Analysis of a Waveguide-Fed Metasurface Antenna

TL;DR

This paper analyzes a waveguide-fed metasurface antenna that achieves reconfigurability through resonance shifts of metamaterial elements, offering a simpler alternative to phased arrays for beamforming and wavefront shaping.

Contribution

It derives analytical models for a 1D waveguide-fed metasurface antenna, including array factors and polarizabilities, validated by full-wave simulations, without requiring active phase shifters.

Findings

Analytical expressions for array factors and polarizabilities.

Validation of models through full-wave simulations.

Demonstration of reconfigurability via resonance shifts.

Abstract

The metasurface concept has emerged as an advantageous reconfigurable antenna architecture for beam forming and wavefront shaping, with applications that include satellite and terrestrial communications, radar, imaging, and wireless power transfer. The metasurface antenna consists of an array of metamaterial elements distributed over an electrically large structure, each subwavelength in dimension and with subwavelength separation between elements. In the antenna configuration we consider here, the metasurface is excited by the fields from an attached waveguide. Each metamaterial element can be modeled as a polarizable dipole that couples the waveguide mode to radiation modes. Distinct from the phased array and electronically scanned antenna (ESA) architectures, a dynamic metasurface antenna does not require active phase shifters and amplifiers, but rather achieves reconfigurability by shifting the resonance frequency of each individual metamaterial element. Here we derive the basic properties of a one-dimensional waveguide-fed metasurface antenna in the approximation that the metamaterial elements do not perturb the waveguide mode and are non-interacting. We derive analytical approximations for the array factors of the 1D antenna, including the effective polarizabilities needed for amplitude-only, phase-only, and binary constraints. Using full-wave numerical simulations, we confirm the analysis, modeling waveguides with slots or complementary metamaterial elements patterned into one of the surfaces.