Aplica??es de Dispositivos de Microondas utilizando Substrato EBG/PBG para Comunica??es M?veis

Silva, Anderson Max Cirilo da

26 July 2011

Made available in DSpace on 2014-12-17T14:55:50Z (GMT). No. of bitstreams: 1 AndersonMCS_DISSERT.pdf: 542550 bytes, checksum: cf969edd5c8c6cd5c0f0dcbf4f8113e0 (MD5) Previous issue date: 2011-07-26 / The modern society depends on an efficient communications system able to of transmitting and receiving information with a higher speed and reliability every time. The need for ever more efficient devices raises optimization techniques of microstrip devices, such as techniques to increase bandwidth: thicker substrates and substrate structures with EBG (Electromagnetic Band Gap) and PBG (Photonic Band Gap). This work has how aims the study of the application of PBG materials on substrates of planar structures in microstrip, more precisely in directional quadrature couplers and in rat-race and impedance of transformers. A study of the planar structures in microstrip and substrates EBG is presented. The PBG substrates can be used to optimize the radiation through the air, thus reducing the occurrence of surface waves and the resulting diffraction edge responsible for degradation of radiation pattern. Through specific programs in FORTRAN Power Station obtained the frequencies and couplings for each structure. Are used the program PACMO - Computer Aided Design in Microwave. Results are obtained of the frequency and coupling devices, ranging the frequency band used (cellular communication and Wimax systems) and the permittivity of the substrate, comparing the results of conventional material and PBG materials in the s and p polarizations. / A sociedade moderna depende de um eficiente sistema de comunica??es, capaz de transmitir e receber informa??es com uma velocidade e confiabilidade maiores a cada momento. A necessidade de dispositivos cada vez mais eficientes faz surgir t?cnicas de otimiza??o dos dispositivos em microfita, como por exemplo, t?cnicas para aumentar a largura de banda: substratos mais espessos e estruturas com substratos de Banda Eletromagn?tica Proibida - EBG (Electromagnetic Band Gap) e Banda Fot?nica Proibida - PBG (Photonic Band Gap). Este trabalho tem como objetivo o estudo da aplica??o de materiais EBG/PBG em substratos de estruturas planares em microfita, mais precisamente em acopladores direcionais em quadratura e em anel e em transformadores de imped?ncias. ? apresentado um estudo das estruturas planares em microfita e dos substratos EBG/PBG. Substratos PBG podem ser usados para otimizar a irradia??o pelo ar, reduzindo assim a ocorr?ncia de ondas superficiais e a conseq?ente difra??o de borda respons?vel pela degrada??o do diagrama de radia??o. Atrav?s de programas espec?ficos em FORTRAN obtiveram-se as freq??ncias e acoplamentos para cada estrutura. Foi utilizado o programa PACMO Projeto Auxiliado por Computador para Microondas. S?o obtidos resultados da freq??ncia e acoplamentos dos dispositivos, variando-se banda de freq??ncia utilizada (sistemas de comunica??o celular e Wimax) e a permissividade do substrato, comparando-se os resultados de materiais convencionais e materiais PBG nas polariza??es s e p.

Acoplador-quadratura

Acoplador-anel

Transformador de Imped?ncias

EBG

PBG

Wimax.

Quadrature Coupler

Rat-race Coupler

Impedance Transformer

EBG

PBG

Wimax.

CNPQ::ENGENHARIAS::ENGENHARIA ELETRICA

A simulation tool for the analysis and design of leaky wave antennas in laterally shielded planar technology with application to metamaterials

Padilla Pardo, Marta

January 2012

Leaky-waves have been a topic of increasing interest in the last years, with diverse practical applications in many different engineering fields. From periodic, FSS, EBG or even metamaterial leaky-wave based antennas to waveguide filters and higher efficiency energy guiding, they all share a common base structure: a travelling-wave propagating within a metal encapsulation, that can be open or closed, and altered by a planar metallization of periodic nature, from which the energy may radiate. Due to the fact that these antennas are usually electrically large and the periodic printed circuit requires a certain grade of complexity, 3D commercial software is prohibitively time consuming. Also, the homebrew methods developed up to this day are either not rigorous and accurate enough or unable to deal with complex periodic geometries. At this point, the evolution of leaky-wave antennas needs a solid, efficient and versatile tool where to base the future design research on. In this work a novel simulation tool for waveguide embedded leaky-wave antennas is presented. It is based on a full-wave Method of Moments applied to the spectral domain Green Functions for a rigorous modal analysis of the finite structure. The use of Subdomain basis functions allows the software to model complex periodic geometries, overcoming a main limitation, and the analytical nature of the method combined with its 2.5D approach, results in a significant computing time reduction. It is built on a modular coding philosophy and provided with a user-friendly graphical interface, and an intuitive working procedure, making the program not only fast and accurate, but also easy to use and extend to new geometries. Finally, it is remarkable the educational potential of this new analysis software, since it identifies higher order effects as bandgaps and multi-harmonic radiation from a complete and simple modal approach.

