Global ETD Search

21	Some optical and magnetic properties of F-centers in colored alkali halide crystals / Rauch, Conrad J. January 1955 (has links) No description available. Physics Halides Crystals Alkali metal halides Physical optics
22	Fast Physical Optics Calculation for SAR Imaging of Complex Scatterers Zhao, Yuanhong 25 June 2012 (has links) No description available. Electromagnetics Fast Physical Optics Self-shadowing Gordon't method SAR imaging
23	Estudo de materiais fotorrefrativos e suas aplicações no processamento óptico holográfico de informação / Study of photorefractive materials and their applications in holographic optical processing of information Gesualdi, Marcos Roberto da Rocha 31 January 2005 (has links) O Estudo de Materiais Fotorrefrativos e suas Aplicações no Processamento Óptico Holográfico de Informação vêm sendo feitos por diversos Grupos de Pesquisas em vários laboratórios devido aos bons resultados obtidos com esses meios em diversas áreas. Entre outros efeitos foto-induzidos o processo que possibilita essas aplicações é o efeito fotorrefrativo, um fenômeno onde o registro holográfico no meio fotorrefrativo ocorre pela modulação do índice de refração de acordo com a distribuição espacial da intensidade da luz incidente, devido a uma redistribuição foto-induzida de cargas espaciais, e conseqüente, geração de um campo espaço-carga no meio. Neste trabalho, estuda-se a propagação e acoplamento de ondas eletromagnéticas em monocristais elétro-ópticos paraelétricos da Família das Silenitas \'BI IND. 12\'\'SI\'\'O IND. 20\' (BSO) e \'BI IND. 12\'\'TI\'\'O IND. 20\' (BTO) e nos ferroelétricos \'LI\'\'NB\'\'O IND. 3\' puros e dopados. O propósito de estudar esses materiais é caracterizá-los e, principalmente, otimizá-los para aplicação no processamento óptico e holográfico de informação. Utiliza-se técnicas de caracterização de redes holográficas fotorrefrativas e de lentes foto-induzidas para determinação de figuras de mérito e parâmetros fotorrefrativos e termo-ópticos nestes meios fotorrefrativos. Propõe-se também algumas aplicações no processamento óptico e holográfico de informação, nas áreas de pesquisa básica, tecnológicas e biomédicas, que vêm despertando grande interesse nos últimos anos, como holografia em tempo real com mapeamento de fase, interterometria speckle em tempo real e registro não-holográfico no processo de conversão incoerente-incoerente; entre outras no processamento óptico e holográfico de dados. / The Study of Photorefractive Materials and their Applications in Optical and Holographical Information Processing come being made for diverse Groups of Research in some laboratories due to the good results in many areas. Among other photo-induced effects, the process that allows these applications is the photorefractive effect, a phenomenon where the holographic recording in photorefractive medium occurs by means of the refractive index modulation due to the space distribution of the light intensity, producing a space-charge photo-induced redistribution, and consequently, the generation of a space-charge field governed by an electro-optic medium. In this work, we study the propagation and coupling of electromagnetic waves in electro-optic monocrystals of the sillemite family Bi12SiO20 (BSO) and Bi12TiO20 (BTO) and in the pure and dop-ed LiNbO3 crystals. The purpose to study these materials is to characterize them and, mainly, to optimize the conditions of their application in the optical and holographical information processing. We use photorefractive holographic gratings and photo-induced lens techniques for determination of figures of merit and photorefractive and thermo-optic parameters in these photorefractive materials. We also consider some applications in the optical and holographical information processing in the research basic, technological and biomedical areas, that come waken great interest in the last years, as phase- shifting real-time holography, real-time speckle interferometry and non-holographic recording with incoherent-incoherent conversion process; among others in the optic and holographic data processing. Física óptica Holografia Holography Interference of light Interferência da luz Optical signal processing Physical optics Processamento de sinais ópticos
