Magneto-Dielectric Wire Antennas Theory and Design

abstract: There is a pervasive need in the defense industry for conformal, low-profile, efficient and broadband (HF-UHF) antennas. Broadband capabilities enable shared aperture multi-function radiators, while conformal antenna profiles minimize physical damage in army applications, reduce drag and w...

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Other Authors: Sebastian, Tom (Author)
Format: Doctoral Thesis
Language:English
Published: 2013
Subjects:
Online Access:http://hdl.handle.net/2286/R.I.18773
id ndltd-asu.edu-item-18773
record_format oai_dc
spelling ndltd-asu.edu-item-187732018-06-22T03:04:24Z Magneto-Dielectric Wire Antennas Theory and Design abstract: There is a pervasive need in the defense industry for conformal, low-profile, efficient and broadband (HF-UHF) antennas. Broadband capabilities enable shared aperture multi-function radiators, while conformal antenna profiles minimize physical damage in army applications, reduce drag and weight penalties in airborne applications and reduce the visual and RF signatures of the communication node. This dissertation is concerned with a new class of antennas called Magneto-Dielectric wire antennas (MDWA) that provide an ideal solution to this ever-present and growing need. Magneto-dielectric structures (μr>1;εr>1) can partially guide electromagnetic waves and radiate them by leaking off the structure or by scattering from any discontinuities, much like a metal antenna of the same shape. They are attractive alternatives to conventional whip and blade antennas because they can be placed conformal to a metallic ground plane without any performance penalty. A two pronged approach is taken to analyze MDWAs. In the first, antenna circuit models are derived for the prototypical dipole and loop elements that include the effects of realistic dispersive magneto-dielectric materials of construction. A material selection law results, showing that: (a) The maximum attainable efficiency is determined by a single magnetic material parameter that we term the hesitivity: Closely related to Snoek's product, it measures the maximum magnetic conductivity of the material. (b) The maximum bandwidth is obtained by placing the highest amount of μ" loss in the frequency range of operation. As a result, high radiation efficiency antennas can be obtained not only from the conventional low loss (low μ") materials but also with highly lossy materials (tan(δm)>>1). The second approach used to analyze MDWAs is through solving the Green function problem of the infinite magneto-dielectric cylinder fed by a current loop. This solution sheds light on the leaky and guided waves supported by the magneto-dielectric structure and leads to useful design rules connecting the permeability of the material to the cross sectional area of the antenna in relation to the desired frequency of operation. The Green function problem of the permeable prolate spheroidal antenna is also solved as a good approximation to a finite cylinder. Dissertation/Thesis Sebastian, Tom (Author) Diaz, Rodolfo E (Advisor) Pan, George (Committee member) Aberle, James (Committee member) Kozicki, Michael (Committee member) Arizona State University (Publisher) Electrical engineering Electromagnetics Antenna Circuit Model Conformal Antennas Electrically Small Antennas Magnetic Dipoles Magneto-Dielectric Antennas Permeability eng 213 pages Ph.D. Electrical Engineering 2013 Doctoral Dissertation http://hdl.handle.net/2286/R.I.18773 http://rightsstatements.org/vocab/InC/1.0/ All Rights Reserved 2013
collection NDLTD
language English
format Doctoral Thesis
sources NDLTD
topic Electrical engineering
Electromagnetics
Antenna Circuit Model
Conformal Antennas
Electrically Small Antennas
Magnetic Dipoles
Magneto-Dielectric Antennas
Permeability
spellingShingle Electrical engineering
Electromagnetics
Antenna Circuit Model
Conformal Antennas
Electrically Small Antennas
Magnetic Dipoles
Magneto-Dielectric Antennas
Permeability
Magneto-Dielectric Wire Antennas Theory and Design
description abstract: There is a pervasive need in the defense industry for conformal, low-profile, efficient and broadband (HF-UHF) antennas. Broadband capabilities enable shared aperture multi-function radiators, while conformal antenna profiles minimize physical damage in army applications, reduce drag and weight penalties in airborne applications and reduce the visual and RF signatures of the communication node. This dissertation is concerned with a new class of antennas called Magneto-Dielectric wire antennas (MDWA) that provide an ideal solution to this ever-present and growing need. Magneto-dielectric structures (μr>1;εr>1) can partially guide electromagnetic waves and radiate them by leaking off the structure or by scattering from any discontinuities, much like a metal antenna of the same shape. They are attractive alternatives to conventional whip and blade antennas because they can be placed conformal to a metallic ground plane without any performance penalty. A two pronged approach is taken to analyze MDWAs. In the first, antenna circuit models are derived for the prototypical dipole and loop elements that include the effects of realistic dispersive magneto-dielectric materials of construction. A material selection law results, showing that: (a) The maximum attainable efficiency is determined by a single magnetic material parameter that we term the hesitivity: Closely related to Snoek's product, it measures the maximum magnetic conductivity of the material. (b) The maximum bandwidth is obtained by placing the highest amount of μ" loss in the frequency range of operation. As a result, high radiation efficiency antennas can be obtained not only from the conventional low loss (low μ") materials but also with highly lossy materials (tan(δm)>>1). The second approach used to analyze MDWAs is through solving the Green function problem of the infinite magneto-dielectric cylinder fed by a current loop. This solution sheds light on the leaky and guided waves supported by the magneto-dielectric structure and leads to useful design rules connecting the permeability of the material to the cross sectional area of the antenna in relation to the desired frequency of operation. The Green function problem of the permeable prolate spheroidal antenna is also solved as a good approximation to a finite cylinder. === Dissertation/Thesis === Ph.D. Electrical Engineering 2013
author2 Sebastian, Tom (Author)
author_facet Sebastian, Tom (Author)
title Magneto-Dielectric Wire Antennas Theory and Design
title_short Magneto-Dielectric Wire Antennas Theory and Design
title_full Magneto-Dielectric Wire Antennas Theory and Design
title_fullStr Magneto-Dielectric Wire Antennas Theory and Design
title_full_unstemmed Magneto-Dielectric Wire Antennas Theory and Design
title_sort magneto-dielectric wire antennas theory and design
publishDate 2013
url http://hdl.handle.net/2286/R.I.18773
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