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Développement d'un colposcope polarimétrique de Müller pour le dépistage du cancer du col utérin : premières mesures in-vivo. / Developpement of a Müller colposcope to prevent the cervical cancer : first in-vivo resultsDeby, Stanislas 26 April 2017 (has links)
Cette thèse a été consacrée au développement et à la mise en oeuvre d’un imageur polarimétrique de Müller installé sur un colposcope standard dans le but de diagnostiquer invivo des lésions précancéreuses du col utérin.Ce travail s’est appuyé sur le développement réalisé durant les dix dernières années au LPICM à l'École polytechnique d’une nouvelle technologie d'imagerie médicale non invasive et a priori adaptée à la détection précoce du cancer : l’imagerie polarimétrique. / This thesis was devoted to the development and the implementation of a polarimetric imager of Müller installed on a standard colposcope in order to diagnose invivo precancerous lesions of the cervix.This work was based on the development carried out during the last ten years at the LPICM at the Ecole polytechnique of a new non-invasive medical imaging technology and a priori adapted to the early detection of cancer: polarimetric imaging.
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Levee Slide Detection using Synthetic Aperture Radar Magnitude and PhaseMarapareddy, Ramakalavathi 11 December 2015 (has links)
The objectives of this research are to support the development of state-of-the-art methods using remotely sensed data to detect slides or anomalies in an efficient and cost-effective manner based on the use of SAR technology. Slough or slump slides are slope failures along a levee, which leave areas of the levee vulnerable to seepage and failure during high water events. This work investigates the facility of detecting the slough slides on an earthen levee with different types of polarimetric Synthetic Aperture Radar (polSAR) imagery. The source SAR imagery is fully quad-polarimetric L-band data from the NASA Jet Propulsion Laboratory’s (JPL’s) Uninhabited Aerial Vehicle Synthetic Aperture Radar (UAVSAR). The study area encompasses a portion of the levees of the lower Mississippi river, located in Mississippi, United States. The obtained classification results reveal that the polSAR data unsupervised classification with features extraction produces more appropriate results than the unsupervised classification with no features extraction. Obviously, supervised classification methods provide better classification results compared to the unsupervised methods. The anomaly identification is good with these results and was improved with the use of a majority filter. The classification accuracy is further improved with a morphology filter. The classification accuracy is significantly improved with the use of GLCM features. The classification results obtained for all three cases (magnitude, phase, and complex data), with classification accuracies for the complex data being higher, indicate that the use of synthetic aperture radar in combination with remote sensing imagery can effectively detect anomalies or slides on an earthen levee. For all the three samples it consistently shows that the accuracies for the complex data are higher when compared to those from the magnitude and phase data alone. The tests comparing complex data features to magnitude and phase data alone, and full complex data, and use of post-processing filter, all had very high accuracy. Hence we included more test samples to validate and distinguish results.
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EXPLOITATION OF THE IMAGE CHARACTERISTICS OF A LOCALIZED TRANSILLUMINATION SYSTEM UTILIZING MOLECULAR CONTRAST AGENTS AND POLARIMETRYBathini, Praneeth 12 May 2008 (has links)
No description available.
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Study of Optically Active Biological Fluids Using Polarimetric Data AnalysisNarayan, Chaya 25 August 2011 (has links)
No description available.
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Extreme Ultraviolet Polarimetry with Laser-Generated High-Order HarmonicsBrimhall, Nicole 09 July 2007 (has links) (PDF)
We developed an extreme ultraviolet (EUV) polarimeter, which employs laser-generated high-order harmonics as the light source. This relatively high-flux directional EUV source has available wavelengths between 8 nm and 62 nm and easily rotatable linear polarization. The polarimeter will aid researchers at BYU in characterizing EUV thin films and improving their understanding of materials for use in EUV optics. This first-time workhorse application of laser high harmonics enables polarization-sensitive reflection measurements not previously available in the EUV. We have constructed a versatile positioning system that places harmonics on the microchannel plate detector with an accuracy of 0.3 mm, which allows a spectral resolution of about 180. We have demonstrated that reflectance as low as 0.2% can be measured at EUV wavelengths and that this data is repeatable to within the error of our source stability (~7% fluctuation). We have compared reflectance data with that taken from the same sample at Beamline 6.3.2 at the Advanced Light Source. This data agrees well from 5 degrees to 30 degrees and the angular locations of the interference fringes also agree.
