Experimental validation of an ultra-thin metasurface cloak for hiding a metallic obstacle from an antenna radiation at low frequencies

We demonstrate numerically and experimentally an ultra-thin (≈ λ/240) metasurface-based invisibility cloak for low frequency antenna applications. We consider a monopole antenna mounted on a ground plane and a cylindrical metallic obstacle of diameter smaller than the wavelength located in its near-...

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Bibliographic Details
Published in:Applied physics letters 2017-07, Vol.111 (5)
Main Authors: Teperik, Tatiana V., Burokur, Shah Nawaz, de Lustrac, André, Sabanowski, Guy, Piau, Gérard-Pascal
Format: Article
Language:English
Subjects:
Antenna radiation patterns
Antennas
Applied physics
Computer simulation
Engineering Sciences
Finite element method
Ground plane
Low frequencies
Metasurfaces
Monopole antennas
Monopoles
Stealth technology
Substrates
Visibility
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Summary:We demonstrate numerically and experimentally an ultra-thin (≈ λ/240) metasurface-based invisibility cloak for low frequency antenna applications. We consider a monopole antenna mounted on a ground plane and a cylindrical metallic obstacle of diameter smaller than the wavelength located in its near-field. To restore the intrinsic radiation patterns of the antenna perturbed by this obstacle, a metasurface cloak consisting simply of a metallic patch printed on a dielectric substrate is wrapped around the obstacle. Using a finite element method based commercial electromagnetic solver, we show that the radiation patterns of the monopole antenna can be restored completely owing to electromagnetic modes of the resonant cavity formed between the patch and obstacle. The metasurface cloak is fabricated, and the concept is experimentally demonstrated at 125 MHz. Performed measurements are in good agreement with numerical simulations, verifying the efficiency of the proposed cloak.
ISSN:0003-6951
1077-3118
DOI:10.1063/1.4996065