Global ETD Search

151	Homogénéisation dynamique de milieux aléatoires en vue du dimensionnement de métamatériaux acoustiques Dubois, Jérôme 17 April 2012 (has links) Les métamatériaux sont des milieux prometteurs pour l'imagerie acoustique. Grâce à ces milieux, il est possible de concevoir des lentilles à faces parallèles pouvant dépasser la limite conventionnelle de résolution d'une lentille et par conséquent améliorer les systèmes d'imagerie. Malgré l'intérêt grandissant des chercheurs pour les métamatériaux, le comportement des ondes acoustiques dans ces milieux n'est pas totalement connu. Nous proposons de développer la problématique de la propagation des ondes acoustiques dans un milieu de type métamatériau en détail dans ce manuscrit. Cette étude a permis d'extraire un critère discriminant un métamatériau d'un matériau classique et d'apporter un regard nouveau sur l'amplification des ondes évanescentes dans les métamatériaux.Nous explorons une piste peu empruntée en vue du dimensionnement de métamatériaux : les milieux aléatoires. Nous nous focalisons sur les milieux à deux dimensions dont les phases sont fluides. Dans cette optique, une phase de validation de techniques d'homogénéisation dynamique existantes est réalisée \textit{via} la comparaison des réponses acoustiques d'un écran de diffuseurs répartis aléatoirement obtenues par des simulations numériques FDTD avec celles prédites par des modèles analytiques. L'étude de ces modèles, utiles au dimensionnement de structures aléatoires présentant des réponses acoustiques ciblées, nous a amené à examiner avec attention leur comportement quasi-statique. Une technique d'homogénéisation permettant de prendre en compte explicitement les interactions entre diffuseurs est proposée dans ce contexte. Développée dans le cadre de la diffusion simple et multiple, elle relie les propriétés mécaniques effectives aux moyennes des champs acoustiques dans un volume représentatif.Finalement, l'analyse du comportement d'un milieu aléatoire \og réaliste \fg~possédant théoriquement des bandes fréquentielles à réfraction négative, grâce à des diffuseurs résonants à basses fréquences, a été menée. Différents régimes de fonctionnement atypiques sont identifiés à l'aide de simulations numériques. La confrontation des réponses de ce milieu avec celles d'un cristal phononique est ensuite présentée et révèle une étonnante similitude entre les deux arrangements. / Metamaterials are promising media for acoustic imaging. For example, such media give the possibility to build flat lenses exhibiting sub-diffraction-limit resolution, thereby improving imaging setup. Despite the growing interest of the researcher for metamaterials, acoustic wave propagation is still not widely known. This work addresses the topic of wave propagation in metamaterials. In this work, we have defined a criterion which differentiate metamaterial from classical material and provide a new insight in the amplification of evanescent waves.We explore how to design metamaterials with random media. We focus on two dimensional media with fluid components. A validation process of existing dynamic homogenization techniques is done via the comparison between the responses of a screen of scatterers obtained by numerical simulations from FDTD with those predict by the analytical models. The study of those models, useful for designing random media with atypical responses, lead us to consider their quasi-static limit. In this context, we propose a homogenization technique which includes explicitly the interactions between scatterers. It is developed for multiple and simple scattering and link the effective properties to the averages of the acoustic fields in a representative volume.Finally, the analysis of the acoustic responses of a realistic random medium having theoretical negative refraction frequency bandwidth, thanks to low frequency resonant scatterers is done. Different atypical responses are identified from the numerical simulations. The comparison between the responses of this medium and those of phononic crystals is presented and shows a surprising similarity of the two arrangements. Diffusion multiple Diffusion simple Homogénéisation dynamique Métamatériaux acoustiques Superlentille Amplification des ondes évanescentes Multiple scattering Single scattering Dynamic homogenization Acoustic metamaterial Superlens Amplification of evanescent waves
