Lucio Vegni scite author profile

rЈ ϭ ͱG r ϭ ͱ1.47 ϫ 0.95 ϭ 1.18 and an effective read range given by: r ϭ rЈ ⅐ r 0 ϭ 5.90 m This means that the insertion of a proper designed metamaterial slab allows an increase of the effective read range parameter of about 40%. CONCLUSIONSIn this article, new insights and solutions to problems related to small antennas for RFID and wireless sensor applications by metamaterials have been provided. We have reviewed design requirements for passive UHF RFID tag antennas; we outlined the design process, and proposed a performance protocol for tag analysis. We have also shown that a metamaterial slab can be used to increase of about 40% the read range of the tag antenna without using a ground plane. NUMERICAL AND EXPERIMENTAL INVESTIGATION OF BASIC PROPERTIES OF WIRE MEDIUM-BASED SHORTENED HORN ANTENNAS

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Equivalent-Circuit Models for the Design of Metamaterials Based on Artificial Magnetic Inclusions

Bilotti

Toscano

Vegni

et al. 2007

IEEE Trans. Microwave Theory Techn.

254

168

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Abstract-In this paper, we derive quasi-static equivalent-circuit models for the analysis and design of different types of artificial magnetic resonators-i.e., the multiple split-ring resonator, spiral resonator, and labyrinth resonator-which represent popular inclusions to synthesize artificial materials and metamaterials with anomalous values of the permeability in the microwave and millimeter-wave frequency ranges. The proposed models, derived in terms of equivalent circuits, represent an extension of the models presented in a recent publication. In particular, the extended models take into account the presence of a dielectric substrate hosting the metallic inclusions and the losses due to the finite conductivity of the conductors and the finite resistivity of the dielectrics. Exploiting these circuit models, it is possible to accurately predict not only the resonant frequency of the individual inclusions, but also their quality factor and the relative permeability of metamaterial samples made by given arrangements of such inclusions. Finally, the three models have been tested against full-wave simulations and measurements, showing a good accuracy. This result opens the door to a quick and accurate design of the artificial magnetic inclusions to fabricate real-life metamaterial samples with anomalous values of the permeability.

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Design of Miniaturized Metamaterial Patch Antennas With $\mu$-Negative Loading

Bilotti

Alù

Vegni

2008

IEEE Trans. Antennas Propagat.

205

110

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Recent theoretical studies have shown that circular patch antennas loaded by an inhomogeneous substrate partially filled with a -negative (MNG) metamaterial may in principle support a resonant radiating mode, even if the total size of the radiator is significantly smaller than the wavelength of operation. In those theoretical analyses, MNG metamaterials have been assumed as continuous, isotropic and readily available materials, characterized by a proper dispersion in frequency and by inherent ohmic losses. The fabrication of such compact antennas, however, would require the major effort of designing proper subwavelength inclusions that realize the MNG behavior of the substrate, and consequently a careful design of their geometry, location and orientation. The fabrication of a fully isotropic MNG sample to reside underneath the sub-wavelength patch, moreover, may be challenging with the current technological limitations. In this paper, we first show that the proposed sub-wavelength radiator may operate even when the fabricated MNG sample is not isotropic, due to the specific polarization of the magnetic field in the MNG region. Then, we propose a complete design of the magnetic inclusions, presenting full-wave numerical simulations of the structure, which effectively supports the expected resonant mode, despite the small size of the antenna. The comparisons among analytical results of the patch loaded by: (a) the ideal MNG sample applying a simple cavity model; (b) full-wave numerical simulations of the same antenna considering the presence of the feed; and (c) full-wave numerical simulations of the antenna loaded by the proposed magnetic inclusions, show how our design effectively simulate the presence of an MNG sample, allowing the realistic design of a sub-wavelength metamaterial patch antenna with satisfactory matching and radiating features. This may open up new venues in the realization of efficient metamaterial radiating components for practical purposes.Index Terms-Integrated antennas, magnetic inclusions, metamaterials.

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Overcoming Mutual Blockage Between Neighboring Dipole Antennas Using a Low-Profile Patterned Metasurface

Monti

Soric

Alù

et al. 2012

Antennas Wirel. Propag. Lett.

155

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Split-Ring-Resonator-Coupled Enhanced Transmission through a Single Subwavelength Aperture

et al. 2009

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We report the enhanced transmission of electromagnetic waves through a single subwavelength aperture by making use of the resonance behavior of a split ring resonator (SRR) at microwave frequencies. By placing a single SRR at the near-field of the aperture, strongly localized electromagnetic fields are effectively coupled to the aperture with a radius that is twenty times smaller than the resonance wavelength (r/λ = 0.05). We obtained 740-fold transmission enhancement by exciting the electric resonance of SRR. A different coupling mechanism, through the magnetic resonance of SRR, is also verified to yield enhanced transmission. Good agreement is obtained between the microwave measurements and numerical simulations.

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Lucio Vegni

Design of Spiral and Multiple Split-Ring Resonators for the Realization of Miniaturized Metamaterial Samples

Equivalent-Circuit Models for the Design of Metamaterials Based on Artificial Magnetic Inclusions

Design of Miniaturized Metamaterial Patch Antennas With $\mu$-Negative Loading

Overcoming Mutual Blockage Between Neighboring Dipole Antennas Using a Low-Profile Patterned Metasurface

Split-Ring-Resonator-Coupled Enhanced Transmission through a Single Subwavelength Aperture

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