Thèses sur le sujet « ARTIFICIAL MAGNETIC CONDUCTOR PLANE »
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1
Visser, Hugo Hendrik. « An artificial magnetic ground-plane for a log-periodic antenna ». Thesis, Stellenbosch : University of Stellenbosch, 2010. http://hdl.handle.net/10019.1/4176.
Texte intégralRésumé :
Thesis (MScEng (Electrical and Electronic Engineering))--University of Stellenbosch, 2010.ENGLISH ABSTRACT: This paper presents the implementation of an artificial magnetic ground-plane with a low profile Log-periodic Dipole Array (LPDA) antennas. After the properties of three typical Electromagnetic Bandgap (EBG) structures are investigated and their bandwidth properties are studied, a mechanism is presented to improve the band-width over which the EBG surface acts as a perfect magnetic conductor (PMC). A low profile LPDA is modeled above this surface and the results indicate an improved band-width region. Compared with a LPDA in free space the frequency band is shifted higher by the EBG surface and the gain pattern is shifted from a horizontal orientation to a vertical orientation.
AFRIKAANSE OPSOMMING: Hierdie dokument stel voor die implementering van kunsmatige magnetiese grondvlakke met Logaritmiese Periodiese Dipool Samestelling (LPDS) antennas. Die eienskappe van drie tipiese Elektromagnetiese Bandgaping (EBG) strukture word ondersoek en hul bandwydte eienskappe word bestudeer. ’n Meganisme word voorgestel om die bandwydte te verbeter waar die EBG oppervlakte soos n perfekte magnetiese geleier optree. ’n Lae profiel LPDS word bo hierdie oppervlakte geplaas. Die resultate dui aan ’n verbetering in the bandwydte. In vergelyking met ’n LPDS in vrye ruimte skuif die frekwensie band ho¨er as gevolg van die EBG oppervlakte en die aanwins patroon skuif van ’n horisontale orientasie na ’n vertikale orientasie.
2
Almutawa, Ahmad Tariq. « Log-Periodic Microstrip Patch Antenna Miniaturization Using Artificial Magnetic Conductor Surfaces ». Scholar Commons, 2011. http://scholarcommons.usf.edu/etd/2982.
Texte intégralRésumé :
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.
3
Kostka, Darryl. « Enhancement of printed inductors using artificial magnetic conductor (AMC) surfaces for millimeter-wave applications ». Thesis, McGill University, 2009. http://digitool.Library.McGill.CA:80/R/?func=dbin-jump-full&object_id=40815.
Texte intégralRésumé :
Integrated inductors are one of the most basic elements used in the design of modern electronic systems. However, they generally suffer from poor quality and are inherently area intensive, thus limiting system performance and prove to be a bottleneck for compact system integration. Several research efforts have been devoted to the development of miniaturized, high quality inductors. One such method proposes the use of an Artificial Magnetic Conductor (AMC) surface to enhance the inductor performance by creating a second inductive region thereby enabling inductor reuse. It can theoretically be shown, through image theory, that an AMC reflector can be used to effectively double the inductance of an inductor component. Accordingly, in order to validate this concept, two AMC surface designs are investigated for both on-chip and PCB-based implementations. The designed AMC surfaces are then integrated with standard loop inductor components in order to justify their performance benefits through measurement results of the fabricated prototypes. Finally, the practicality of this approach is demonstrated through the application of mm-wave VCOs by replacing a standard LC-VCO tank inductor with a miniaturized AMC-backed inductor. In order to do so, mm-wave LC-VCO prototypes are designed, fabricated and characterized through measurements.Les inducteurs intégrés sont parmi les éléments élémentaires les plus utilisés dans la conception de systèmes électroniques modernes. Cependant, ils souffrent généralement d’une faible qualité et d’une large consomption d’espace, limitant ainsi les performances du système et compliquent donc l’intégration de systèmes compactes. Plusieurs efforts en recherche ont été consacrés au développement d’inducteurs de haute qualité miniatures. Une de ces méthodes proposent l’utilisation d’un Conducteur Magnétique Artificiel (CMA) comme surface pour améliorer la performance de l’inducteur en créant une deuxième région inductive ainsi permettant la réutilisation de l’inducteur. Il peut être démontré théoriquement, par la théorie des images, qu’un réflecteur CMA peut être utilisé pour doubler l’inductance total d’un inducteur. Par conséquent, afin de valider ce concept, deux designs de surfaces CMA sont investigués pour l’intégration sur puce (on-chip) et sur carte (PCB). Les surfaces CMA sont ensuite intégrées avec des composantes d’inducteurs en boucle standards afin de justifier leurs avantages en termes de performances par les résultats expérimentaux obtenus par ces prototypes. Finalement, le caractère pratique de cette approche est démontré par l’application d’un Oscillateur (VCO) d’ondes-mm en remplaçant le réservoir-LC par une version miniaturisée d’un inducteur par CMA. Pour ce faire, les prototypes d’Oscillateur-LC à ondes-mm sont conçus, fabriqués et caractérisé de façon expérimentale.
4
Jamaly, Nima. « Comparative Study of Different Excitation Techniques for Microstrip-like Structures over an Infinite Perfect Electric Conductor Plane ». Thesis, University of Gävle, Department of Technology and Built Environment, 2006. http://urn.kb.se/resolve?urn=urn:nbn:se:hig:diva-326.