24	Approximations of Integral Equations for WaveScattering Atle, Andreas January 2006 (has links) <p>Wave scattering is the phenomenon in which a wave field interacts with physical objects. An incoming wave is scattered at the surface of the object and a scattered wave is produced. Common practical cases are acoustic, electromagnetic and elastic wave scattering. The numerical simulation of the scattering process is important, for example, in noise control, antenna design, prediction of radar cross sections and nondestructive testing.</p><p>Important classes of numerical methods for accurate simulation of scattering are based on integral representations of the wave fields and theses representations require the knowledge of potentials on the surfaces of the scattering objects. The potential is typically computed by a numerical approximation of an integral equation that is defined on the surface. We first develop such numerical methods in time domain for the scalar wave equation. The efficiency of the techniques are improved by analytic quadrature and in some cases by local approximation of the potential.</p><p>Most scattering simulations are done for harmonic or single frequency waves. In the electromagnetic case the corresponding integral equation method is called the method of moments. This numerical approximation is computationally very costly for high frequency waves. A simplification is suggested by physical optics, which directly gives an approximation of the potential without the solution of an integral equation. Physical optics is however only accurate for very high frequencies.</p><p>In this thesis we improve the accuracy in the physical optics approximation of scalar waves by basing the computation of the potential on the theory of radiation boundary conditions. This theory describes the local coupling of derivatives in the wave field and if it is applied at the surface of the scattering object it generates an expression for the unknown potential. The full wave field is then computed as for other integral equation methods.</p><p>The new numerical techniques are analyzed mathematically and their efficiency is established in a sequence of numerical experiments. The new on surface radiation conditions give, for example, substantial improvement in the estimation of the scattered waves in the acoustic case. This numerical experiment corresponds to radar cross-section estimation in the electromagnetic case.</p> Integral equations Marching on in time On surface radiation condition Physical Optics Numerical analysis Numerisk analys
25	Approximations of Integral Equations for WaveScattering Atle, Andreas January 2006 (has links) Wave scattering is the phenomenon in which a wave field interacts with physical objects. An incoming wave is scattered at the surface of the object and a scattered wave is produced. Common practical cases are acoustic, electromagnetic and elastic wave scattering. The numerical simulation of the scattering process is important, for example, in noise control, antenna design, prediction of radar cross sections and nondestructive testing. Important classes of numerical methods for accurate simulation of scattering are based on integral representations of the wave fields and theses representations require the knowledge of potentials on the surfaces of the scattering objects. The potential is typically computed by a numerical approximation of an integral equation that is defined on the surface. We first develop such numerical methods in time domain for the scalar wave equation. The efficiency of the techniques are improved by analytic quadrature and in some cases by local approximation of the potential. Most scattering simulations are done for harmonic or single frequency waves. In the electromagnetic case the corresponding integral equation method is called the method of moments. This numerical approximation is computationally very costly for high frequency waves. A simplification is suggested by physical optics, which directly gives an approximation of the potential without the solution of an integral equation. Physical optics is however only accurate for very high frequencies. In this thesis we improve the accuracy in the physical optics approximation of scalar waves by basing the computation of the potential on the theory of radiation boundary conditions. This theory describes the local coupling of derivatives in the wave field and if it is applied at the surface of the scattering object it generates an expression for the unknown potential. The full wave field is then computed as for other integral equation methods. The new numerical techniques are analyzed mathematically and their efficiency is established in a sequence of numerical experiments. The new on surface radiation conditions give, for example, substantial improvement in the estimation of the scattered waves in the acoustic case. This numerical experiment corresponds to radar cross-section estimation in the electromagnetic case. Integral equations Marching on in time On surface radiation condition Physical Optics Numerical analysis Numerisk analys
