Quality factors) is measured without and with plasma. Experimentally, the return loss of the sources (hence their Produced, using a fluid-type code to describe the dynamics of charged SimulationsĪnalyze the electromagnetic behavior of the sources, using the commercial The study of the sources follows aĬomplementary approach that uses simulation and experiment. In both sources, micro-plasmas are produced within the 50–200 \(\mu \)m gapĬreated between two metal electrodes placed at the open end of a Planar transmission line configuration, corresponding to linear resonators. The designed antenna structure is planar, simple and compact since it can be easily embedded for Wi-Fi applications, cellular phones and wireless communications for low manufacturing cost.In this paper, we study two microwave sources based on a Then, the simulation and measurement results were compared. The fabricated antenna was measured by the Vector Network Analyzer. After simulating with the CST software, the patch antenna was fabricated using the MITS milling machine on the FR-4 substrate in the YTU’s communication lab. The designed antenna has the realized gain of 3.42 dB at the resonant frequency of 2.397 GHz. The proposed antenna is the compact design of 28.2842mm 48.2842mm area on the FR4-epoxy substrate with dielectric constant of 4.4 and thickness of 1.6. The designed microstrip patch antenna consists of a hexagonal patch which is found to be resonant at the frequency of 2.397 GHz with the return loss of -31.2118 dB having satisfactory radiation properties. And the work is the design of a Hexagonal shaped microstrip patch antenna which is presented for the wireless communication applications such as Wi-Fi in S-band. The proposed antenna may find applications in wireless local area network (Wi-Fi) and Bluetooth technology. The proposed MSA is fed by the coaxial probe. The substrate used for the proposed antenna is the flame resistant four (FR-4) with a dielectric constant of 4.4 and a loss tangent of 0.025. The simulation of the proposed antenna was done with the aid of the computer simulation technology (CST) microwave studio student version 2017. The aim of this work is to design the microstrip patch antenna for Wi-Fi applications which operates at 2.4 GHz. This research covers the study of basics and fundamentals of the microstrip patch antenna. In recent years, the inventions in communication systems require the design of low cost, minimal weight, compact and low profile antennas which are capable of main-taining high performance.
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