OKOLI ARINZECHUKWU MIRACLE, ADIBOR LYDIA EGUONO, ONIYEMOFE MELODY URINRIN, ONYELA UDOCHUKWUKA

The rapid expansion of fifth-generation (5G) wireless networks demands antenna arrays with wide bandwidth, high gain, and efficient beamforming capabilities to facilitate ultra-high-definition video streaming, extensive Internet of Things (IoT) connectivity, and communications with minimal latency. Nevertheless, traditional microstrip patch antennas continue to face fundamental challen0ges, including limited bandwidth, strong mutual coupling in array configurations, and reduced radiation efficiency caused by dielectric and surface wave losses. These challenges hinder their suitability for high-performance 5G applications. This project presents the design and simulation of a 4×4 microstrip patch antenna array optimized for sub-6GHz 5G applications. The Rogers 4350B substrate is utilized because of its low-loss characteristics and stable dielectric properties. To improve performance, U-shaped slots are added to the radiating elements, and a Defected Ground Structure (DGS) is incorporated into the ground plane. The design, analysis, and optimization of the antenna are carried out using ANSYS HFSS, focusing on achieving wide impedance bandwidth, high gain, and improved inter-element isolation without physical fabrication. The selection of materials, substrate parameters, and design dimensions are carefully chosen to facilitate future fabrication and experimental validation. Simulation results show that the proposed antenna achieves a gain of 10.64dB, a bandwidth of 180MHz, radiation efficiency of 72.3%, and a return loss (S11) of –19.96dB at 3.5GHz. In comparison, the conventional 4×4 array of the same dimensions without slots and DGS recorded a gain of 10.31dB, no substantial bandwidth as the return loss at the resonance frequency, 3.5GHz, is above the -10dB line, efficiency of 64.39%. The observed improvements are primarily attributed to the DGS, which effectively suppresses surface waves, minimizes mutual coupling, and enhances current distribution uniformity across the array. Overall, the optimized DGS-based antenna demonstrates superior performance in terms of gain, bandwidth, and element isolation, making it a strong candidate for compact and efficient sub-6GHz 5G base station and user terminal applications. The findings of this study provide a useful framework for further research and practical realization of high-performance antenna arrays for next-generation wireless communication systems.

The rapid expansion of fifth-generation (5G) wireless networks demands antenna arrays with wide bandwidth, high gain, and efficient beamforming capabilities to facilitate ultra-high-definition video streaming, extensive Internet of Things (IoT) connectivity, and communications with minimal latency. Nevertheless, traditional microstrip patch antennas continue to face fundamental challen0ges, including limited bandwidth, strong mutual coupling in array configurations, and reduced radiation efficiency caused by dielectric and surface wave losses. These challenges hinder their suitability for high-performance 5G applications. This project presents the design and simulation of a 4×4 microstrip patch antenna array optimized for sub-6GHz 5G applications. The Rogers 4350B substrate is utilized because of its low-loss characteristics and stable dielectric properties. To improve performance, U-shaped slots are added to the radiating elements, and a Defected Ground Structure (DGS) is incorporated into the ground plane. The design, analysis, and optimization of the antenna are carried out using ANSYS HFSS, focusing on achieving wide impedance bandwidth, high gain, and improved inter-element isolation without physical fabrication. The selection of materials, substrate parameters, and design dimensions are carefully chosen to facilitate future fabrication and experimental validation. Simulation results show that the proposed antenna achieves a gain of 10.64dB, a bandwidth of 180MHz, radiation efficiency of 72.3%, and a return loss (S11) of –19.96dB at 3.5GHz. In comparison, the conventional 4×4 array of the same dimensions without slots and DGS recorded a gain of 10.31dB, no substantial bandwidth as the return loss at the resonance frequency, 3.5GHz, is above the -10dB line, efficiency of 64.39%. The observed improvements are primarily attributed to the DGS, which effectively suppresses surface waves, minimizes mutual coupling, and enhances current distribution uniformity across the array. Overall, the optimized DGS-based antenna demonstrates superior performance in terms of gain, bandwidth, and element isolation, making it a strong candidate for compact and efficient sub-6GHz 5G base station and user terminal applications. The findings of this study provide a useful framework for further research and practical realization of high-performance antenna arrays for next-generation wireless communication systems.