Texte intégralRésumé :
The overall goal of the thesis is to establish detailed comparisons among different well-known models of excitations in their application on Microstrip-like Monopoles. Comparisons are made over the input impedances predicted by these excitations. In this way, the Galerkin’s version of the Method of Moment is applied and rooftops functions are chosen as our basis/weighting functions. Different excitation models have their influence over the excitation vector and a unique MoM matrix is used to give input impedances. We shall elicit the effects of several parameters over relative input self/mutual impedances derived from these excitation models and finally make conclusions about their differences in anticipating the input Resistance, input Reactance and also resonance frequencies.
5
Wang, Shenhong. « High-gain planar resonant cavity antennas using metamaterial surfaces ». Thesis, Loughborough University, 2006. https://dspace.lboro.ac.uk/2134/12481.
Texte intégralRésumé :
This thesis studies a new class of high gain planar resonant cavity antennas based on metamaterial surfaces. High-gain planar antennas are becoming increasing popular due to their significant advantages (e.g. low profile, small weight and low cost). Metamaterial surfaces have emerged over the last few years as artificial structures that provide properties and functionalities not readily available from existing materials. This project addresses novel applications of innovative metamaterial surfaces on the design of high-gain planar antennas. A ray analysis is initially employed in order to describe the beamfonning action of planar resonant cavity antennas. The phase equations of resonance predict the possibility of low-profile/subwavelength resonant cavity antennas and tilted beams. The reduction of the resonant cavity profile can be obtained by virtue of novel metamaterial ground planes. Furthermore, the EBG property of metamaterial ground planes would suppress the surface waves and obtain lower backlobes. By suppressing the TEM mode in a resonant cavity, a novel aperture-type EBG Partially Reflective Surface (PRS) is utilized to get low sidelobes in both planes (E-plane and H-plane) in a relatively finite structure. The periodicity optimization of PRS to obtain a higher maximum directivity is also investigated. Also it is shown that antennas with unique tilted beams are achieved without complex feeding mechanism. Rectangular patch antennas and dipole antennas are employed as excitations of resonant cavity antennas throughout the project. Three commercial electromagnetic simulation packages (Flomerics Microstripes ™ ver6.S, Ansoft HFSSTM ver9.2 and Designer ™ ver2.0) are utilized during the rigorous numerical computation. Related measurements are presented to validate the analysis and simulations.
6
Guo, Yunchuan. « Analysis and design of novel electromagnetic metamaterials ». Thesis, Loughborough University, 2006. https://dspace.lboro.ac.uk/2134/7864.
Texte intégralRésumé :
This thesis introduces efficient numerical techniques for the analysis of novel electromagnetic metamaterials. The modelling is based on a Method of Moments modal analysis in conjunction with an interpolation scheme, which significantly accelerates the computations. Triangular basis functions are used that allow for modelling of arbitrary shaped metallic elements. Unlike the conventional methods, impedance interpolation is applied to derive the dispersion characteristics of planar periodic structures. With these techniques, the plane wave and the surface wave responses of fractal structures have been studied by means of transmission coefficients and dispersion diagrams. The multiband properties and the compactness of the proposed structures are presented. Based on this method, novel planar left-handed metamaterials are also proposed. Verifications of the left-handedness are presented by means of full wave simulation of finite planar arrays using commercial software and lab measurement. The structures are simple, readily scalable to higher frequencies and compatible with low-cost fabrication techniques.
7
Meng, Fanhong. « Développement d’antennes à base de structures métamatériaux pour les applications aéronautiques (GPS/DME, bande L) et de communications haut débit (en bade E – 80 GHz) ». Thesis, Paris 10, 2015. http://www.theses.fr/2015PA100203.