26	Sección recta de blancos radar complejos en tiempo real Rius Casals, Juan Manuel 08 July 1991 (has links) Este trabajo resuelve el problema de gran interés para la industria aeronáutica: el cálculo de la sección recta (RCS) de blancos radar complejos en tiempo real. Para ello basta una estación de trabajo con un acelerador grafico 3-d hardware en lugar de los super-ordenadores vectoriales que requieren los métodos clásicos. El método desarrollado totalmente original e innovador, consiste en procesar gráficamente una imagen del blanco presente en la pantalla de la estación grafica. Con ello se consigue que el tiempo de cpu sea independiente del tamaño y complejidad del blanco, con lo que su principal aplicación es la estimación rápida de la RCS de blancos radar complejos. Este método, al que hemos denominado "procesado grafico", implementa las aproximaciones asintóticas de alta frecuencia que permiten obtener las principales contribuciones a la RCS: óptica física, para la reflexión en superficies; condiciones de contorno de impedancia, para la reflexión en recubrimientos absorbentes radar (RAM), método de las corrientes equivalentes para la disposición en aristas y un método grafico de iluminación global (radiosity) para las reflexiones múltiples entre superficies. Los resultados de este trabajo hacen posible, por vez primera, el diseño interactivo de formas de baja RCS "stealth" con una estación de trabajo, por lo que se ha conseguido una herramienta software para la industria aeronáutica de gran eficiencia y potencialidad en sus aplicaciones. antennas numerical computation radar cross section greco physical optics 62 621.3
27	Propriedades ópticas de materiais híbridos de sílica dopados com nanocristais de CdSe/ZnS Alencar, Lorena Dariane da Silva [UNESP] 26 February 2014 (has links) (PDF) Made available in DSpace on 2014-08-13T14:50:46Z (GMT). No. of bitstreams: 0 Previous issue date: 2014-02-26Bitstream added on 2014-08-13T18:00:41Z : No. of bitstreams: 1 000756517.pdf: 1734857 bytes, checksum: 281f33b4567ed911763af72805522884 (MD5) / Fundação de Amparo à Pesquisa do Estado de São Paulo (FAPESP) / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior (CAPES) / Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq) / Materiais híbridos de Sílica modificados organicamente (ORMOSIL) são muito estudados devido à variedade de alcóxidos funcionalizados com moléculas orgânicas (epóxi, vinil, amina, fenil, etc). O estudo das propriedades de materiais híbridos de sílica/orgânico preparados via sol-gel dopados com nanocristais de semicondutores do tipo núcleo/casca é de grande interesse, pois possibilita que propriedades ópticas e mecânicas sejam controladas a partir da síntese, produzindo materiais multifuncionais que apresentam características híbridas da matriz sílica/orgânico aliada aos fenômenos ópticos produzidos pelo dopante. Neste trabalho foram estudadas as propriedades ópticas de matrizes de sílica/orgânico à base de 3-glicidoxipropiltrimetoxisilano (GPTS) e tetraetilortosilicato (TEOS) preparadas pelo processo sol-gel, dopadas com nanocristais de CdSe/ZnS. As matrizes híbridas dopadas foram caracterizadas por espectroscopia óptica (absorção óptica e luminescência UV/VIS) e espectroscopia termo-óptica (lente térmica). Nanocristais de CdSe/ZnS com três tamanhos diferentes de núcleos (~2 a 5 nm) e banda de emissão centrada em 525, 560 e 615 nm (verde, laranja e vermelho, respectivamente) foram estudados quando inseridos na matriz híbrida e as caracterizações foram realizadas in-situ na matriz desde o estado inicial sol e durante a cinética de gelificação. Durante a cinética de gelificação, catalisada pela adição de NH4OH, foi observado a diminuição da intensidade de luminescência dos nanocristais com mínimo no ponto de gel da matriz e subsequente desvio para o azul com acentuado aumento da intensidade de luminescência relacionada com a consolidação da matriz. Através dos espectros de densidade óptica foi possível determinar a variação da energia de gap das amostras durante a cinética de gelificação. As medidas de lente térmica foram realizadas usando laser de excitação e prova para estudar os... / Organically Modified Silicates (ORMOSIL) have been object of study due to the variety of the organically functionalized alkoxides (epoxy, vinyl, phenyl, etc). This allows the production of new hybrid silica materials with adjustable properties depending on the organic molecule linked to silica. The study of the properties of CdSe/ZnS core-shell nanocrystals embedded in GPTS/TEOS-derived organic/silica hybrids is of high interest due the optical and mechanical properties which can be controlled from the synthesis, producing multifunctional materials. This work aims the study of the optical properties measured in situ of CdSe/ZnS nanocrystals embedded in organic/silica hybrid colloids prepared by sol-gel technique derived from 3-glycidoxypropyltrimethoxysilane (GPTS) and tetraethylorthosilicate (TEOS). Doped organic/silica hybrid matrices were characterized by optical spectroscopy (absorption and photoluminescence) and thermo-optical spectroscopy (thermal lens). CdSe/ZnS nanocrystals with three different core sizes (~2 -5 nm) and emission band centered at 525, 560 and 615 nm (green, orange and red, respectively) were studied embedded in the hybrid matrix. The optical characterizations were performed in-situ in the matrix from the initial sol and during the gelation kinetics (transition from sol to gel). During the gelation kinetics started by NH4OH addition, an intensity decrease of the nanocrystals photoluminescence was observed during the sol to gel transition, achieving minimum photoluminescence intensity exactly at the matrix gel point with subsequent blue shift and accentuated photoluminescence intensity increase related to the matrix consolidation. Through the optical absorption spectra it was possible to determine the variation in the energy gap of the samples during the kinetics of gelation. TL transient measurements were performed using the mode-mismatched dual-beam configuration to study the effect of the CdSe/ZnS embedded in... Physical optics Fisica otica Silica - propriedades óticas Nanocristais Processo sol-gel Luminescencia
28	[en] SYNTHESIS OF OMNIDIRECTINAL REFLECTOR FED BY DIELETRIC LENS ASSOCIATED WITH A COAXIAL FEED HORN / [pt] SÍNTESE DE REFLETORES OMNIDIRECIONAIS ALIMENTADOS POR LENTES DIELÉTRICAS ASSOCIADAS À CORNETA COAXIAL LISSETH SAAVEDRA PATIÑO 07 March 2017 (has links) [pt] Antenas refletoras para cobertura omnidirecional vêm sendo utilizadas em diversos estudos de micro-ondas e ondas milimétricas. A principal motivação para trabalhar nestas bandas, entre outras aplicações, é o desenvolvimento de sistemas de comunicação sem fio de banda larga. O presente trabalho utiliza uma lente dielétrica na abertura do alimentador da antena refletora para reduzir a largura do feixe e, simultaneamente, evitar a presença de lóbulos laterais na região de cobertura. Uma apropriada modelagem da lente reduz o tamanho da antena sem degradar as características de radiação. O trabalho é dividido em duas partes: a modelagem de lentes dielétricas; e a modelagem de reflertores. A modelagem de lentes dielétricas circularmente simétricas utilizando os princípios da Óptica Geométrica para controlar a largura de feixe do diagrama de radiação transmitido pela lente. O modelo é feito a partir do deslocamento do foco da geratriz da lente, o novo foco virtual é o ponto geométrico onde convergem os raios emergentes da lente. A rotação da geratriz da superfície refletora faz que este ponto se torne um anel cáustico virtual. As lentes modeladas têm como alimentador uma corneta coaxial que fornece um diagrama de radiação circularmente simétrico. O diagrama de radiação transmitido pela lente é calculado usando as aproximações da ótica geométrica e ótica física em campo distante e próximo. Os resultados são comparados com os resultados simulados em um software especializado de simulação eletromagnética. A modelagem de refletores baseada nas propriedades da Ótica Geométrica. O refletor é uma superfície de revolução obtida através da rotação de uma geratriz em torno ao eixo de simetria. Neste trabalho, a geratriz é descrita por uma sucessão de seções de cônicas concatenadas, esta metodologia utiliza o diagrama de radiação transmitido da lente para obter uma distribuição de campo no plano vertical previamente especificada, que nosso caso é uma distribuição constante. O diagrama de radiação em campo distante radiado pelo refletor é calculado usando as aproximações da física ótica, estes resultados são 6 comparados com os resultados simulados em um software especializado em simulação eletromagnética. / [en] Reflector antennas for omnidirectional coverage have been considered in several studies of microwave and millimeter wave. The main motivation to work in these bands, among other applications, is the development of wireless broadband communication systems. This work uses a dielectric lens in the aperture of the reflector antenna feeder to reduce the beamwidth and simultaneously avoid the presence of side lobes in the coverage area. An appropriate lens modeling reduces the antenna size without degrading the radiation characteristics. The work is divided into two parts: the modeling of lens and modeling of reflector.The modeling of lens using the principles of the Geometrical Optics to control the radiation pattern transmitted by the lens. The modeling depends on the lens focus displacement, which is the geometric point of convergence of the rays emerging from the lens. The rotation of the lens generatrix causes this point to become a virtual caustic ring. The lens has a coaxial feed horn that provides a