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PIER PIER B PIER C PIER M PIER Letters
2010-11-10
Optimal Design of Dipole Antennas Backed by a Finite High-Impedance Screen
By
Giacomo Bianconi,

    Dr. Giacomo Bianconi

    Dipartimento di Ingegneria dell'Informazione

    Università di Pisa

    Italy

    Homepage

Filippo Costa,

    Dr. Filippo Costa

    Department of Information Engineering

    University of Pisa

    Italy

    Homepage

Simone Genovesi,

    Dr. Simone Genovesi

    Dipartimento di Ingegneria dell' Informazione

    Università di Pisa

    Italy

    Homepage

Agostino Monorchio

    Dr. Agostino Monorchio

    Dept Informat Engn

    Univ Pisa

    Italy

    Homepage

Progress In Electromagnetics Research C, Vol. 18, 137-151, 2011
doi:10.2528/PIERC10111204 | Google Scholar

Abstract
The performance of a short dipole antenna closely located above a finite High-Impedance Surface (HIS) is addressed. The antenna behavior is thoroughly analyzed in the frequency range up to the HIS resonance within the region where the propagation of the TE surface waves is not allowed. In the first part of the paper the analysis of a dipole antenna above a grounded dielectric slab is considered, and then it is extended to the case of a substrate with a frequency selective surface printed on it. For all configurations, the radiation pattern of the structure and Front-to-Back Ratio (FBR) are reported and compared. It is shown that the presence of a suitable frequency selective surface, regardless of the shape of the periodic elements, guarantees the antenna matching but does not influence the behavior of the radiation patterns and the front-to-back ratio in the frequency range where only TM modes are allowed to propagate. The front-to-back ratio has been found to be maximum when the size of the generic HIS is around 0.8λg (with λg the TM guided surface wave wavelength). All the speculations are supported by simulated and measured results.
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Citation
Giacomo Bianconi, Filippo Costa, Simone Genovesi, and Agostino Monorchio, "Optimal Design of Dipole Antennas Backed by a Finite High-Impedance Screen," Progress In Electromagnetics Research C, Vol. 18, 137-151, 2011.
doi:10.2528/PIERC10111204
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