Texte intégralRésumé :
Les travaux présentés dans ce manuscrit sont relatifs à la conception et au développement d’antennes basées sur les structures artificielles – métamatériaux. La première antenne conçue et réalisée est une antenne bi-fonction en bande L (~1GHz) (GPS et DME) à diversité de bande/de polarisation, destinée aux applications aéronautiques. Ces travaux rentrent dans le cadre du projet MSIE (pôle de compétitivité ASTHEC) pour lequel notre LEME a été très actif. Les partenaires industriels de ce projet sont EADS/IW, Dassault aviation, INEO-Défense, SATIMO. Les résultats montrent la faisabilité d’une antenne unique pouvant avoir simultanément deux fonctions avec une diversité de polarisation et de bande spectrale. L’utilisation des métamatériaux a permis en particulier le maintien de la polarisation circulaire de l’antenne GPS -L1 à L5. La fonction DME a été consolidée avec le maintien de son gain. La seconde antenne est une antenne cavité Fabry-Pérot mettant en œuvre une structure partiellement réfléchissante double couche. Nous avons démontré le phénomène physique d’inversion de la phase du coefficient de réflexion de la PRS. Nous avons obtenu un gradient positif de phase sur une bande de 5 GHz autour de 80GHz. Grace à ce profil nouveau de la phase obtenu par la structure métamatériau PRS, on dispose d’une avance linéaire de la phase qui compense le retard du à la cavité Fabry-Pérot. Ainsi on maintient les conditions de résonance de la cavité sur une large bande, 5GHz. Nous démontrons, que la mise en œuvre de cette structure aux caractéristiques inédites permet de réaliser une antenne cavité ultra-directive sur une très large bande spectrale de 5GHz. Les performances atteintes sont une directivité de 35 à 40dBi sur 5 GHz, une adaptation parfaite (gain ~ directivité) avec très peu de sources primaires. L’antenne est compacte avec une hauteur totale inférieure au 10mm (connecteur compris) et une surface de 100mmx100mmThe work presented in this manuscript is related to the design and development of antennas based on artificial structures - metamaterials. The first designed and built antenna is a GPS and DME dual-function in the L (~ 1GHz). It is an antenna designed with polarization and spectral diversities for aeronautical applications. The work is within the MSIE project of ASTHEC cluster for which our laboratory (LEME) was very active. The industrial partners of the project are EADS/IW, Dassault Aviation, INEO-Defense SATIMO. The results show the feasibility of a single antenna having simultaneously two functions with a diversity of polarization and spectral band. The use of metamaterials enabled in particular the preservation of circular polarization of the GPS antenna on the bands ranging from L1 to L2. The DME function was consolidated with the same gain.The second antenna is an antenna Fabry-Perot cavity employing a partially reflective structure (PRS) Double-layer. We have demonstrated by numerical simulation and experimental characterization, the physical phenomenon of inversion phase of the reflection coefficient PRS. We obtain a positive gradient of the phase over a broad band of 5 GHz around 80GHz. Thanks to this new profile obtained by the PRS metamaterial structure, it has a linear advance of the phase which compensates for the delay of the Fabry-Perot cavity. Thus the cavity resonance conditions are maintained over a wide band, 5GHz. We demonstrate that the implementation of this structure with unique features allows a highly directive antenna cavity over a very wide spectral band 5GHz. The performance are a directivity of 35-40 dBi over 5 GHz, a perfect adaptation (gain ~ directivity) with very few primary sources
8
Raimbault, Narcisse. « Antenne hélice compacte directive à polarisation circulaire pour dispositif RFID ». Thesis, Rennes 1, 2015. http://www.theses.fr/2015REN1S009/document.
Texte intégralRésumé :
La technologie RFID (Radio Frequency Identification) prend une place de plus en plus importante dans la société d'aujourd'hui notamment dans des domaines aussi variés que la santé, la sécurité, la logistique... Le développement de cette technologie met en évidence de nouvelles contraintes comme la réduction des zones de lecture et la géo-localisation pour le stockage et le suivi de marchandises. Dans ce contexte, la thèse s'est focalisée sur le développement d'antennes pour lecteur RFID dans le cadre du projet SPINNAKER piloté par TAGSYS RFID et soutenu par OSEO. L'objectif de cette étude est de concevoir des antennes compactes et directives à polarisation circulaire en bande UHF et SHF. L'antenne hélice présente toutes ces caractéristiques à l'exception de la hauteur, très importante dès que l'on souhaite obtenir des performances élevées surtout en gain. Dans ce manuscrit, trois solutions sont proposées pour réduire la hauteur de l'antenne hélice tout en répondant aux cahiers des charges. La première solution consiste à utiliser un réflecteur de forme cylindrique ou conique qui permet de réduire la hauteur d'une antenne hélice classique d'un facteur quatre pour atteindre 0,9λ. La réduction de la hauteur se traduit par une augmentation de la surface autour de l'antenne avec une dimension latérale de 2,3λ. La seconde solution consiste à utiliser l'antenne hélice avec une cavité Fabry-pérot. La hauteur du système antennaire obtenue est de 0,5λ avec un diamètre de 2λ. La dernière solution développée dans la thèse introduit une surface CMA à la solution précédente qui permet de réduire la hauteur à 0,25λ. Toutes les solutions proposées ont été validées expérimentalementOver the past 20 years, the RFID (Radio Frequency Identification) technology is having a huge expansion. Nowadays, it is frequently used in different areas as the health, the security and the logistic. A lot of researches are ongoing on this topic, especially in order to reduce the reading zone of the readers and to locate the tags. This thesis focuses on the development of new antennas for Readers RFID devices and is part of the SPINNAKER project supported by OSEO. The antennas requirements are circular polarization, high directivity and gain with low profile. The helix antennas meet all these requirements except the axial length. In this manuscript, we propose three solutions to reduce the helix antenna axial length. The first one uses a cylindrical or conical optimal reflector to reduce the length by four. This reduction affects directly the surface witch increases up to 2.3λ. The second solution uses the helix antenna as a circular polarization feed for a Fabry-Perot (FP) cavity. The final antenna presents a cavity height of 0.5λ and a 2λ diameter. The last solution conserves the FP cavity in which we include an Artificial Magnetic Conductor (AMC) to reduce the cavity height to 0.25λ. All these solutions are validated by measurements
9
Kristou, Nebil. « Étude et conception de métamatériaux accordables pour la miniaturisation d’antennes aux fréquences micro-ondes ». Thesis, Rennes 1, 2018. http://www.theses.fr/2018REN1S016/document.
