主要问题，因为传感器的数量如此之大，如果使用电线，环境负荷和成本将是巨大的。此外，在许多情况下，更换电池是不可接受的。射频无线电力传输(WPT)系统是一个很好的解决方案，远端电源的距离超过几米。图1显示了5.7GHz RFWPT系统及其在本工作中考虑的规范。通过5.7GHz频率的波束成形控制传输功率，减小波束宽度和天线尺寸。TX-RX距离范围为1 ～ 10m，因此RX射频输入功率PIN从-3到近30dBm $(500 \mu W \sim 1W)$。最大PIN值远高于典型射频能量收集系统所能处理的PIN值[1-4]。为了用一个TX模块为多个RX传感器节点供电，采用时分电源。对于这种WPT系统，DC-DC变换器$(V_{IN_DC})$的输入电压需要覆盖到10V，因为整流器的开路电压VOC在$P_{IN}=30$ dBm时超过10V。另一方面，控制器电路的功耗要小，才能在低引脚时保持高效率。此外，当没有射频输入时，DC-DC转换器应保持活态。这种中断可能持续几毫秒到几秒钟。

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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2021 IEEE Asian Solid-State Circuits Conference (A-SSCC)

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