Linear arrays consisting of four probe-fed cylindrical dielectric resonator antennas

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

Probe-fed cylindrical dielectric resonator antennas CDRAs , with dielectric constant ⑀ s 37 and supported by an infinite ground plane, are simulated using the finite r element method. From this, closed form expressions are obtained for the resonant frequency, directivity, and unloaded Q-factor, appl

Two four-element linear aperture-coupled cylindrical dielectric resonator antenna arrays ha¨e been theoretically modeled and experimentally implemented. The arrays produced broadside radiation shaping the E-and H-plane, respecti¨ely. The resonant frequency, return loss, radiation pattern, gain, unlo

Figure 7 Attenuation in slow-wave structure w x This higher loss is due to the conductor loss 9 . The conductor loss for the slow wave can be incorporated in this formuw x lation 10 . ## 4. CONCLUSION Using the concept of SLR formulation, a unified CADoriented model for the multilayer slow-wave mi

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

The radiation chamcteristics of a parabolic cylindrical refictor antenna fed by a linear microstrip patch array operated at fi band are studied. CaLiiy model and physical optics approximations are used to analyze the patch array and the induced currents on the reflector surface, respectively. Radiat