Realization of Single-Layer Fourier Phased Metasurfaces for Wideband RCS Reduction

An efficient and fast strategy to design and realize single-layer Fourier phased metasurfaces for wideband radar cross-section (RCS) reduction when illuminated by a circular polarization (CP) plane wave is proposed in this letter. The scattering phase (between 0° and 360°) required at each unit cell of the proposed metasurfaces was computed using the Fourier phase formula in which the focal length ( F ) is inversely proportional to the phase distribution. Pancharatnam–Berry (PB) phase theory was applied with unit cells of subwavelength periodicity to further enhance the scattering and RCS reduction characteristics. The proposed wideband Fourier phased metasurface has a square shape and contains 30 × 30 PB unit cells with subwavelength periodicity of 5 mm ≈ 0.26λ _{16 GHz} . Both simulation and measured results show that the proposed Fourier phased metasurfaces can achieve more than 10 dB of RCS reduction under normal incidence of CP plane wave regardless of the value of F . Under oblique incidence, more than 10 dB of RCS reduction was maintained for incident angles up to 60°. In addition, the single-layer Fourier phased metasurface features wideband 10 dB RCS reduction bandwidth from 10 to 24 GHz with a thickness of only 2 mm. This resulted in an 82.3% fractional bandwidth of RCS reduction, which is higher than the other designs reported in the literature. The proposed design strategy provides a promising way to design and realize metasurfaces for wideband and stable RCS reduction performance without the need to use a computationally complex and/or time-consuming and slow running optimization algorithm.