621.382

Theory, Design and Development of Artificial Magnetic Materials

Yousefi, Leila

January 2009

Artificial Magnetic Materials (AMMs) are a subgroup of metamaterials which are engineered to provide desirable magnetic properties not seen in natural materials. These artificial structures are designed to provide either negative or enhanced positive (higher than one) relative permeability. AMMs with negative permeability are used to develop Single Negative (SNG), or Double Negative (DNG) metamaterials. AMMs with enhanced positive permeability are used to provide magneto-dielectric materials at microwave frequencies where the natural magnetic materials fail to work efficiently. AMMs are realized by embedding metallic resonators in a host dielectric. These inclusions provide desirable magnetic properties near their resonance frequency. Artificial magnetic materials used as SNG, or DNG have many applications such as: sub-wavelength cavity resonators, sub-wavelength parallel-plate wave guides, sub-wavelength cylindrical and spherical core–shell systems, efficient electrically small dipole antennas, super lenses, THz active devices, sensitivity enhancement near-field probes using double and single negative media, and mutual coupling reduction between antennas. On the other hand, artificial magnetic materials used as magneto-dielectrics have other applications in developing enhanced bandwidth efficient miniaturized antennas, low profile enhanced gain antennas using artificial magnetic superstrates, wide band woodpile Electromagnetic Band Gap (EBG) structures, EBGs with enhanced in-phase reflection bandwidth used as artificial magnetic ground planes. In this thesis, several advances are added to the existing knowledge of developing artificial magnetic materials, in terms of analytical modeling, applications, realization, and experimental characterization. To realize AMMs with miniaturized unit cells, new inclusions based on fractal Hilbert curves are introduced, and analyzed. Analytical models, numerical full wave simulation, and experimental characterization are used to analyze, and study the new structures. A comprehensive comparison is made between the new inclusions, and perviously developed inclusions in terms of electromagnetic properties. The new inclusions have advantages of miniaturization, and less dispersion when compared to the existing structures in the literature. To realize multi-band AMMs, unit cells with multiple inclusions are proposed, designed, and analyzed. The new unit cells can be designed to give the desired magnetic properties either over distinguished multiple frequency bands, or over a single wide frequency band. Numerical full wave simulation is used to verify the proposed concept, and analytical models are provided for design, and optimization of the new unit cells. Unit cells with different configurations are optimized to get a wideband responce for the effective permeability. Space mapping technique is used to provide a link between analytically optimized structures, and full wave numerical simulation results. Two new methods are proposed for experimental characterization of artificial structures using microstrip, and strip line topologies. Using numerical results, the effect of anisotropy on the accuracy of the extracted parameters are investigated, and a fitting solution is proposed, and verified to address this challenge. New structures based on 2nd , and 3rd order fractal Hilbert curves are fabricated, and characterized using microstrip line, and strip line fixtures. Experimental results are presented, and compared with numerical results. The new experimental methods have advantages of lower cost, easier to fabricate and measure, and smaller sample size when compared to the existing methods in the literature. A new application is proposed for use of magnetic materials to develop wide band artificial magnetic conductors (AMC). Analytical models, and numerical analysis is used to validate the concept. A new ultra wideband AMC is designd, and analysed. The designed AMC is used as the ground plane to develop a low profile high gain ultra wide band antenna. The designed antenna is simulated, and its return loss, and gain is presented over a wide range of frequencies. A comprehensive study is presented on the performance of AMMs for the application of miniaturized antennas. A miniaturized antenna, using fractal Hilbert metamaterials as substrate, is fabricated, and measured. Measurement results are presented, and compared with numerical results. A parametric study is presented on the effect of the constitutive parameters of the artificial substrate on the performance of the miniaturized antenna. In this study, the effect of magnetic loss of AMM on the gain, and efficiency of the antenna, as well as the effect of dispersion of AMM on the bandwidth of the antenna is investigated.

