GCPW Microstrip Array Antenna for 6G Wireless Networks

What is it about?

This paper presents the design of a grounded coplanar waveguide (GCPW) microstrip array antenna with via-holes for operation beyond 100 GHz. The design was conducted using a 3D full-wave electromagnetic (EM) finite difference time domain (FDTD) solver at CST MWS. The paper discusses the simulation results for the bandwidth, working frequencies, peak gain, and peak directivity of the proposed antenna, which show promising results for 6G integrated vehicular autonomous and next-generation wireless communication networks. [Some of the content on this page has been created by AI]

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Why is it important?

The research is important for several reasons: It addresses the need for efficient and compact antenna designs for next-generation wireless communication networks, particularly 6G and integrated autonomous vehicular networks. The proposed GCPW microstrip array antenna design can potentially improve the performance of communication networks, providing higher data rates, lower latency, and better reliability. The research contributes to the ongoing effort to develop innovative antenna technologies that can support the growing demands of emerging applications and services in the IoT and B5G/6G environments. Key Takeaways: 1. The paper presents a design of a grounded coplanar waveguide (GCPW) microstrip array antenna with via-holes, suitable for beyond 100 GHz integrated vehicular autonomous and next-generation wireless communication networks at the sixth generation (6G). 2. The design was simulated using a 3D full-wave electromagnetic (EM) based on finite difference time domain (FDTD) at Computer Simulation Technology Microwave Studio (CST MWS), achieving a good agreement with the frequency-domain solver. 3. The simulated results of the proposed antenna showed a bandwidth (BW) of 24.22 GHz, working frequencies ranging from 107.41 to 133.54 GHz, peak gain of 12.1 dB, and peak directivity of 12.98 dBi. 4. The compact size and wide impedance bandwidth of the proposed antenna make it a promising candidate for 6G and 5G communication networks.