A C-band microwave rectenna using aperture-coupled antenna array and novel Class-F rectifier with cavity

TL;DR

This paper presents a high-efficiency C-band rectenna with a novel Class-F rectifier and aperture-coupled antenna array, achieving 72% MW-to-DC conversion efficiency through harmonic termination and cavity shielding techniques.

Contribution

It introduces a new Class-F rectifier design considering input harmonic control and a cavity shielding method, enhancing rectenna efficiency.

Findings

Achieved 72% MW-to-DC conversion efficiency.

Developed a 19.5 dBi aperture-coupled antenna array.

Implemented a defected ground structure low-pass filter.

Abstract

A rectenna (rectifying antenna) is usually applied to a microwave power transmission (MPT) system as a terminal, which receives microwave (MW) power and converts them into DC power. A 5.8 GHz aperture-coupled patch antenna array is developed with a gain of 19.5 dBi, which is a part of the rectenna. A novel Class-F rectifier with a series diode is proposed to achieve a high rectifying efficiency based on harmonic termination techniques. The input circuit of the proposed rectifier is taken into consideration to reach the Class-F condition, while mostly only the output circuit is involved in conventional Class-F designs. A low-pass filter based on defected ground structure is implemented, which not only blocks the harmonics produced in rectifying but also presents desired impedance at harmonics. The current and voltage waveforms on the diode are well enforced. The radiation feature of the rectifier is presented as well. It shows that an optimized cavity, which shields the parasite radiation, may achieve a 5% enhancement on the MW-to-DC conversion efficiency. A C-band rectifier based on HSMS-286 Schottky diode is fabricated and measured. A MPT simple demo system is constructed with the proposed rectifier and antenna. A measured maximum MW-to-DC conversion efficiency of 72% is achieved on the rectifier. The design method is extremely valuable in a high conversion efficiency rectenna design based on harmonic termination techniques.