Metamaterials

Artificial Magnetic Materials

Antenna

Miniaturized Antennas

EBG

DNG

SNG

MNG

Electrical and Computer Engineering

Theory, Design and Development of Artificial Magnetic Materials

Yousefi, Leila

January 2009

Artificial Magnetic Materials (AMMs) are a subgroup of metamaterials which are engineered to provide desirable magnetic properties not seen in natural materials. These artificial structures are designed to provide either negative or enhanced positive (higher than one) relative permeability. AMMs with negative permeability are used to develop Single Negative (SNG), or Double Negative (DNG) metamaterials. AMMs with enhanced positive permeability are used to provide magneto-dielectric materials at microwave frequencies where the natural magnetic materials fail to work efficiently. AMMs are realized by embedding metallic resonators in a host dielectric. These inclusions provide desirable magnetic properties near their resonance frequency. Artificial magnetic materials used as SNG, or DNG have many applications such as: sub-wavelength cavity resonators, sub-wavelength parallel-plate wave guides, sub-wavelength cylindrical and spherical core–shell systems, efficient electrically small dipole antennas, super lenses, THz active devices, sensitivity enhancement near-field probes using double and single negative media, and mutual coupling reduction between antennas. On the other hand, artificial magnetic materials used as magneto-dielectrics have other applications in developing enhanced bandwidth efficient miniaturized antennas, low profile enhanced gain antennas using artificial magnetic superstrates, wide band woodpile Electromagnetic Band Gap (EBG) structures, EBGs with enhanced in-phase reflection bandwidth used as artificial magnetic ground planes. In this thesis, several advances are added to the existing knowledge of developing artificial magnetic materials, in terms of analytical modeling, applications, realization, and experimental characterization. To realize AMMs with miniaturized unit cells, new inclusions based on fractal Hilbert curves are introduced, and analyzed. Analytical models, numerical full wave simulation, and experimental characterization are used to analyze, and study the new structures. A comprehensive comparison is made between the new inclusions, and perviously developed inclusions in terms of electromagnetic properties. The new inclusions have advantages of miniaturization, and less dispersion when compared to the existing structures in the literature. To realize multi-band AMMs, unit cells with multiple inclusions are proposed, designed, and analyzed. The new unit cells can be designed to give the desired magnetic properties either over distinguished multiple frequency bands, or over a single wide frequency band. Numerical full wave simulation is used to verify the proposed concept, and analytical models are provided for design, and optimization of the new unit cells. Unit cells with different configurations are optimized to get a wideband responce for the effective permeability. Space mapping technique is used to provide a link between analytically optimized structures, and full wave numerical simulation results. Two new methods are proposed for experimental characterization of artificial structures using microstrip, and strip line topologies. Using numerical results, the effect of anisotropy on the accuracy of the extracted parameters are investigated, and a fitting solution is proposed, and verified to address this challenge. New structures based on 2nd , and 3rd order fractal Hilbert curves are fabricated, and characterized using microstrip line, and strip line fixtures. Experimental results are presented, and compared with numerical results. The new experimental methods have advantages of lower cost, easier to fabricate and measure, and smaller sample size when compared to the existing methods in the literature. A new application is proposed for use of magnetic materials to develop wide band artificial magnetic conductors (AMC). Analytical models, and numerical analysis is used to validate the concept. A new ultra wideband AMC is designd, and analysed. The designed AMC is used as the ground plane to develop a low profile high gain ultra wide band antenna. The designed antenna is simulated, and its return loss, and gain is presented over a wide range of frequencies. A comprehensive study is presented on the performance of AMMs for the application of miniaturized antennas. A miniaturized antenna, using fractal Hilbert metamaterials as substrate, is fabricated, and measured. Measurement results are presented, and compared with numerical results. A parametric study is presented on the effect of the constitutive parameters of the artificial substrate on the performance of the miniaturized antenna. In this study, the effect of magnetic loss of AMM on the gain, and efficiency of the antenna, as well as the effect of dispersion of AMM on the bandwidth of the antenna is investigated.

Metamaterials

Artificial Magnetic Materials

Antenna

Miniaturized Antennas

EBG

DNG

SNG

MNG

Electrical and Computer Engineering

Log-Periodic Microstrip Patch Antenna Miniaturization Using Artificial Magnetic Conductor Surfaces