Texte intégralRésumé :
Les antennes présentes dans la plupart des systèmes communicants comme les véhicules automobiles, les avions et les trains se multiplient et sont soumises à une contrainte d’intégration de plus en plus sévère. De nombreuses techniques de miniaturisation d’antennes existent et passent toutes par un compromis entre la taille et les performances (bande passante et/ou rendement de rayonnement). Pour les systèmes cités ci-dessus, les antennes sont souvent placées devant ou à proximité d’un réflecteur métallique (toit de véhicule, carlingue d’aéronef). Dans ce cas, l’épaisseur de système antennaire est une contrainte majeure et les métamatériaux de type Conducteur Magnétique Artificiel (CMA) ouvrent des perspectives intéressantes grâce à leurs propriétés électromagnétiques non conventionnelles. Cependant, pour les applications sub-GHz (RFID, LTE, PMR…), les CMA sont limités par les dimensions des cellules unitaires nécessaires à leur mise en œuvre (λg/4) ainsi que leur bande réduite de fonctionnement. Réduire leurs dimensions permet de rendre leur utilisation compatible avec le contexte des antennes miniatures intégrées. Ajouter l’agilité fréquentielle permet de palier le problème de la bande passante réduite dans le cas des antennes et des CMA miniaturisés en ajustant le fonctionnement du système antennaire sur une large bande passante. Cette thèse de doctorat propose d’étudier et de développer un nouveau système antennaire à faible profil composé d’une antenne miniature associée à une métasurface compacte reconfigurable en fréquence et compatible avec le standard NB-IoT dans la bande basse LTE (700 MHz – 960 MHz)Antennas are now very integrated in several connected systems like cars, airplanes and trains. Many antenna miniaturization techniques exist and all go through a compromise between size and performance (bandwidth and/or radiation efficiency). For the systems mentioned above, the antennas are often placed near a metallic reflector (vehicle roof, aircraft cabin). Within this context, Artificial Magnetic Conductors (AMC) present an attractive reflector for low profile antennas which can take advantage of intrinsic zero reflection phase response to boost antenna performance without the need for thick quarter wave backplane. However, for sub-GHz applications (RFID, LTE, PMR ...), AMC are limited by the size of the unit cells necessary for their implementation (λg/4) as well as their reduced operating bandwidth. AMC miniaturization makes their use compatible with small antennas. Adding tunability restores the possibility of adjusting the operating frequency over a large bandwidth. This PhD thesis proposes to study and develop a new electrically small, low-profile antenna based on miniaturized and tunable AMC for the NB-IoT standard in low LTE band (700 MHz – 960 MHz)
10
Silva, Pimenta Marcio. « Antennes souples à base de métamatériaux de type conducteurs magnétiques artificiels pour les standards de systèmes de géolocalisation ». Phd thesis, Université Nice Sophia Antipolis, 2013. http://tel.archives-ouvertes.fr/tel-00923200.
Texte intégralRésumé :
Grâce aux progrès réalisés ces dernières années dans la conception de réseaux intelligents, tels que les réseaux centrés sur la personne (WBAN) ou les réseaux sans fils de proximité (WPAN), de nouveaux types d'applications émergent et utilisent des capteurs d'informations capables de relever les paramètres physiologiques, environnementaux et plus particulièrement le positionnement des personnes. Dans ce cadre, nous nous sommes attachés dans ce travail de recherche à la conception et la réalisation d'antennes en polarisation circulaire pouvant être intégrées dans des vêtements, pour les standards de géolocalisation européen Galiléo et Américain GPS. Nous avons utilisé pour ces antennes des structures métamatériaux de type conducteurs magnétiques artificiels, afin d'augmenter les performances en rayonnement et pour diminuer le couplage avec et le corps humain. Une autre voie explorée est l'utilisation d'antennes patchs qui sont de nature faible encombrement. La bande de fréquence du standard de communications par satellite Iridium étant très proche du standard de géolocalisation GPS, nous avons trouvé intéressant de développer une solution de type patch couvrant les deux bandes GPS (1,575 GHz) et Iridium (1,621 GHz). L'antenne devant être intégrée sur une boite crânienne, les niveaux de débit d'absorption spécifique et les modifications du rayonnement sous conformation de l'antenne ont également été étudiés. L'évolution de ce travail a été ensuite d'étudier le comportement de cette antenne posée sur le dessus d'un casque militaire français. Les performances en rayonnement ont été satisfaisantes et ont montré la possibilité d'une telle application.
11
CHAUHAN, MANOJ SINGH. « INVESTIGATION OF ELECTROMAGNETIC BAND GAP STRUCTURES FOR MICRO STRIP PATCH ANTENNA ». Thesis, 2014. http://dspace.dtu.ac.in:8080/jspui/handle/repository/15452.
Texte intégralRésumé :
The main objective of this dissertation “Investigation of Electromagnetic Band Gap
Structures for Micro Strip patch Antenna” is to design and simulate the various electromagnetic
band gap (EBG) structure in order to investigate their frequency band gap region and reflection phase
characteristic for micro strip antenna parameter improvement. Range of frequency region at which
wave cannot propagate in the material is known as frequency band gap region and variation in phase of
a reflected wave is produced by a surface determined by the reflection phase property.
Two dimensional mushroom-like EBG structures have been investigated in this dissertation.
