3D Printed Directive Beam-Steering Antenna Based on Gradient Index Flat Lens With an Integrated Polarizer for Dual Circular Polarization at W-Band

In this communication, the design of a circularly polarized (CP) perforated gradient index (GRIN) flat lens antenna with directive beam-steering properties is presented for millimeter-wave applications at W-band (75-95 GHz). The dielectric lens, fed by an open-ended square waveguide (SWG) located in the lens focal plane, enhances the radiation in a particular direction, generating a high-directivity beam with planar wavefront. The integration of a dielectric polarizer with the lens allows the conversion from a linearly polarized (LP) incident wave to a CP-emitted wave over the whole bandwidth. Horizontally and vertically polarized waves, achieved by the excitation of the fundamental SWG TE01 and TE10 modes are transformed into left-hand CP and right-hand CP waves, respectively. A +/- 30?degrees scan range in both azimuth and elevation planes is demonstrated for the whole frequency range, attained by displacing the feed along the focal plane of the lens. Lens and polarizer are manufactured as a single piece by stereolithography (SLA) 3-D printing technology with Form 3 Formlabs 3-D-printer. Measured results show maximum measured directivity values that range from 23.5 to 23.8 dB, a remarkable circular polarization purity as a wide axial ratio bandwidth of 20.58% (< 3 dB), from 77.5 to 95 GHz, is achieved for the principal beam steers and an aperture efficiency for broadside beam direction between 90.32% and 57.34% in the frequency band of interest.

Automated summary

This paper presents a design of a circularly polarized perforated gradient index (GRIN) flat lens antenna with directive beam-steering properties for millimeter-wave applications. The lens, fed by an open-ended square waveguide (SWG), enhances radiation in a specific direction and generates a high-directivity beam with planar wavefront. The integration of a dielectric polarizer allows the conversion of a linearly polarized incident wave to a circularly polarized emitted wave. The lens and polarizer are manufactured using stereolithography (SLA) 3-D printing technology, and the measured results demonstrate a wide axial ratio bandwidth of 20.58% and an aperture efficiency ranging from 57.34% to 90.32%.