Almutawa, Ahmad Tariq

01 January 2011

Microstrip patch antennas are attractive for numerous military and commercial applications due to their advantages in terms of low-profile, broadside radiation, low-cost, low-weight and conformability. However, the inherent narrowband performance of patch antennas prohibits their use in systems that demand wideband radiation. To alleviate the issue, an existing approach is to combine multiple patch antennas within a log-periodic array configuration. These log-periodic patch antennas (LPMAs) are capable of providing large bandwidths (>50%) with stable broadside radiation patterns. However, they suffer from electrically large sizes. Therefore, their miniaturization without degrading the bandwidth performance holds promise for extending their use in applications that demand conformal and wideband installations. In recent years, electromagnetic band gap structures have been proposed to enhance the radiation performances of printed antennas. These engineered surfaces consist of a periodic arrangement of unit cells having specific metallization patterns. At particular frequencies, they provide a zero-degree phase shift for reflected plane waves and effectively act as high impedance surfaces. Since, their band-limited electromagnetic field behavior is quite similar to a hypothetical magnetic conductor; they are also referred to as artificial magnetic conductors (AMCs). AMC structures were shown to allow lower antenna profile, larger bandwidth, higher gain, and good unidirectional radiation by alleviating the field cancellation effects observed in ground plane backed antenna configurations. Previous research studies have already demonstrated that microstrip patch antennas can enjoy significant size reductions when placed above the AMC surfaces. This project, for the first time, investigates the application of AMCs to LPMA configurations. Specifically, the goal is to reduce the LPMA size while retaining its highly desired large bandwidth performance. To accomplish this, we employ various AMC surface configurations (e.g. uniform, log-periodic) under traditional LPMAs and investigate their performance in terms of miniaturization, bandwidth, gain, and radiation patterns.

AMC

Broadband Antenna

EBG

FSS

HIS

American Studies

Arts and Humanities

Electrical and Computer Engineering

Electromagnetics and Photonics

Implementação de estruturas EBG em antenas de microfitas e polarização linear-circular com metasuperfície para WLAN

Silva, José Lucas da

30 January 2018

Submitted by Automação e Estatística (sst@bczm.ufrn.br) on 2018-04-11T20:06:39Z No. of bitstreams: 1 JoseLucasDaSilva_TESE.pdf: 3479810 bytes, checksum: 104984cc1ac3030914010d411403b0b2 (MD5) / Approved for entry into archive by Arlan Eloi Leite Silva (eloihistoriador@yahoo.com.br) on 2018-04-16T21:57:57Z (GMT) No. of bitstreams: 1 JoseLucasDaSilva_TESE.pdf: 3479810 bytes, checksum: 104984cc1ac3030914010d411403b0b2 (MD5) / Made available in DSpace on 2018-04-16T21:57:57Z (GMT). No. of bitstreams: 1 JoseLucasDaSilva_TESE.pdf: 3479810 bytes, checksum: 104984cc1ac3030914010d411403b0b2 (MD5) Previous issue date: 2018-01-30 / O Conselho Nacional de Desenvolvimento Científico e Tecnológico - CNPq / Com a ampla utilização de sistemas de comunicação sem fio e sua aplicação em banda de frequência WLAN (Wireless Local Area Network), o presente trabalho visa analisar o comportamento de antenas de microfita, projetadas em configurações de estruturas com anéis ressoadores (SRR), ressoadores complementares (CSRR) e bandas eletromagnéticas proibidas (EBG) com largura de banda acima de 400 MHz. Esses elementos são inseridos periodicamente sob o patch no substrato das antenas e aplicadas para faixas de frequência ISM - bandas reservadas no desenvolvimento industrial, científico e médico (2,45 GHz e 5,85 GHz). Dessa forma, objetiva-se melhorar o desempenho dos parâmetros eletromagnéticos das antenas de microfita. Em seguida, aplicou-se à antena de microfita padrão uma estrutura metasuperfície com células simplificadas, de forma a proporcionar capacidade de converter os sinais linearmente polarizados, gerados por uma antena de microfita, em sinais circularmente polarizados, obedecendo a faixa de operação projetada. Para obter a otimização das estruturas modeladas na polarização, de acordo com a resposta em banda de frequência, razão axial e perda de retorno desejada, a ferramenta optimetric foi utilizada, permitindo explorar resultados para perda de retorno menor que -10 dB e razão axial abaixo de 3 dB. A análise numérica das estruturas se deu por meio do ANSYS HFSS e, para a validar esses resultados, as estruturas foram experimentalmente caracterizadas. / With the wide use of wireless communication systems and its application in Wireless Local Area Network (WLAN) frequency band, the present work aims to analyze the behavior of microstrip antennas, designed in configurations of structures with resonator rings (SRR), resonators (CSRRs) and banned electromagnetic bands (EBG) with bandwidth above 400 MHz. These elements are periodically inserted under the patch on the antennas substrate and developed for ISM frequency bands - bands reserved for industrial, scientific and medical development (2.45 GHz and 5.85 GHz). Hence, the objective is to improve the performance of the electromagnetic parameters of these modern microstrip antennas. Then, the proposed antennas are applied to the simplified cell metasurface model, in order to provide the ability to convert the linearly polarized signals generated by a microstrip antenna into circularly polarized signals, obeying their projected operating range. To obtain optimization of the structures modeled in the polarization according to the response of frequency band, axial ratio and desired return loss, the optimetric tool was used, allowing to exploit results for return loss of less than -10 dB and axial ratio below 3 dB. The numerical analysis of the structures takes place through ANSYS HFSS and, to validate these results, the structures will be experimentally characterized.