152	The application of negative refractive index metamaterials to mm and sub-mm wavelength instrumentation Mohamed, Imran January 2013 (has links) The manipulation of electromagnetic radiation via the use of periodic arrays of sub-wavelength metallic structures (unit cells), nowadays named "metamaterials", has been known of in the microwave engineering community for over fifty years. In the last decade interest in such sub-wavelength structures grew, mainly due to their ability to interact with radiation in ways natural materials could not e.g. by producing a negative refractive index (NRI). This project sought to see whether NRI metamaterials could provide benefits to the mm and sub-mm wavelength astronomical instrumentation currently in use. To aid rapid design and optimisation of devices made from a cascaded set of metamaterial unit cells, a hybridised Transmission Line (TL) model was developed where the matrix components used in the TL model were "seeded" with data taken from a Finite Element Method (FEM) model of a simpler structure. A comparison between the two found that the TL model was capable of providing results that differed from the FEM model by no more than ~10E−4 for the transmitted intensity, \|S21\|^2, and <1° for transmitted phase, arg(S21). A slab of material with a refractive index, n = −1, can exhibit an effect known as "superlensing". A three unit cell thick NRI slab was designed, manufactured and experimentally tested. It was found to be capable of producing an NRI across a fractional band of at least 21%, producing a refractive index value of n = −1 at around 90 GHz. The experimental and simulated transmission and reflection data show good match with each other. A highly birefringent air gap Half Wave Plate (HWP) was designed, manufactured and experimentally tested. Defining its useful bandwidth as the region where the phase difference, is equal to (−180 ± 3)° a single HWP had a fractional bandwidth of 0.3%. The bandwidth was extended by using the Pancharatnam method, developed in the 1950's to produce highly achromatic optical wave plates. The method however is applicable to other frequencies and polarisation control technologies. Optimising a three HWP TL-based Pancharatnam model, the HWP's modelled fractional bandwidth increased to 6.6%. Experimental data agrees with the model showing a plateauing of the phase difference at −180°. A highly birefringent polypropylene embedded Quarter Wave Plate (QWP) was also designed, manufactured and tested. Defining its useful bandwidth as the region where the differential phase is (90 ± 2)° a single QWP produced a fractional bandwidth of 0.6%. By optimising a four QWP TL-based Pancharatnam model, the QWP's performance was improved to 7.8%. Experimental data, whilst not in complete agreement with the model does show a reduction in the gradient of phase difference where it crossed 90°. It was found that current designs for NRI metamaterials fall short of the standards required to be used in quasi-optical astronomical instrumentation due to high dispersion and absorption. The high dispersion limits NRI metamaterials to uses in instruments built for narrowband applications. Whilst the Pancharatnam method can increase bandwidths where a flat differential phase response is required, this comes at the cost of increased absorption. To reach their full potential, NRI metamaterials' lossiness must be reduced e.g. possibly by cryogenic means or the use of "active" metamaterials. 621.382
153	Synthesis of Planar Microwave Circuits based on Metamaterial Concepts through Aggressive Space Mapping Rodríguez Pérez, Ana María 30 March 2015 (has links) RF and microwave applications represent one of the fastest-growing segments of the high performance electronics market, where ongoing innovation is critical. Manufacturers compete intensively to meet market needs with reduced cost, size, weight and many other performance criteria demands. Under this scenario, transmission lines based on metamaterial concepts can be considered a very interesting alternative to the conventional transmission lines. They are more compact (compatible with planar manufacturing processes) and present higher degrees of design flexibility. Furthermore, metamaterial transmission lines can also provide many other unique properties not achievable with ordinary transmission lines, such as dispersion or impedance engineering. Nevertheless, the impact in the industry is still not relevant, mostly due to the complexity of the related synthesis and design procedures. These procedures are mainly based on the engineer’s experience, with the help of costly full-wave electromagnetic (EM) simulators and parameter extraction methods. The aim of this thesis is to contribute to simplify and speed up the synthesis and design procedures of artificial transmission lines. In particular, the lines obtained by periodically loading a conventional transmission line with electrically small resonators, such as split ring resonators (SSRs) or its complementary particle (CSRR). The design procedure is automated by using Space Mapping techniques. In contrast to other alternative methods, real synthesis is found from the circuit schematic (that provides a given target response) and without need of human intervention. Some efforts to make the method practical and useful have been carried out. Given a certain target response, it is determined whether it can be physically implemented with a chosen technology, and hence proceeding next to find the synthesis, or