The equivalent LC circuit of EBG structure acts as two dimensional electric filter to block the flow of
wave. Frequency band gap property is investigated by dispersion diagram, scattering parameter method
and reflection phase property is investigated by wave guide method.
Electromagnetic Interference (EMI) is a source of noise problems in electronic devices. The
EMI is attributed to coupling between sources of radiation and components placed in the same media
such as substrate or chassis. This coupling can be either through conducting currents or through
radiation. The radiation of electromagnetic (EM) fields is supported by surface currents. Thus,
minimization of these surface currents is considered a major and critical step to suppress EMI. In this
dissertation, A novel EBG strategy is presented to confine surface currents in antenna substrate.
Traditional use of lossy materials and absorbers suffers from considerable disadvantages including
mechanical and thermal reliability leading to limited life time, cost, volume, and weight. Here, a new
method of EM noise suppression is introduced into micro strip patch antennas using mushroom-type
EBG structures. These structures are suitable for suppressing surface currents within a frequency band
denoted as the band gap. The effectiveness of the EBG as an EMI suppresser is demonstrated using
numerical simulations CST Software. Applications of EBG structure in micro strip antennas are
investigated, in which surface wave of micro strip antenna substrate is suppressed by dual layer of EBG
around the micro strip patch. Significant improvement in return loss and bandwidth has been achieved.
v
EBG structure also exhibit property of artificial magnetic conductor (AMC) in a certain
frequency range. Phase of reflected wave do not change in this frequency region. PEC ground plane in
micro strip antenna gives 180 degree phase shift, which rise the disadvantage of distractive interference
between incident wave and reflected wave of micro strip antenna .When PEC ground plane is replaced
by AMC ground plane, it gives the constructed interference. Micro strip antenna with AMC ground
plane has been investigated. Significant improvement in return loss has been achieved of micro strip
antenna.
12
Peng, Guan-Fu, et 彭冠富. « Design of a Novel Artificial Magnetic Conductor ». Thesis, 2009. http://ndltd.ncl.edu.tw/handle/60437937815906937556.
Texte intégralRésumé :
碩士國立彰化師範大學
電信工程研究所
97
In this thesis, we propose a novel artificial magnetic conductor(AMC) structure using wire helix in a metal box. This structure is equivalent to a parallel resonant LC circuit resulting in some kinds of characteristics like the perfect magnetic conductor(PMC) at resonance frequency. Due to the periodic arrangement of this structure, the electromagnetic band-gap(EBG) effect will appear in this specific band. First, we calculate the effective AMC bandwidth with reflection phase between 45 degrees for AMC with infinite elements case by a numerical analysis model. Simulated radiation patterns for half-wavelength dipole antenna on the AMC is compared with those of the same half-wavelength dipole antenna on the PMC. Our proposed AMC structure is verified to have the characteristics of PMC from 1.95 GHz to 2.75 GHz. We also study the characteristics of EBG of this AMC structure by suspended microstrip method. One of the measured EBG band is from 2.765 GHz to 2.934 GHz.
13
Hsu, Sheng-Chieh, et 許勝傑. « Reflection Characteristics of a Gradient Artificial Magnetic Conductor ». Thesis, 2010. http://ndltd.ncl.edu.tw/handle/37128951384019539623.
Texte intégralRésumé :
碩士國立交通大學
電信工程研究所
99
We studied the electromagnetic reflection of a two-dimensional square patches array backed with a grounded dielectric slab. By tuning the size of the metal patch, the adjacent two patches may have an equal reflected-phase angle. Using this property of progressively reflected-phase angle in the array elements, for a normal incident wave we can steer the reflected wave into a desired direction. In this thesis, we have established a simple formula based on the array antenna theory to figure out the reflected wave pattern. Moreover, a time-domain full-wave simulation package (CST) was employed to rigorously calculate the electromagnetic fields in the structure as well as the far-field pattern. Besides, we have fabricated the structure and measured its scattering pattern in an electromagnetic anechoic chamber. The excellent measured results confirm the design principle and procedures in this research. Such a planar structure may have potential applications in beam-tilting and radar cross section reduction.
14
Yang, Cheng-Yan, et 楊承諺. « Design of Tag Antennas with Artificial Magnetic Conductor for On-Body Applications ». Thesis, 2015. http://ndltd.ncl.edu.tw/handle/97448130247265925963.
