Performance of hemielliptic dielectric lens antennas with optimal edge illumination

TL;DR

This paper investigates how edge illumination affects the performance of compact dielectric lens antennas, demonstrating that optimal edge illumination improves directivity depending on material and polarization.

Contribution

It introduces an accurate analysis method for dielectric lens antennas considering finite size and directive feeds, highlighting the importance of optimal edge illumination for performance enhancement.

Findings

Proper edge illumination maximizes antenna directivity.

Optimal edge illumination depends on lens material and feed polarization.

Analysis accounts for finite lens size and directive feeds.

Abstract

The role of edge illumination in the performance of compact-size dielectric lens antennas (DLAs) is studied in accurate manner using a highly efficient algorithm based on the combination of the Muller boundary integral equations and the method of analytical regularization. The analysis accounts for the finite size of the lens and directive nature of the primary feed placed close to the center of the lens base. The problem is solved in a two-dimensional formulation for both E- and H-polarizations. It is found that away from internal resonances that spoil the radiation characteristics of DLAs made of dense materials, the edge illumination has primary importance. The proper choice of this parameter helps maximize DLA directivity, and its optimal value depends on the lens material and feed polarization. Index Terms: Beam collimation, dielectric lens antenna, directivity improvement, edge illumination, edge taper, hemielliptic lens.