not. For this purpose, a two-step Aggressive Space Mapping approach is successfully proposed. In contrast to other methods, the real synthesis is found from certain target circuit values (corresponding to the equivalent circuit model that characterizes the structure to be synthesized). Different efforts have been carried out in order to implement a useful and practical method. Some of them were focused to determine if, given certain circuit parameters (which determine the target response) and certain given technology specifications (permittivity and height of the substrate, technology limits), that response is physically realizable (convergence region). This technique was successfully formulated and it is known as “Two-Step Aggressive Space Mapping Approach”. In this work, the latest improvements made till date, from the synthesis of basic unit cells until different applications and kinds of metamaterial-based circuits, are presented. The results are promising and prove the validity of the method, as well as its potential application to other basic cells and more complex designs. The general knowledge gained from these cases of study can be considered a good base for a coming implementation in commercial software tools, which can help to improve its competitiveness in markets, and also contribute to a more general use of this technology. / Rodríguez Pérez, AM. (2014). Synthesis of Planar Microwave Circuits based on Metamaterial Concepts through Aggressive Space Mapping [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/48465 / TESIS Artificial transmission lines Metamaterial transmission lines Space mapping Automated circuit synthesis Split ring resonators (SRRs) Planar filters TEORIA DE LA SEÑAL Y COMUNICACIONES
154	WIRELESS POWER TRANSFER USING OPEN-WIRE TRANSMISSION LINE COUPLING Brian J Vaughn (8052236) 14 January 2021 (has links) <div> <div> <div> <div> <p>This dissertation presents and develops a novel method of wireless power transfer that relies on electromagnetic coupling from open-wire transmission lines instead of tra- ditional methods. Wireless power transfer techniques are being rapidly pursued in re- search currently due to the potential utility of powering devices over the air instead of with direct electrical connections. Uses for such techniques include an array of ap- plications from consumer electronics, to medical devices, to cars and UAVs. While con- ventional wireless power transfer techniques exist, it is shown here that open-wire trans- mission line methods present distinct advantages for certain applications. In particular, wireless power transfer using Goubau and twin-lead line architectures will be conceptual- ized and investigated in terms of their theory, design, and efficiency performance. Fur- ther, a circuit model theory will be developed in this work to provide a generalized for- mulation for open-wire-line wireless power transfer analysis. Additionally, receiver de- sign techniques will be outlined and geometries based on metamaterial principles will be pursued in order to achieve receiver miniaturization and access the applications this af- fords. </p> </div> </div> </div> </div> Goubau line Wireless Power Transfer (WPT) transmission lines electromagnetic applications metamaterial design twin-lead transmission line
155	Optical Propagation in Anisotropic Metamaterials: Application to Analysis and Design of Metallo-Dielectric Filters AL-Ghezi, Hammid 09 August 2021 (has links) No description available. Electromagnetics Nanotechnology Nanoscience
156	Modelování mikrovlnných rezonátorů z metamateriálů / Modeling metamaterial microwave resonators Zvolenský, Tomáš January 2008 (has links) Práce je věnována modelování mikrovlnných rezonátorů z metamateriálů (materiálů se záporným indexem lomu). V úvodu je rozebráno, co metamateriály jsou, jak se vytvářejí a které jejich vlastnosti jsou podstatné při návrhu rezonátorů. Následuje návrh planárního rezonátoru z metamateriálů. Pro tento účel byly naprogramovány funkce počítající rozměry jednotlivých součástí struktury. Simulace navržené struktury probíhala v programu Zeland IE3D. Simulované struktury byly optimalizovány s ohledem na požadované kmitočty rezonance. První rezonátor sestával z jedné elementární buňky, druhý ze dvou buněk, naladěných na rozdílné kmitočty. Rezonátory byly vyrobeny a experimentálně byly ověřeny jejich vlastnosti.
157	Využití metamateriálů pro zlepšení parametrů antén / Improving antenna parameters by the application of metamaterials Šporik, Vladimír January 2009 (has links) The thesis is focused on the design of a planar resonant-type antenna, which exploits a proper combination of left- and right-handed properties of transmission lines. This transmission line is called CRLH TL and is based on Sievenpiper mushroom structure. Advantages of the proposed antenna concept are demonstrated by a detailed comparison of its basic properties with the properties of a conventional patch antenna.
