Adiabatic Floquet-Wave Expansion for the Analysis of Leaky-Wave Holograms Generating Polarized Vortex Beams

TL;DR

This paper introduces an efficient theoretical method combining aperture field estimation and Floquet-wave expansion to analyze large leaky-wave holograms generating polarized vortex beams with reduced computational resources.

Contribution

It develops a novel combined analytical approach for leaky-wave hologram analysis that simplifies computation and enables the design of complex vortex beams with polarization control.

Findings

The method accurately predicts vortex beam properties.

Isotropic and anisotropic unit cells are compared, showing anisotropic structures perform better.

Theoretical results agree well with full-wave simulations.

Abstract

This paper presents the combination of aperture field estimation (AFE) technique and adiabatic Floquet-wave (AFW) expansion method for the analysis of leaky-wave holograms capable of generating orbital angular momentum (OAM) vortex waves. In these formulations the propagation and leakage constants are theoretically estimated and as a result the aperture field and far-zone field are calculated. This theoretical approach significantly reduces the computational complexity in such a way that the analysis of holograms with large dimensions is possible with low memory requirements. Isotropic and anisotropic unit cells are used to realize the holograms, which anisotropic structures show better performance in the control of wave polarization. The holograms are designed to generate vortex beams with topological charge of m=2 and circular polarization states in the microwave regime. To evaluate the accuracy of the proposed method, the results of theoretical model and full-wave simulations are compared, with good agreement.