Texte intégralRésumé :
碩士國立宜蘭大學
電子工程學系碩士班
104
This thesis aims at designing UHF RFID tag antennas with artificial magnetic conductor and a circularly polarized(CP) antenna for on-body applications. UHF radio frequency identification (RFID) technology is capable of being used to monitor and identify objects or people. By using backscattering modulation to communicate between a reader and tags, UHF RFID has a relatively far reading range, quick data transferring rate, large data carrying capacity and other advantages. However, when on-body applications are required, the input impedance, radiation pattern, realized gain and reading range of tags are influenced due to human-body dissipations effect. Here, two kinds of artificial magnetic conductor placed on the back plane of a miniaturized dipole tag are studied in order to insulate the influence from the human body. The designed tag antennas with artificial magnetic conductor can operate in the UHF RFID band (902-928 MHz). In this thesis, a unit cell of a patch-type artificial magnetic conductor (AMC) is proposed in the beginning. The unit cell size of the AMC is 55×55 mm2(0.168λ0 × 0.168λ0 mm2). To miniaturize the AMC size and lower the first resonant frequency, four T-type slots are symmetrically inserted into each side of the metal patch so that the operating frequency is reduced to 915 MHz. The second kind of unit cell structure for the miniaturized AMC is then proposed. This kind of AMC has capacitive interdigital structures which are the key design factor for designing smaller unit cells at the low operating frequency. The size of the unit cell is shrunk to 40×40 mm2 (0.122λ0 × 0.122λ0 mm2). On the other hand, a T-matching network is employed to transform the impedance of a folded dipole to conjugate match with a Monza®4 microchip. The proposed antennas are analyzed and designed in free space. The designed tag antenna is simulated by the EM simulator, HFSS. The simulation results are compared with those by the FEKO EM simulator to verify numerical accuracy. Finally, the design structure is also constructed to verify the simulation results. In the third chapter, two kinds of tag antenna with AMC are presented and discussed. One is the folded dipole antenna with T-slot AMC and the other is the dipole antenna with miniaturized AMC. The bandwidth, gain and radiation efficiency are analyzed as the influence of body proximity is considered. The proposed antennas with AMC are fabricated to perform measurement. The reading range can achieve up to 8 meters when the tag is put close to the human body. In chapter 4, a miniaturized CP tag antenna is proposed in order to improve the reading range. Theoretically, a circularly polarized antenna does not have 3 dB polarization losses as compared with a linear tag antenna since a UHF reader always radiates a CP wave. A cross-coupled CP-tag antenna which has a symmetric matching network is presented and studied. Two asymmetrically orthogonal cross-dipoles with meander lines are combined to generate a degenerate mode for circular polarization. The geometry size of the proposed tag is only 60×60 mm2. In the free space, the simulated impedance bandwidth of the CP tag antenna achieves 82 MHz (893-974 MHz, 8.6 %), the 3dB band-width is 16 MHz (916-930 MHz, 1.5 %), and the realized gain is 1.95 dBic, which make it achieve a 12 m reading range.
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Kern, Douglas John Werner Douglas H. « Advancements in artificial magnetic conductor design for improved performance and antenna applications ». 2009. http://etda.libraries.psu.edu/theses/approved/WorldWideIndex/ETD-4373/index.html.
Texte intégral
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HONG, JHIH-HAN, et 洪志翰. « Design of Circularly Polarized Tag Antenna with Artificial Magnetic Conductor for On-Body Applications ». Thesis, 2017. http://ndltd.ncl.edu.tw/handle/422486.
Texte intégralRésumé :
碩士國立宜蘭大學
電子工程學系碩士班
105
This thesis aims at designing UHF tag antennas with artificial magnetic conductor (AMC) for on-body UHF RFID applications. RFID technology has extensive applications in the world markets. In the development of the IOT, there will be various kinds of object using tag antennas to transfer information. Even in case of developing for on-body applications, the wearable device or tags will be indispensable. Whenever the tag is applied on the different objects, the performance of the tag will be changed by the material of object. Designers must seriously consider the object effects on the RFID tags. If the object is a lossy media, the antenna gain will significantly decrease. Therefore, we designed various tag antennas with artificial magnetic conductor. When the tag antenna is pasted on a human body or metal objects, AMC can effectively isolate the bad effects and then read range is increased in the applications. In the thesis, we used the concept of the PDAMC (Polarization-dependent artificial magnetic conductor) to convert the linearly polarized tag dipole into the circularly polarized (CP) tag. The PDAMC makes the tag reduce the polarization loss of 3 dB for CP reader applications and it also insulate the interference of human body. Thus, the dipole tag has farther read range and its predicted read range can achieve 16 meters. Our research results demonstrate that the tags antenna can be completely pasted on the AMC surface to achieve the design of the thinnest thickness. The study of circularly polarized antennas is more complex than linear polarized antennas in the field of the AMC research. We proposed a CP cross-dipole tag which was integrated on a square AMC structure. The substrate of the cross-dipole can be pasted on the surface of a 3×3 AMC to achieve the goal of thin thickness. The total thickness is only 6.4 mm. For on-body applications, the read range of the CP tag was significantly increased by the AMC substrate. The read range of 15.7 meters was measured by using a reader of 4W EIRP when the tag was pasted on a human body. In order to develop a wearable antenna for on-body applications, we also explored the design by using latex substrate which is a flexible material. Since the latex substrate has features of low weight, flexible and non-absorbent, the CP tag was designed directly on the AMC latex substrate. The study finds that the predicted read range achieves 17.5 meters but the size is a little large. Furthermore, the number of the AMC array was further reduced to miniaturize the array size. The CP cross-slot antenna was integrated with a 2×2 AMC structure to achieve the smallest area which is only 131×131×6.4 mm3. In addition to reducing the numbers of AMC array, the proposed miniaturized AMC was designed by using cross-slots cut on the conduct of a unit cell AMC. When the tag is integrated on the miniaturized 3×3 AMC, the read range achieves around 10.8 meters.
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Han-LinYue et 岳翰林. « Research on Millimeter-Wave CMOS On-Chip Antennas and Artificial Magnetic Conductor (AMC) Antennas ». Thesis, 2012. http://ndltd.ncl.edu.tw/handle/18268790475031752540.
