Diffraction by a truncated planar array of dipoles: a Wiener-Hopf approach
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Publication:781418
DOI10.1016/j.wavemoti.2019.03.004OpenAlexW2921331433WikidataQ128298936 ScholiaQ128298936MaRDI QIDQ781418
Alastair P. Hibbins, Matteo Albani, Miguel Camacho, Filippo Capolino
Publication date: 16 July 2020
Published in: Wave Motion (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.wavemoti.2019.03.004
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- An efficient numerical evaluation of the Green's function for the Helmholtz operator on periodic structures
- One-dimensional reflection by a semi-infinite periodic row of scatterers
- Low-Frequency Scattering by a Semi-Infinite Lattice of Cylinders
- Frequency-domain Green's function for a planar periodic semi-infinite phased array. II. Diffracted wave phenomenology
- Frequency-domain Green's function for a planar periodic semi-infinite phased array .I. Truncated floquet wave formulation
- High-frequency analysis of an array of line sources on a truncated ground plane
- Synthesis of Modulated-Metasurface Antennas With Amplitude, Phase, and Polarization Control
- Optimized Periodic MoM for the Analysis and Design of Dual Polarization Multilayered Reflectarray Antennas Made of Dipoles
- Analytical Multimodal Network Approach for 2-D Arrays of Planar Patches/Apertures Embedded in a Layered Medium
- An Efficient MoM Formulation for Finite-by-Infinite Arrays of Two-Dimensional Antennas Arranged in a Three-Dimensional Structure
- New Method for the Efficient Summation of Double Infinite Series Arising From the Spectral Domain Analysis of Frequency Selective Surfaces
- Comparative Analysis of Acceleration Techniques for 2-D and 3-D Green's Functions in Periodic Structures Along One and Two Directions
- Enhanced MoM Analysis of the Scattering by Periodic Strip Gratings in Multilayered Substrates
- Semi‐infinite diffraction gratings—I
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