Antenas de microfitas

Estrutura EBG

Metasuperfície

WLAN

Antény s kryty z metamateriálů / Antennas with metamaterial radomes

Martínek, Luděk

January 2013

This thesis deals with microstrip antennas covered by the metamaterials. First, are described planar antennas, their problems and the emergence of surface waves. Surface waves can cause unwanted coupling among particular parts of the structure and can degrade its parameters. The problem can be solved using an electromagnetic band gap structure (EBG). These periodic structures are able to suppress surface waves in different frequency bands. It is shown how the EBG structure in the function superstate improve directivity and antenna gain. Radiation conventional microstrip antenna with metallo-dielectric EBG superstrate and with the purely dielectric double-layer superstrate is described. The both structures are designed and simulated in CST Microwave Studio program. Further is described the antenna radiation with so-called mushroom structure and metallo-dielectric EBG superstate. The structure is again designed and simulated in CST MWS program. Finally, there are two structures with metallo-dielectric superstate implemented and measured.

Planární anténa na EBG substrátu / Patch antenna with EBG substrate

Cepek, Tomáš

January 2014

The aim of the thesis is to describe EBG substrate and exminate his influence on some types of antennas and choose one of them for realization. In first part this thesis describes the paramaeters of antenna in generall, in the second part is dedicated to introduction with EBG substrate mainly on the surface with the high impedance (HIES). The third part deals with the simulations of microstrip patch antennas with EBG substrate and without EBG substrate. In the last parts was designed and optimized antenna using superstrate.

Antény pro oblasti (sub)milimetrových vln / (Sub)millimeter-Wave Antennas

Pítra, Kamil

January 2014

Disertační práce se zabývá návrhem a optimalizací kruhově polarizované anténa pro oblast terahertzových kmitočtů. V práci se věnuji zjednodušené teorii terahertzového zdroje a návrhu vhodné antény pro tento zdroj. Návrh je zaměřen na dosažení kruhové polarizace z lineárně polarizovaných antén. Abych potlačil šíření povrchové vlny na elektricky tlustém dielektrickém substrátu, věnuji se návrhu a optimalizaci specifických periodických struktur. Návrh těchto struktur je poměrně komplikovaný, protože neexistuje přímočarý vztah mezi vlastnostmi struktur s elektromagnetickým zádržným pásmem (EBG) a geometrií buňky. Abych vhodně koncentroval vyzařovanou energii do úzkého svazku, věnuji se návrhu a optimalizaci částečně odrazného plochy (PRS), které působí jako planární čočka pro terahertzovou anténu.

A Tunable Electromagnetic Band-Gap Microstrip Filter

Lancaster, Greg A

01 January 2013

In high frequency design, harmonic suppression is a persistent struggle. Non-linear devices such as switches and amplifiers produce unwanted harmonics which may interfere with other frequency bands. Filtering is a widely accepted solution, however there are various shortcomings involved. Suppressing multiple harmonics, if desired, with traditional lumped element and distributed component band-stop filters requires using multiple filters. These topologies are not easily made tunable either. A new filter topology is investigated called Electromagnetic Band-Gap (EBG) structures. EBG structures have recently gained the interest of microwave designers due to their periodic nature which prohibits the propagation of certain frequency bands. EBG structures exhibit characteristics similar to that of a band-stop filter, but in periodically repeating intervals making it ideal for harmonic suppression. The band-gap frequency of an EBG structure may be varied by altering the periodicity of the structure. However, EBG materials are generally static in structure making tuning a challenge. In this thesis, a novel solution for tuning the band-gap properties of an EBG structure is investigated. Designs aimed to improve upon existing solutions are reached. These designs involve acoustic and mechanical tuning methods. Performance is simulated using Agilent’s Advanced Design System (ADS) and a device is constructed and evaluated. Comparing all measured test cases to simulation, band-gap center frequency error is on average 4.44% and absolute band-gap rejection error is 1.358 dB.

Tunable

Filter

Band-gap

EBG

Photonic

Band Gap

Electromagnetics and Photonics

Engineering Physics