Texte intégral
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Nafe, Mahmoud. « Gain-Enhanced On-Chip Antenna Utilizing Artificial Magnetic Conductor Reflecting Surface at 94 GHz ». Thesis, 2015. http://hdl.handle.net/10754/565638.
Texte intégralRésumé :
Nowadays, there is a growing demand for high frequency-bandwidth mm-wave (30-300 GHz) electronic wireless transceiver systems to support applications such as high data-rate wireless communication and high resolution imaging. Such mm-wave systems are becoming more feasible due to the extreme transistor downscaling in silicon-based integrated circuits, which enabled densely-integrated high-speed elec- tronics operating up to more than 100 GHz with low fabrication cost. To further enhance system integrability, it is required to implement all wireless system compo- nents on the chip. Presently, the last major barrier to true System-on-Chip (SoC) realization is the antenna implementation on the silicon chip.
Although at mm-wave frequencies the antenna size becomes small enough to fit on chip, the antenna performance is greatly deteriorated due the high conductivity and high relative permittivity of the silicon substrate. The negative e↵ects of the silicon substrate could be avoided by using a metallic reflecting surface on top of silicon, which e↵ectively isolates the antenna from the silicon. However, this approach has the shortcoming of having to implement the antenna on the usually very thin silicon oxide layer of a typical CMOS fabrication process (10’s of μm). This forces the antenna to be in a very close proximity (less than one hundredth of a wavelength) to the reflecting surface. In this regime, the use of conventional metallic reflecting
surface for silicon shielding has severe e↵ects on the antenna performance as it tends to reduce the antenna radiation resistance resulting in most of the energy being absorbed rather than radiated.
In this work, the use of specially patterned reflecting surfaces for improving on- chip antenna performance is investigated. By using a periodic metallic surface on top of a grounded substrate, the structure can mimic the behavior of a perfect mag- netic conductor, hence called Artificial Magnetic Conductor (AMC) surface. Unlike conventional ground plane reflecting surfaces, AMC surfaces generally enhance the radiation and impedance characteristics of close-by antennas. Based on this property, a ring-based AMC reflecting surface has been designed in the oxide layer for on-chip antennas operating at 94 GHz. Furthermore, a folded dipole antenna with its associ- ated planar feeding structures has been optimized and integrated with the developed ring-based AMC surface. The proposed design is then fabricated at KAUST clean- room facilities. Prototype characterization showed very promising results with good correlation to simulations, with the antenna exhibiting an impedance bandwidth of 10% (90-100 GHz) and peak gain of -1.4 dBi, which is the highest gain reported for on-chip antennas at this frequency band without the use of any external o↵-chip components or post-fabrication steps.
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« High Impedance Surface Using A Loop With Negative Impedance Elements ». Master's thesis, 2010. http://hdl.handle.net/2286/R.I.8791.
Texte intégralRésumé :
abstract: Antennas are required now to be compact and mobile. Traditional horizontally polarized antennas are placed in a quarter wave distance from a ground plane making the antenna system quite bulky. High impedance surfaces are proposed for an antenna ground in close proximity. A new method to achieve a high impedance surface is suggested using a metamaterial comprising an infinite periodic array of conducting loops each of which is loaded with a non-Foster element. The non-Foster element cancels the loop's inductance resulting in a material with high effective permeability. Using this material as a spacer layer, it is possible to achieve a high impedance surface over a broad bandwidth. The proposed structure is different from Sievenpiper's high impedance surface because it has no need for a capacitive layer. As a result, however, it does not suppress the propagation of surface wave modes. The proposed structure is compared to another structure with frequency selective surface loaded with a non-Foster element on a simple spacer layer. In particular, the sensitivity of each structure to component tolerances is considered. The proposed structure shows a high impedance surface over broadband frequency but is much more sensitive than the frequency selective surface structure.Dissertation/Thesis
M.S. Electrical Engineering 2010
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YiWu et 吳易. « 60- and 77-GHz Millimeter-Wave CMOS On-Chip Artificial-Magnetic-Conductor Antennas and Integrated Phased-Array Antenna RFIC ». Thesis, 2014. http://ndltd.ncl.edu.tw/handle/h99u3g.
Texte intégralRésumé :
碩士國立成功大學
電腦與通信工程研究所
102
This thesis presents the research of millimeter-wave (MMW) CMOS on-chip antennas fabricated using TSMC 90-nm and 0.18-μm CMOS standard process. The three-dimensional (3D) EM simulator HFSS is used for design and simulation. The designed MMW on-chip antennas including: (1) a 60-GHz CMOS integrated on-chip artificial-magnetic-conductor (AMC) spiral monopole-antenna with compact folded loop dual-mode bandpass filter; (2) a 60-GHz CMOS AMC bandpass-filtering spiral monopole-antenna; (3) a 77-GHz CMOS AMC 1×2 folded dipole antenna array; (4) a 60-GHz CMOS AMC 2×2 monopole-antenna phased array receiving subsystem with integrated aariable-gain low-noise amplifier (VG-LNA) and phase shifter. The AMC structures are utilized in the designed on-chip antenna to reduce the CMOS substrate loss and improve radiation efficiencies. The measured performances of the designed MMW on-chip antennas are all conducted by the on-wafer measurement setup.
