Abstract

Microstrip antennas possess a compact form factor, exhibit a low profile, and demonstrate a lightweight nature, thereby enabling their suitability for deployment on both planar and non-planar surfaces. When the framework is installed, it requires a comparatively small amount of space. The production of printed circuits has become a facile and inexpensive process owing to advancements in contemporary technology. Antennas with a low profile are often required owing to space, weight, cost, performance, simplicity of installation, and aerodynamic profile in powerful planes, spaceships, satellites, and rocket operations. Many other applications, not only mobile radio and wireless communications, have comparable requirements. Microstrip antennas are a useful tool for accomplishing this goal. A proposal has been put forth to utilize a patch antenna for 5G cellular connectivity at 28 GHz, with the aim of generating robust beams on the azimuthal plane. The antenna proposed in this study exhibits a radiation efficiency of 93.46 percent and a total efficiency of 92.80 percent, as demonstrated through simulations. This study showcases the feasibility of producing millimeter-wave antennas operating at 28 GHz through the utilization of cost-effective additive manufacturing techniques. The simulation of all outcomes is conducted through the utilization of the CST Microwave Studio.

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