circularly symmetrical radiation pattern. The radiation pattern transmitted by the lens is calculated using the approximation of Geometric Optics and Physical Optics in the near and far field; these results are compared with the simulated results in a specialized electromagnetic simulation software. The reflector modeling is based on the properties of Geometric Optics. The reflector is a revolution surface obtained by rotating a generatrix around the symmetry axis. In this work, the generatrix is described by a sequence of concatenated conical sections. This method uses the transmitted radiation pattern of the lens to obtain a previously specified field distribution in the vertical plane, which is a constant distribution in the present case. The far field radiation pattern of the reflector is calculated using the Physical Optics approximation. These results are compared with the simulated results in a specialized electromagnetic simulation software. [pt] OTICA FISICA [en] PHYSICAL OPTICS [pt] OTICA GEOMETRICA [en] GEOMETRICAL OPTICS [pt] LENTE DIELETRICA [pt] REFLETOR
29	A beam tracing model for electromagnetic scattering by atmospheric ice crystals Taylor, Laurence Charles January 2016 (has links) While exact methods, such as DDA or T-matrix, can be applied to particles withsizes comparable to the wavelength, computational demands mean that they are size limited. For particles much larger than the wavelength, the Geometric Optics approximation can be employed, but in doing so wave effects, such as interference and diffraction, are ignored. In between these two size extremes there exists a need for computational techniques which are capable of handling the wide array of ice crystal shapes and sizes that are observed in cirrus clouds. The Beam Tracing model developed within this project meets these criteria. It combines aspects of geometric optics and physical optics. Beam propagation is handled by Snell's law and the law of reflection. A beam is divided into reflected and transmitted components each time a crystal facet is illuminated. If the incident beam illuminates multiple facets it is split, with a new beam being formed for each illuminated facet. The phase-dependent electric field amplitude of the beams is known from their ampli- tude (Jones) matrices. These are modified by transmission and reflection matrices, whose elements are Fresnel amplitude coefficients, each time a beam intersects a crystal facet. Phase tracing is carried out for each beam by considering the path that its 'centre ray' would have taken. The local near-field is then mapped, via a surface integral formulation of a vector Kirchhoff diffraction approximation, to the far-field. Once in the far-field the four elements of the amplitude matrix are trans- formed into the sixteen elements of the scattering matrix via known relations. The model is discussed in depth, with details given on its implementation. The physical basis of the model is given through a discussion of Ray Tracing and how this leads to the notion of Beam Tracing. The beam splitting algorithm is described for convex particles followed by the necessary adaptations for concave and/or ab- sorbing particles. Once geometric aspects have been established details are given as to how physical properties of beams are traced including: amplitude, phase and power. How diffraction is implemented in the model is given along with a review of existing diffraction implementations. Comparisons are given, first against a modified Ray Tracing code to validate the geometric optics aspects of the model. Then, specific examples are given for the cases of transparent, pristine, smooth hexagonal columns of four different sizes and orientations; a highly absorbing, pristine, smooth hexagonal column and a highly absorbing, indented, smooth hexagonal column. Analysis of two-dimensional and one-dimensional intensity distributions and degree of linear polarisation results are given for each case and compared with results acquired through use of the Amster- dam Discrete-Dipole Approximation (ADDA) code; with good agreement observed. To the author's best knowledge, the Beam Tracer developed here is unique in its ability to handle concave particles; particles with complex structures and the man- ner in which beams are divided into sub-beams of quasi-constant intensity when propagating in an absorbing medium. One of the model's potential applications is to create a database of known particle scattering patterns, for use in aiding particle classification from images taken by the Small Ice Detector (SID) in-situ probe. An example of creating such a database for hexagonal columns is given. 551.57
