Affan A. Baba scite author profile

A simple metasurface integrated with horn antenna exhibiting wide bandwidth, covering full Ku-band using 3D printing is presented. It consists of a 3D-printed horn and a 3D-printed phase transformation surface placed at the horn aperture. Considering the non-uniform wavefront of 3D printed horn, the proposed 3D-printed phase transformation surface is configured by unit cells, consisting of a cube in the centre which is supported by perpendicular cylindrical rods from its sides. Placement of proposed surface helps to improve the field over the horn aperture, resulting in lower phase variations. Both simulated and measured results show good radiation characteristics with lower side lobe levels in both E- and H-planes. Additionally, there is an overall increment in directivity with peak measured directivity up to 24.8 dBi and improvement in aperture efficiency of about 35% to 72% in the frequency range from 10–18 GHz. The total weight of the proposed antenna is about 345.37 g, which is significantly light weight. Moreover, it is a low cost and raid manufacturing solution using 3D printing technology.

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Aperture coupled Dielectric Resonator Antenna design with flat reflector

Ali

Zakariya

Baharudin

et al. 2013

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A single element circular slot aperture coupled Cylindrical Dielectric Resonator Antenna (CDRA) with a flat reflector is designed and presented. The measured bandwidth of the antenna is about 1.8 % (5.32 -5.52) while the simulated bandwidth is 1.11% (5.32 -5.44 GHz). A comprehensive parametric study has been conducted to realize the effects of slot size, slot position and reflector parameters to increase the directivity of the designed antenna. The experimental results show that the antenna covers 5 GHz band, which satisfies the basic requirement of the WLAN application IEEE 802.11a.

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Achieving a Large Gain-Bandwidth Product From a Compact Antenna

Baba

Hashmi

2017

IEEE Trans. Antennas Propagat.

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A Millimeter-Wave Antenna System for Wideband 2-D Beam Steering

Baba

Hashmi

Esselle

et al. 2020

IEEE Trans. Antennas Propagat.

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Aperture coupled Cylindrical Dielectric Resonator Antenna design with box shaped reflector

Ali

Zakariya

Baharudin

et al. 2013

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Affan A. Baba

A Horn Antenna Covered with a 3D-Printed Metasurface for Gain Enhancement

Aperture coupled Dielectric Resonator Antenna design with flat reflector

Achieving a Large Gain-Bandwidth Product From a Compact Antenna

A Millimeter-Wave Antenna System for Wideband 2-D Beam Steering

Aperture coupled Cylindrical Dielectric Resonator Antenna design with box shaped reflector

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