Modelling of probe-fed cylindrical dielectric resonator antennas

In this study, we report two four-element linear broadside arrays shaping the E and E field components. The radiating elements are probe-fed cylindrical dielectric resonator antennas. The arrays are analytically formulated, numerically simulated, and experimentally tested. The resonant frequency, ra

Three four-element planar arrays, with the radiating elements being cylindrical dielectric resonator antennas excited by probes at the HE mode, are reported. The first array produces broadside radia-11␦ tion, whereas the other two pro¨ide maximum radiation at ele¨ation angles of ; 35᎐40Њ. The resona

## Ž . impedance profile and WrH ratio are plotted in Figure Ž . and c , respectively. The approximate Q-function used in the examples above reduces the convergence speed, and the results considerably depend on the device length. However, the present method enhances the degree of freedom in desi

structures with more than one port, including active elements, and to realize an extremely simple yet efficient combination of an oscillator integrated within an antenna. It has been proven that the design frequency could be attained without any tuning, by directly using the structure dimensions res

The characteristics of the dielectric resonator antenna top loaded by a circular conducting disk with different diameters is studied experimentally. It is found that antenna parameters such as the resonant frequency, the input impedance, and the far-field radiation pattern, are affected tremendously

A comparison with the case of a dielectric nondispersive w x cluster 8 when the shift of the value of the plasma cluster velocity corresponding to the maximum reflectivity of the electromagnetic wave in the waveguide ␤ is lacking shows 1 that the shift of the reflectivity maximum to smaller values o