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Yung-HsiagnChuang et 莊詠翔. « Research on 60- and 77-GHz GIPD On-Chip Antenna / Filtering-Antennas and CMOS Artificial Magnetic Conductor (AMC) Antennas ». Thesis, 2012. http://ndltd.ncl.edu.tw/handle/23845646976160362070.
Texte intégralRésumé :
碩士國立成功大學
電腦與通信工程研究所
100
This thesis presents the design of millimeter-wave (MMW) GIPD and CMOS on-chip antennas. The GIPD and CMOS MMW on-chip antennas are fabricated with tMt GIPD process and TSMC 90-nm CMOS standard process, respectively. The three-dimensional (3D) EM simulator HFSS is used for design simulation. The designed MMW on-chip antennas including: (1) a 77-GHz GIPD integrated on-chip Yagi antenna with balun-bandpass filter, which combined three passive components (antenna, balun, bandpass filter) of the MMW receiver front-end; (2) a 77-GHz CMOS integrated on-chip AMC-Yagi antenna with balun-bandpass filter, in which an artificial magnetic conductor (AMC) between antenna and Si-substrate is placed to improve radiation efficiency; (3) a 77-GHz GIPD integrated on-chip linear tapered slot antenna (LTSA) with unbalanced-to-balanced bandpass filter, in which two sides of the LTSA are corrugated with rectangular gratings to increase the antenna power gain and F/B ratio; (4) a 60-GHz unbalanced-fed bandpass-filtering dipole/Yagi antennas with bandpass response. The measured performances of the designed MMW on-chip antennas are all performed by using the on-wafer measurement setup.
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Huang, Chien-Jung, et 黃建融. « Formulation of a Standard Flow Chart of Feeding the Low Profile Antenna and Extraction of the Artificial Magnetic Conductor Band from the Reflection Phases ». Thesis, 2013. http://ndltd.ncl.edu.tw/handle/97925226528887092232.
Texte intégralRésumé :
碩士國立交通大學
電信工程研究所
102
A popular way to design a low profile antenna is by combining the traditional antenna with a high impedance surface (HIS), because the HIS can mimic the property of the perfect magnetic conductor (PMC) to improve the radiation. However, the way to feed the low profile antenna is still a big issue because the artificial magnetic conductor (AMC) condition of the HIS is a frequency-dependent property. It means the frequency band in which the PMC property of the HIS prevails is limited. This band is termed as the AMC region. There had been intensive research performed on the low profile antenna but there has not been a consistent, let alone identical method for feeding the low profile antenna. In consideration of that, matching the low profile antenna by a systematic way is our purpose. To fulfill our idea, we should introduce the reflection phase first, because when talking about the HIS structure, many researchers usually characterize the AMC region of the HIS by the frequency range in which the reflection phase lies between ±45° (0° of reflection phase pertains to PMC property). However, this does not consider the radiation pattern of the traditional antenna. Because the reflection phase of the general definition is defined by the normal incident wave, the waves excited by the traditional antenna on the HIS are not all normal incident waves toward the HIS. Therefore surveying the pattern of the traditional antenna becomes the priority to extract the AMC band.
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Alibakhshikenari, M., B. S. Virdee, C. H. See, Raed A. Abd-Alhameed, F. Falcone et E. Limiti. « High-gain metasurface in polyimide on-chip antenna based on CRLH-TL for sub-terahertz integrated circuits ». 2020. http://hdl.handle.net/10454/17985.
Texte intégralRésumé :
YesThis paper presents a novel on-chip antenna using standard CMOS-technology based on metasurface implemented on two-layers polyimide substrates with a thickness of 500 μm. The aluminium ground-plane with thickness of 3 μm is sandwiched between the two-layers. Concentric dielectric-rings are etched in the ground-plane under the radiation patches implemented on the top-layer. The radiation patches comprise concentric metal-rings that are arranged in a 3 × 3 matrix. The antennas are excited by coupling electromagnetic energy through the gaps of the concentric dielectric-rings in the ground-plane using a microstrip feedline created on the bottom polyimide-layer. The open-ended feedline is split in three-branches that are aligned under the radiation elements to couple the maximum energy. In this structure, the concentric metal-rings essentially act as series left-handed capacitances CL that extend the effective aperture area of the antenna without affecting its dimensions, and the concentric dielectric rings etched in the ground-plane act as shunt left-handed inductors LL, which suppress the surface-waves and reduce the substrates losses that leads to improved bandwidth and radiation properties. The overall structure behaves like a metasurface that is shown to exhibit a very large bandwidth of 0.350–0.385 THz with an average radiation gain and efficiency of 8.15dBi and 65.71%, respectively. It has dimensions of 6 × 6 × 1 mm3 that makes it suitable for on-chip implementation.
This work is partially supported by RTI2018-095499-B-C31, Funded by Ministerio de Ciencia, Innovación y Universidades, Gobierno de España (MCIU/AEI/FEDER,UE), and innovation programme under grant agreement H2020-MSCA-ITN-2016 SECRET-722424 and the fnancial support from the UK Engineering and Physical Sciences Research Council (EPSRC) under grant EP/E022936/1.
Research Development Fund Publication Prize Award winner, March 2020