A Quasi-Direct Method for the Surface Impedance Design of Modulated Metasurface Antennas

A Quasi-Direct Method for the Surface Impedance Design of Modulated Metasurface Antennas

A new approach is presented for synthesizing modulated metasurface (MTS) antennas (MoMetAs) with arbitrary radiation patterns, assumed to be given in amplitude, phase, and polarization. The MTS is defined on a circular domain and is represented as a continuous sheet transition impedance boundary con...

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Bibliographic Details
Published in:IEEE transactions on antennas and propagation Vol. 67; no. 1; pp. 24 - 36
Main Authors: Bodehou, Modeste, Craeye, Christophe, Martini, Enrica, Huynen, Isabelle
Format: Journal Article
Language:English
Published: New York IEEE 01-01-2019
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects:
Antenna radiation patterns
Antennas
Basis functions
beam shaping
Boundary conditions
Electric fields
Impedance
impedance boundary condition (IBC)
Integral equations
inverse problems
leaky-wave (LW) antennas
Metasurfaces
metasurfaces (MTSs)
Optical surface waves
Orthogonal functions
Substrates
Surface impedance
Testing
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Description
Summary:A new approach is presented for synthesizing modulated metasurface (MTS) antennas (MoMetAs) with arbitrary radiation patterns, assumed to be given in amplitude, phase, and polarization. The MTS is defined on a circular domain and is represented as a continuous sheet transition impedance boundary condition (IBC) on the top of a grounded substrate. The proposed method relies on an entire-domain discretization of the electric field integral equation (EFIE). Via the dyadic Green's function of the grounded substrate, the desired radiation pattern is translated into the visible part of the surface current spectrum, decomposed into entire-domain and orthogonal basis functions, while the invisible part of the spectrum stems from the solution of the unmodulated sheet problem. The EFIE is then inverted to obtain the sheet impedance, which is constrained to be anti-Hermitian, as required for implementation with lossless patches. The efficiency of the method relies on the precomputation of the reaction integrals between three functions: basis functions for currents and impedances and testing functions for fields. The formulation is presented first for the scalar (isotropic) MTS case and then generalized to the tensorial (anisotropic) MTSs. Several radiation patterns are presented and designed successfully. A full-wave method-of-moment code is used to validate the designed MTSs IBC.
ISSN:0018-926X
1558-2221
DOI:10.1109/TAP.2018.2874762