Bandwidth enhancement of a microstrip antenna with embedded reactive loading

No¨el dual-frequency operation of a single-feed rectangular microstrip antenna with an embedded reacti¨e loading is presented. The reacti¨e loading is pro¨ided by a structure of two cascaded microstrip-line sections embedded within a rectangular slot cut in the patch. By selecting suitable dimension

By integrating a microstrip structure of cascaded microstrip-line sections into a bow-tie microstrip path, compact broadband operation of microstrip antennas can be obtained. The cascaded microstrip-line sections ser¨e as a reacti¨e load for the bow-tie patch, and its optimal dimensions for broadban

A design of broadband circular microstrip antenna with embedded reacti¨e loading directly matched to a 50 ⍀ microstrip feed line is presented. This design is achie¨ed owing to the integrated reacti¨e loading, a T-shaped microstrip-line section embedded in a nearly rectangular slot cut near the patch

are used to check the accuracy of the measurement technique. A good agreement between the measured dielectric constant and the reported one is observed. The results show that the dielectric constant of the material can be measured using the waveguide cavities with a good accuracy. REFERENCES 1. L.P.

Experimental and simulation results of a coaxially fed U-slot microstrip antenna stacked with a rectangular patch are presented. Results include impedance bandwidth, copolar and cross-polar radiation patterns, and gain.

The stacked structure of an aperture-coupled cylindrical ( ) dielectric resonator DR antenna is studied experimentally. The effects of the offset and the air gap between the dri¨en and parasitic DR elements are in¨estigated. It is found that the bandwidth of the stacked structure can increase from t