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High-Gain Microstrip Patch Antenna Array Using Artificial Magnetic Conductor Structures

Array Antena Patch Mikrostrip Gain Tinggi Menggunakan Struktur Konduktor Magnetik Buatan 4o Section Engineering
Vol 10 No 1 (2025): June (In Progress):
DOI : https://doi.org/10.21070/acopen.10.2025.10880
Published : May 3, 2025

Saba F. Ahmed Jaf (1), Amenah Edrees Kanaan (2)

(1) University of Kirkuk, College of Engineering, Kirkuk, Iraq
(2) University of Ninevah, College of Electronics engineering, Musel, Iraq
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Abstract:

General background: Microstrip patch antennas (MSPAs) are widely applied in wireless communication due to their compactness, low cost, and ease of fabrication. Specific background: Recent technological advancements have focused on enhancing MSPA performance for applications in Wi-Fi, radar, and medical implantable devices. Knowledge gap: However, optimizing antenna gain while minimizing return loss across varied array configurations and frequencies remains insufficiently explored. Aims: This study aims to design and analyze 1, 2×2, 3×3, and 4×4 MSPA arrays operating at 10 GHz and 13 GHz using the HFSS simulator, comparing their return loss and gain performance. Results: The optimized 4×4 MSPA array demonstrated a maximum gain of 14.5 dBi with a 17% radiation efficiency improvement and reduced back-lobe radiation, outperforming conventional designs. Novelty: Incorporation of artificial magnetic conductor (AMC) units into the array structure significantly enhanced gain, directivity, and front-to-back ratio while maintaining a low-profile configuration, simplifying fabrication. Implications: These findings provide a systematic approach to optimizing MSPA arrays, offering practical benefits for applications in next-generation wireless systems, radar technologies, and biomedical devices.


Highlights:


 




  1. Optimized Design: AMC boosts gain and minimizes return loss.




  2. Broad Application: Supports Wi-Fi, radar, and medical devices.




  3. Easy Fabrication: Low-profile antenna simplifies manufacturing process.




 


Keywords: Microstrip Patch Antenna, HFSS Simulation, Antenna Array, Artificial Magnetic Conductor, Gain Enhancement

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