This work focused on the design, characterization and investigation of GaAs based multi-layered compact 3D MMIC based antenna. Different patch antennas were designed and characterized along with its S-parameters. Two proposed models of multi-layered patch antenna using V-shaped feeder line and planar feeder line with a spiral transmission line in metal-2 were more compact in size and showed an improvement in performance based on bandwidth compared to the traditional planar feeder line configuration. This implies the proposed planar feed line with the spiral transmission is cost effective. The newly propose planar antenna with a spiral transmission feeder line is 49% more compact in area compared to using the normal planar feeder line. The new design also has wider bandwidth with a bandwidth of 2.99% as compared to the traditional planar with a bandwidth of 1.93%, better input return loss and a slightly lower resonance frequency. Similarly, another multilayer patch antenna was proposed using a V-shaped feeder line, This V-shaped feeder line antenna model showed a much lower resonance frequency (36.50 GHz) compared to normal planar (38.92GHz) and the planar with spiral transmission line model (38.52 GHz).
%0 Journal Article
%1 habeeb_bello_2023_8285312
%A Bello, Habeeb
%A Nazifi, Khalid Idris
%A Sadiq, Sanusi Mohammed
%D 2023
%J Global Journal of Engineering and Technology Advances
%K 3-D MMICs
%N 3
%P 096–106
%R 10.30574/gjeta.2023.15.3.0109
%T Investigation and design methods of a compact patch antennas using 3-D MMIC for various applications
%U https://gjeta.com/content/investigation-and-design-methods-compact-patch-antennas-using-3-d-mmic-various-applications
%V 15
%X This work focused on the design, characterization and investigation of GaAs based multi-layered compact 3D MMIC based antenna. Different patch antennas were designed and characterized along with its S-parameters. Two proposed models of multi-layered patch antenna using V-shaped feeder line and planar feeder line with a spiral transmission line in metal-2 were more compact in size and showed an improvement in performance based on bandwidth compared to the traditional planar feeder line configuration. This implies the proposed planar feed line with the spiral transmission is cost effective. The newly propose planar antenna with a spiral transmission feeder line is 49% more compact in area compared to using the normal planar feeder line. The new design also has wider bandwidth with a bandwidth of 2.99% as compared to the traditional planar with a bandwidth of 1.93%, better input return loss and a slightly lower resonance frequency. Similarly, another multilayer patch antenna was proposed using a V-shaped feeder line, This V-shaped feeder line antenna model showed a much lower resonance frequency (36.50 GHz) compared to normal planar (38.92GHz) and the planar with spiral transmission line model (38.52 GHz).
@article{habeeb_bello_2023_8285312,
abstract = {This work focused on the design, characterization and investigation of GaAs based multi-layered compact 3D MMIC based antenna. Different patch antennas were designed and characterized along with its S-parameters. Two proposed models of multi-layered patch antenna using V-shaped feeder line and planar feeder line with a spiral transmission line in metal-2 were more compact in size and showed an improvement in performance based on bandwidth compared to the traditional planar feeder line configuration. This implies the proposed planar feed line with the spiral transmission is cost effective. The newly propose planar antenna with a spiral transmission feeder line is 49% more compact in area compared to using the normal planar feeder line. The new design also has wider bandwidth with a bandwidth of 2.99% as compared to the traditional planar with a bandwidth of 1.93%, better input return loss and a slightly lower resonance frequency. Similarly, another multilayer patch antenna was proposed using a V-shaped feeder line, This V-shaped feeder line antenna model showed a much lower resonance frequency (36.50 GHz) compared to normal planar (38.92GHz) and the planar with spiral transmission line model (38.52 GHz).},
added-at = {2023-09-15T16:04:09.000+0200},
author = {Bello, Habeeb and Nazifi, Khalid Idris and Sadiq, Sanusi Mohammed},
biburl = {https://www.bibsonomy.org/bibtex/2ba7ecc67de51f16a0da58b8c1f9e254a/gjetajournal},
doi = {10.30574/gjeta.2023.15.3.0109},
interhash = {d0b571109c486044e7bc0aa402554d12},
intrahash = {ba7ecc67de51f16a0da58b8c1f9e254a},
issn = {2582-5003},
journal = {{Global Journal of Engineering and Technology Advances}},
keywords = {3-D MMICs},
month = jun,
number = 3,
pages = {096–106},
timestamp = {2023-09-15T16:04:09.000+0200},
title = {Investigation and design methods of a compact patch antennas using 3-D MMIC for various applications},
url = {https://gjeta.com/content/investigation-and-design-methods-compact-patch-antennas-using-3-d-mmic-various-applications},
volume = 15,
year = 2023
}