Near-Field Beam Focusing Characterization for 2D Waveguide-Fed Metasurface Antennas

TL;DR

This paper analyzes the near-field beam focusing of 2D waveguide-fed metasurface antennas, deriving scaling laws and beam-depth limits validated by electromagnetic simulations.

Contribution

It introduces a physics-compliant model and analytical expressions for beamforming gain and transition to far-field behavior in 2D metasurface antennas.

Findings

Beamforming gain scales linearly with the number of radiating elements.

Derived a compact expression for the transition to far-field behavior.

Validated analysis with full electromagnetic simulations.

Abstract

Two-dimensional (2D) waveguide-fed metasurfaces enable scalable antenna apertures through guided wave excitation of distributed radiating elements. However, the resulting non-uniform excitation challenges classical interpretations of near-field characteristics. Using a physics-compliant model, this paper analyzes the near-field beam focusing behavior of such architectures. We derive asymptotic scaling laws for the beamforming gain, showcasing that the power-normalized gain scales linearly with the number of radiating elements. Furthermore, we introduce a normalized beam-depth formulation and obtain a compact analytic expression that characterizes the transition to far-field-like behavior. The presented analysis is validated against simulations based on the full electromagnetic model, confirming the accuracy of the derived scaling laws and beam-depth limits.