Metasurfaces for Wideband and Efficient Polarization Rotation

An efficient wideband polarization-rotation thin metasurface based on oval pattern is presented. The aim of this structure is to manipulate the polarization of incident electromagnetic waves in reflect band. The oval pattern is split by strip lines to outperform the results. It is shown that the pro...

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Bibliographic Details
Published in:IEEE transactions on antennas and propagation 2021-03, Vol.69 (3), p.1799-1804
Main Authors: Karamirad, Mohsen, Ghobadi, Changiz, Nourinia, Javad
Format: Article
Language:English
Subjects:
Broadband
Circular polarization
Conversion ratio
Converters
Electromagnetic radiation
Equivalent impedance surface (EIS)
Frequencies
Frequency conversion
Impedance
Incidence angle
low profile
Magnetic resonance
Metasurfaces
polarization converter
Reflection
Resonant frequency
Rotation
Simulation
Strips
Surface impedance
Wideband
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Description
Summary:An efficient wideband polarization-rotation thin metasurface based on oval pattern is presented. The aim of this structure is to manipulate the polarization of incident electromagnetic waves in reflect band. The oval pattern is split by strip lines to outperform the results. It is shown that the proposed polarization converter converts the incident linearly or circularly polarized waves into orthogonal counterpart over a frequency band of 10.2-20.5 GHz. A prototype of the proposed structure is fabricated to validate the numerical simulation. The experimental and simulation results confirm that polarization conversion ratio (PCR) is greater than 90% at the same frequency band with high stability to oblique incidence angle. Numerical simulation reveals that the strong electric and magnetic resonances between top and bottom layers lead to wideband polarization conversion. Equivalent impedance surface method is discussed to further analysis the polarization conversion mechanism.
ISSN:0018-926X
1558-2221
DOI:10.1109/TAP.2020.3012828