158	Gradient-Index Metamaterial Infrared Detector for Enhanced Photo-Response and Image Quality Adams, Kelsa Derek 05 1900 (has links) An enhanced thermal imaging concept made possible through the development of a gradient-indexed metamaterial infrared detector that offers broadband transmission and reflection in THz waves. This thesis proposes a proof of feasibility for a metamaterial infrared detector containing an anti-reflective coating with various geometrically varying periodic metasurfaces, a gradient-indexed dielectric multilayer for near-perfect longpass filtering, and a gradient index of refraction (GRIN) metalens for enhanced focal plane thermal imaging. 2D Rigorous Coupled-Wave Analysis (RCWA) is used for understanding the photonic gratings performance based on material selection and varying geometric structure. Finite Difference Time Domain (FDTD) is used to characterize performance for a diffractive metalens by optimizing the radius and arrangement of cylindrical nanorods to create a desired phase profile that can achieve a desired focal distance for projections on a detector for near- to far-infrared thermal imaging. Through combining a micromachined anti-reflective coating, a near-perfect longpass filter, and metamaterial GRIN metalens, infrared/THz focal plane thermal imaging can obtain faster photo-response and image quality at targeted wavelengths, which allows for scientific advancements in electro-optical devices for the Department of Defense, aerospace, and biochemical detection applications. Metamaterial Metalens Infrared Detector rigorous coupled-wave analysis anti-reflection coating photonic multilayer longpass filter focal point concentration light focusing Engineering, Mechanical Physics, Optics
159	Tailoring the properties of metamaterials for linear and nonlinear applications Sydoruk, Oleksiy 13 June 2007 (has links) The thesis is devoted to magnetic metamaterials operating in the frequency range of 10 MHz 1 GHz. Mechanisms of tailoring the properties of metamaterials are developed and a number of linear and nonlinear applications is proposed.In Chapter 1, the introduction to the field of metamaterials is given and the main goal of the thesis is defined as the search for possible applications of low-frequency metamaterials. The main motivation is the potential of magnetic metamaterials in Magnetic Resonance Imaging (MRI).Chapter 2 briefly summarizes the near-field properties of magnetic metamaterials. Magnetic coupling between a pair of metamaterial elements is described and magnetoinductive (MI) waves propagating on the metamaterials arrays are introduced.In Chapter 3, the magnetic coupling between the elements is studied in more detail. Based on the analogy between MI waves and acoustic waves in solids, "diatomic" metamaterial arrays having two elements per unit cell are introduced. It is shown that by changing the resonant frequencies of the elements and the coupling between them it is possible to acquire additional freedom in tailoring the dispersion properties of MI waves compared to simple "monatomic" configurations.In Chapter 4, various linear applications of metamaterials are discussed. They are shift-dependent transmission, subwavelength imaging and focusing, and rotational resonance of MI waves. It is shown that the microscopic model based on taking the interaction between the elements into account allows for reliable explanation of the phenomena studied.In Chapter 5, a nonlinear application, parametric amplification of MI waves, is discussed. It is shown that parametric amplification can lead to the compensation of loss in metamaterials and to increase of the power extracted from an MRI detection system.Conclusions are drawn and possible directions for future work are determined in Chapter 6. Metamaterial magnetoinductive waves dispersion Magnetic Resonance Imaging subwalength imaging parametric amplification 33.16 - Elektrizität, Magnetismus 33.75 - Magnetische Materialien 29 - Physik, Astronomie ddc:620
160	Linear and Nonlinear Functions of Plasmas in Electromagnetic Metamaterials / 電磁メタマテリアルにおけるプラズマの線形及び非線形機能 Iwai, Akinori 25 March 2019 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第21732号 / 工博第4549号 / 新制\|\|工\|\|1709(附属図書館) / 京都大学大学院工学研究科電気工学専攻 / (主査)教授大村善治, 教授松尾哲司, 教授竹内繁樹 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DFAM Negative refractive index Second harmonic wave generation Electromagnetic particle simulation Negative permeability metamaterial Negative permittivity plasma High-power microwave plasma 500

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