5G网络中物联网设备的能量收集解决方案

Maryam Eshaghi, R. Rashidzadeh
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引用次数: 5

摘要

随着第五代(5G)无线技术的成熟和更广泛的采用,物联网(IoT)和物联网应用将经历显着增长。如何为数十亿低功耗无线物联网设备供电,引发了人们对能量收集的新兴趣。5G技术将为设计电路提供新的机会,以有效地从毫米波中提取能量,为物联网设备供电。本文采用兼容5G技术的先进设计系统(Advanced Design System, ADS)设计并仿真了一种能量收集电路。设计并实现了一种在11.02 GHz工作时回波损耗为- 17.35 dB的微带贴片天线。使用肖特基二极管的整流器也被设计成在高频下工作。仿真结果表明,该方案可以从11.02 GHz的入射波中提取能量,并在物联网传感器上产生1.18 V的能量,效率为87%。
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An Energy Harvesting Solution for IoT Devices in 5G Networks
Internet of Things (IoT) and IoT applications will experience significant growth as the fifth-generation (5G) of wireless technology matures and becomes more widely adopted. How to power on billions of low power wireless IoT devices has initiated a new interest in energy harvesting. The 5G technology will open new opportunities to design circuits to efficiently extract energy from millimeter waves to power on IoT devices. In this paper, an energy harvesting circuit is designed and simulated using Advanced Design System (ADS) which is compatible with 5G technology. A microstrip patch antenna with −17.35 dB return loss at 11.02 GHz is designed and implemented. A rectifier using a Schottky diode is also designed to operate at high frequencies. Simulation results indicate that the proposed solution can extract energy from incoming waves at 11.02 GHz and generate 1.18 V across an IoT sensor with an efficiency of 87%.
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