Ioannis D. Bougas scite author profile

The exigency for continuous use of electrical devices has created greater demands for electricity along with more efficient transmission techniques. Energy from natural resources can be solar, thermal, vibration, friction, or Radio Frequencies (RF) signals. This state-of-the-art work provides a summary of RF energy harvesting techniques and can be used as a guide for the manufacture of RF energy scavenging modules. The use of Radio Frequency (RF) Energy Harvesting (EH) technique contributes to the development of autonomous energy devices and sensors. A rectenna system includes three main units: the receiving antenna, the impedance matching network, and the rectifier. We thoroughly analyze how to design a rectenna system with special emphasis given on the design of the rectifier. At the same time many works of the last 10 years are presented. This review article categorizes the used topologies depending on the type of antennas, IMNs, and rectifiers and comparatively presents their advantages and disadvantages.

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State-of-the-Art Technologies in RF Energy Harvesting Circuits – A Review

Bougas

Papadopoulou

Psannis

et al. 2020

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Rectifier circuit design for 5G energy harvesting applications

Bougas

Sarigiannidis

Papadopoulou

et al. 2022

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Dual-Band Rectifier Circuit Design for IoT Communication in 5G Systems

et al. 2023

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Radio-frequency (RF) energy harvesting (EH) is emerging as a reliable and constantly available free energy source. The primary factor determining whether this energy can be utilized is how efficiently it can be collected. In this work, an RF EH system is presented. More particularly, we designed a dual-band RF to DC rectifier circuit at sub-6 GHz in the 5G bands, able to supply low-power sensors and microcontrollers used in agriculture, the military, or health services. The system operates at 3.5 GHz and 5 GHz in the 5G cellular network’s frequency band FR1. Numerical results reveal that the system provides maximum power conversion efficiency (PCE) equal to 53% when the output load (sensor or microcontroller) is 1.74 kΩ and the input power is 12 dBm.

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Ioannis D. Bougas

State-of-the-Art Techniques in RF Energy Harvesting Circuits

State-of-the-Art Technologies in RF Energy Harvesting Circuits – A Review

Rectifier circuit design for 5G energy harvesting applications

Dual-Band Rectifier Circuit Design for IoT Communication in 5G Systems

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