Beamwidth Enhancement of Microstrip Antennas Using Capacitive Via-Fence Loading

In this paper, a general approach to enhance the beamwidth of microstrip antennas is proposed for wide beam coverage in both E- and H-planes. A microstrip antenna loaded with two arrays of capacitive via fences is propounded and systematically studied. By introducing the vertical currents brought by the capacitive metalized vias, the half-power beamwidth (HPBW) is effectively broadened compared with the regular microstrip antennas. In addition, by utilizing the air medium with low loss, the microstrip antenna can be supported by the two arrays of via fences, maintaining a high radiation efficiency. To validate the proposed design, a prototype is fabricated and tested. The measurement results agree well with the simulated ones, with enhanced HPBWs of 100(degrees) and 90(degrees) in E- and H-planes, respectively. Compared with the existing 2.4-GHz antennas, the propounded antenna is with the advantages of wide beamwidth and high radiation efficiency, exhibiting the potential applications for space-limited mobile devices with wide coverage requirement.

Automated summary

This paper proposes a general approach to enhance the beamwidth of microstrip antennas for wide beam coverage in both E- and H-planes. By introducing vertical currents brought by capacitive metalized vias, the half-power beamwidth (HPBW) is effectively broadened compared to regular microstrip antennas. In addition, the use of low-loss air medium and two arrays of via fences allows for high radiation efficiency. A fabricated and tested prototype validates the proposed design, showing enhanced HPBWs of 100(degrees) and 90(degrees) in E- and H-planes, respectively. Compared to existing 2.4-GHz antennas, the proposed antenna offers the advantages of wide beamwidth and high radiation efficiency, making it suitable for space-limited mobile devices with wide coverage requirements.