30	Synthesis, characterization and application studies of cyanostilbene-based molecular materials with aggregation-induced emission (AIE) characteristics Lau, Wai Sum 25 August 2014 (has links) The molecular design, synthesis, spectroscopic and photophysical characterization of a series of cyanostilbene-based compounds are studied in this thesis. The thermal, electrochemical and aggregation induced emission (AIE) properties of these cyanostilbene-based compounds, as well as their application in organic lighting-emitting diodes, live cell imaging, chemical vapor sensor were investigated. Chapter 1 gives a brief introduction on the aggregation-caused quenching (ACQ) behavior of the conventional organic luminogens and the discovery and proposed mechanism of AIE phenomenon. Furthermore, some examples and the applications of these AIE compounds will be discussed. In Chapter 2, triphenylamine- and carbazole-containing cyanostilbene-based derivatives are presented. From the examination of the emission profile, they are all AIE-active through comparison of the photoluminescence intensity in dissolved and in aggregated states. Additionally, the calculation of the enhancement ratio (I/I0 – 1) of each fluorophore was performed in order to quantify its AIE effect. One of our cyanostilbene-based luminogens has achieved an enhancement ratio with a value of 1128. This cyanostilbene-based luminogens has also shown good performance in OLED investigation. In addition to the OLEDs application, the selected cyanostilbene-based luminogens with solid-state emission, cell-permeability and reversible switch-on/off capability have illustrated the positive result in live-cell imaging and chemical vapor sensing. Conjugated polymer with high molecular weight is the superior option by overcoming the weaknesses of low-molecular-weight luminogens with excellent thin-film form ability and comparatively simple and inexpensive fabrication processes. The design and synthesis of the cyanostilbene-based polymeric chromophores are described in Chapter 3. The polymerization of the AIE-active diacetylene ligands by connection of trans-[Pt(PBu3)2] unit at both ends has successfully retained their AIE behavior. In contrast, the ACQ problem has occurred on the polymers with organic spacers and the AIE-active ligands. From the DFT calculation on the Pt polymers and the blue shift of emission spectra in high water content suggested that the AIE phenomenon of Pt polymers is probably originated from the elimination of the non-radiative intramolecular charge transfer (ICT) process. Owing to the high demand in red-emitting materials in the applications of electroluminescent devices, fluorescent sensing and bio-imaging, effort has been made to design a system with the new chromophores with donor (D) – acceptor (A) system and thus to synthesize phenothiazine (D)-containing cyanostilbene (A)-based derivatives which are depicted in Chapter 4. Consistent with the conventional AIE-active luminogens with a successively climb of photoluminescence intensities in response to the increase of water proportion, phenothiazine-containing cyanostilbene-based derivatives has exhibited a V-shape fashion of emission intensity. It suggests that the emission of chromophores started to be quenched due to the increase of solvent polarity, overriding that of the molecular aggregation when a “small” volume of water is being introduced. While aggregate formation was dominant from the addition of a “large” amount of poor solvent, less polar local environment was created which suppressed the non-radiative transition to the ICT state and intensified the emission efficiency. Phenothiazine (D) – cyanostilbene (A) system has created a series of red-emitting chromophores with great tunability for the sake of achieving the desired emission color and better emission efficiency. To functionalize these AIE-active cyanostilbene-based chromophores, pyridine group was attached to the compounds to take the advantage of its metal-chelating capability, which is discussed in Chapter 5. The AIE features of cyanostilbene-based compounds can be preserved after the introduction of the pyridyl unit. Even it possessed a weak photoluminescence in its dilute solution which suggest that the high electron delocalization within the molecule has rigidified the structure to some extent, it is transformed to a highly emissive state with a high proportion of water. The exclusive variation of emission behavior with obvious bathochromic shift and boost of emission spectrum in the presence of cadmium-(II) ion has demonstrated its potential metal ion sensing ability. Chapter 6 and 7 present the concluding remarks and the experimental data of the compounds of Chapter 2 to 5, respectively. Electrochemical analysis Light emitting diodes Molecules Organic thin films Physical optics

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