Energized IOT Sensor through RF Harvesting Energy

Int. J. Online Biomed. Eng. Pub Date : 2022-07-11 DOI:10.3991/ijoe.v18i09.30839

Mohamed Zied Chaari, Rashid Al-Rahimi, O. Aghzout

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Abstract

Wireless Power Collecting (WPC) present the future in powering and energizing intelligent Internet of Things (IoT) electronics devices. This chapter studies and utilizes a circuit to powering wirelessly IoT devices. The WPC offer a best technique to help researchers and engineers of modern societies to build cell blocks. The concept is to energy any IoT devices and sensors wirelessly from Radio Frequency (RF) power strength in the same areas that may be hard to achieve or potentially hazardous. We implemented the RF harvesting technology with IoT devices to increase the efficiency of sensors. The idea of this system is to power up and self-energize any IoT sensors wirelessly. This work studies two different topologies of a rectangular patch antenna and different RF harvesting circuit voltage multiplier configurations using a microwave power station as the input RF source. This work aims to utilize the wireless power transmission technique in the smart house solution. The proposed prototype gets all technical parameters to generate enough electricity to power up the bulbs 5 W wirelessly at a gap distance around a five meters. Finally, we test the RF rectifier circuit coupled with a twin patch antenna that can self-energize the bulb, eventually devices work without batteries.

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通过射频收集能量为物联网传感器供电

无线电力收集(WPC)为智能物联网(IoT)电子设备供电和充电提供了未来。本章研究并利用电路为无线物联网设备供电。WPC提供了一种最好的技术来帮助现代社会的研究人员和工程师构建细胞块。该概念是通过射频(RF)功率强度在可能难以实现或具有潜在危险的同一区域以无线方式为任何物联网设备和传感器供电。我们在物联网设备上实施了射频采集技术，以提高传感器的效率。该系统的理念是通过无线方式为任何物联网传感器供电和自供电。本文研究了矩形贴片天线的两种不同拓扑结构和使用微波电站作为输入射频源的不同射频采集电路电压乘法器配置。本工作旨在将无线电力传输技术应用于智能家居解决方案中。这个提议的原型具备了所有的技术参数，可以产生足够的电力，在大约5米的距离上为灯泡无线供电5w。最后，我们测试了射频整流电路与双贴片天线相结合，可以自激灯泡，最终设备无需电池即可工作。

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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Int. J. Online Biomed. Eng.

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