Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band

A dielectric resonator antenna via substrate-integrated coplanar waveguide is proposed and analyzed as a fed mechanism for N78 5G bands. SICPW as a transmission line structure integrating coplanar waveguides and substrate integration techniques offers high gain, wide bandwidth, and low losses. This...

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Published in:Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024
Main Author: Abdullah R.; Ja'afar H.; Jamaluddin M.H.; Jaafar A.N.; Akhbar R.; Sedeghikia F.
Format: Conference paper
Language:English
Published: Institute of Electrical and Electronics Engineers Inc. 2024
Online Access:https://www.scopus.com/inward/record.uri?eid=2-s2.0-85197122508&doi=10.1109%2fICASI60819.2024.10547798&partnerID=40&md5=7b4506bb7dd7077df5291a825a8b2fc6
id 2-s2.0-85197122508
spelling 2-s2.0-85197122508
Abdullah R.; Ja'afar H.; Jamaluddin M.H.; Jaafar A.N.; Akhbar R.; Sedeghikia F.
Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
2024
Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024


10.1109/ICASI60819.2024.10547798
https://www.scopus.com/inward/record.uri?eid=2-s2.0-85197122508&doi=10.1109%2fICASI60819.2024.10547798&partnerID=40&md5=7b4506bb7dd7077df5291a825a8b2fc6
A dielectric resonator antenna via substrate-integrated coplanar waveguide is proposed and analyzed as a fed mechanism for N78 5G bands. SICPW as a transmission line structure integrating coplanar waveguides and substrate integration techniques offers high gain, wide bandwidth, and low losses. This antenna has a $50\ \Omega$ input impedance and operates via SICPW power. Operating at 3.5 GHz with an impedance bandwidth of approximately 8.9% and 8.01 dBi gain, the antenna exhibits a favorable reflection coefficient (>10 dB) in the desired frequency. The proposed antenna is feasible for future 5G applications. © 2024 IEEE.
Institute of Electrical and Electronics Engineers Inc.

English
Conference paper

author Abdullah R.; Ja'afar H.; Jamaluddin M.H.; Jaafar A.N.; Akhbar R.; Sedeghikia F.
spellingShingle Abdullah R.; Ja'afar H.; Jamaluddin M.H.; Jaafar A.N.; Akhbar R.; Sedeghikia F.
Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
author_facet Abdullah R.; Ja'afar H.; Jamaluddin M.H.; Jaafar A.N.; Akhbar R.; Sedeghikia F.
author_sort Abdullah R.; Ja'afar H.; Jamaluddin M.H.; Jaafar A.N.; Akhbar R.; Sedeghikia F.
title Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
title_short Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
title_full Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
title_fullStr Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
title_full_unstemmed Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
title_sort Dielectric Resonator Antenna Via Substrate Integrated Coplanar Waveguide Feed Mechanism for the N78 5G Band
publishDate 2024
container_title Proceedings of the 2024 10th International Conference on Applied System Innovation, ICASI 2024
container_volume
container_issue
doi_str_mv 10.1109/ICASI60819.2024.10547798
url https://www.scopus.com/inward/record.uri?eid=2-s2.0-85197122508&doi=10.1109%2fICASI60819.2024.10547798&partnerID=40&md5=7b4506bb7dd7077df5291a825a8b2fc6
description A dielectric resonator antenna via substrate-integrated coplanar waveguide is proposed and analyzed as a fed mechanism for N78 5G bands. SICPW as a transmission line structure integrating coplanar waveguides and substrate integration techniques offers high gain, wide bandwidth, and low losses. This antenna has a $50\ \Omega$ input impedance and operates via SICPW power. Operating at 3.5 GHz with an impedance bandwidth of approximately 8.9% and 8.01 dBi gain, the antenna exhibits a favorable reflection coefficient (>10 dB) in the desired frequency. The proposed antenna is feasible for future 5G applications. © 2024 IEEE.
publisher Institute of Electrical and Electronics Engineers Inc.
issn
language English
format Conference paper
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record_format scopus
collection Scopus
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