3D-printed wideband reflectarray antennas with mechanical beam-steering

This paper investigates the performance of 3D-printed dielectric reflectarray antennas (RAs) with wideband behavior and beam-steering capabilities. The designed unit cell consists of a single-layer dielectric element perforated with a square hole, whose side is used to control the local variation of...

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Bibliographic Details
Published in:International journal of microwave and wireless technologies 2024-02, Vol.16 (1), p.21-29
Main Authors: Massaccesi, Andrea, Beccaria, Michele, Bertana, Valentina, Marasso, Simone Luigi, Cocuzza, Matteo, Dassano, Gianluca, Pirinoli, Paola
Format: Article
Language:English
Subjects:
Antenna arrays
Antennas
Bandwidths
Beam steering
Broadband
Design
Direction of arrival
Effectiveness
Extremely high frequencies
Manufacturing
MMS 2022 Special Issue
Numerical analysis
Radiation
Reflectance
Three dimensional printing
Unit cell
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Summary:This paper investigates the performance of 3D-printed dielectric reflectarray antennas (RAs) with wideband behavior and beam-steering capabilities. The designed unit cell consists of a single-layer dielectric element perforated with a square hole, whose side is used to control the local variation of the reflection coefficient. The numerical analysis of the unit cell and of first $52\times52$ reflectarray working in Ka-band, whose scanning capabilities are tested just moving the feed along an arc, confirms that the unit cell has a stable behavior with respect to both the frequency and the direction of arrival of the incident field. In view of these promising capabilities, the proposed unit cell is used to design a bifocal reflectarray with the same size and working in the same frequency band of the first one. Its numerical characterization and the measurements of a prototype prove that the RA is able to provide less than 0.8 dB of gain losses over a scanning range of ±40∘ in the vertical plane, while the bandwidth varies between 13.5% and 28%, depending on the pointing direction. The obtained results demonstrate the effectiveness of the proposed approach and highlight the potential of 3D-printing technology for producing high performance, cost-effective RAs with wideband behavior and excellent beam-steering features.
ISSN:1759-0787
1759-0795
DOI:10.1017/S1759078723000776