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Polarimetric Characterization Of Random Electromagnetic Beams And ApplicationsMujat, Mircea 01 January 2004 (has links)
Polarimetry is one of the principal means of investigating the interaction of light with matter. Theoretical models and experimental techniques are presented in this dissertation for polarimetric characterization of random electromagnetic beams and of signatures of random media in different scattering regimes and configurations. The degree of polarization rather than the full description of the state of polarization is of interest in multiple scattering and free space propagation where the statistical nature and not the deterministic component of light bears the relevant information. A new interferometric technique for determining the degree of polarization by measuring the intensity fluctuations in a Mach-Zehnder interferometric setup is developed. For this type of investigations, one also needs a light source with a controllable degree of polarization. Therefore, also based on a Mach-Zehnder interferometer, we proposed a new method for generating complex random electromagnetic beams. As a direct application of the cross-spectral density matrix formalism, it is shown that the spectral and the polarimetric characteristics of light can be controlled by adjusting the correlations between parallel components of polarization propagating through the two arms of the interferometer. When optical beams are superposed in the previous applications it is desirable to understand how their coherence and polarimetric characteristics are combined. A generalization of the interference laws of Fresnel and Arago is introduced and as a direct application, a new imaging polarimeter based on a modified Sagnac interferometer is demonstrated. The system allows full polarimetric description of complex random electromagnetic beams. In applications such as active illumination sensing or imaging through turbid media, one can control the orientation of the incident state of polarization such that, in a given coordinate system, the intensities are equal along orthogonal directions. In this situation, our novel interferometric technique has a significant advantage over standard Stokes imaging polarimetry: one needs only one image to obtain both the degree of polarization and the retardance, as opposed to at least three required in classical Stokes polarimetry. The measurement of the state of polarization is required for analyzing the polarization transfer through systems that alter it. Two innovative Mueller matrix measurement techniques are developed for characterizing scattering media, either in quasi real-time, or by detection of low level signals. As a practical aspect of Mueller polarimetry, a procedure for selecting the input Stokes vectors is proposed. The polarimetric signatures of different particulate systems are related to their structural properties and to the size distribution, shape, orientation, birefringent or dichroic properties of the particles. Various scattering regimes and different geometries are discussed for applications relevant to the biomedical field, material science, and remote sensing. The analysis is intended to elucidate practical aspects of single and multiple scattering on polydisperse systems that were not investigated before. It seems to be generally accepted that depolarization effects can only be associated to multiple scattering. It is demonstrated in this dissertation that depolarization can also be regarded as an indication of polydispersity in single scattering. In order to quantify the polarizing behavior of partially oriented cylinders, the polarization transfer for systems consisting of individual layers of partially aligned fibers with different degrees of alignment and packing fractions is also analyzed in this dissertation. It is demonstrated that a certain degree of alignment has the effect of a partial polarizer and that the efficiency of this polarizer depends on the degree of alignment and on the packing fraction of the system. In specific applications such as long range target identification, it is important to know what type of polarization is better preserved during propagation. The experimental results demonstrate that for spherical particles smaller than the wavelength of light, linear polarization is better preserved than circular polarization when light propagates through turbulent media. For large particles, the situation is reversed; circular polarization is better preserved. It is also demonstrated here that this is not necessarily true for polyhedral or cylindrical particles, which behave differently. Optical activity manifests as either circular birefringence or circular dichroism. In this dissertation, a study is presented where both the effect of optical activity and that of multiple scattering are considered. This situation is relevant for medical applications and remote sensing of biological material. It is demonstrated here that the output state of polarization strongly depends on the optical density of the scattering medium, the optical rotatory power and the amount of circular dichroism associated to the scattering medium. This study shows that in the circular birefringence case, scattering and optical activity work together in depolarizing light, while in the dichroic case the two effects compete with each other and the result is a preservation of the degree of polarization. To characterize highly diffusive media, a very simple model is developed, in which the scattering is analyzed using the Mueller matrix formalism in terms of surface and volume contributions.
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Observational and Numerical Studies of Solar Coronal Magnetic Field / 太陽コロナ磁場の観測的及び数値的研究Yamasaki, Daiki 23 March 2023 (has links)
京都大学 / 新制・課程博士 / 博士(理学) / 甲第24421号 / 理博第4920号 / 新制||理||1703(附属図書館) / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 一本 潔, 准教授 浅井 歩, 教授 横山 央明 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DFAM
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Polarization Signatures in Vector SpaceBeamer, Diane K. 20 August 2018 (has links)
No description available.
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Novel Optical Sensors for High Temperature Measurement in Harsh EnvironmentsZhang, Yibing 29 July 2003 (has links)
Accurate measurement of temperature is essential for the safe and efficient operation and control of a vast range of industrial processes. Many of these processes involve harsh environments, such as high temperature, high pressure, chemical corrosion, toxicity, strong electromagnetic interference, and high-energy radiation exposure. These extreme physical conditions often prevent conventional temperature sensors from being used or make them difficult to use. Novel sensor systems should not only provide accurate and reliable temperature measurements, but also survive the harsh environments through proper fabrication material selections and mechanical structure designs.
This dissertation presents detailed research work on the design, modeling, implementation, analysis, and performance evaluation of novel optical high temperature sensors suitable for harsh environment applications. For the first time to our knowledge, an optical temperature sensor based on the broadband polarimetric differential interferometric (BPDI) technology is proposed and tested using single crystal sapphire material. With a simple mechanically structured sensing probe, in conjunction with an optical spectrum-coded interferometric signal processing technique, the proposed single crystal sapphire optical sensor can measure high temperature up to 1600 oC in the harsh environments with high accuracy, corrosion resistance, and long-term measurement stability. Based on the successfully demonstrated sensor prototype in the laboratory, we are confident of the next research step on sensor optimization and scale-up for full field implementations. The goal for this research has been to bring this temperature sensor to a level where it will become commercially viable for harsh environment applications associated with industries. / Ph. D.
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Design and implementation of nanoantennas on integrated guides and their application on polarization analysis and synthesisEspinosa Soria, Alba 05 July 2018 (has links)
La fotónica sobre silicio se ha convertido en la tecnología más importante en la producción de chips integrados fotónicos. Sus grandes ventajas, entre las cuales destacan su idoneidad para la fabricación a gran escala y su bajo coste de producción, como resultado de la posibilidad del uso tecnología CMOS, son motivo suficiente para justificar su supremacía sobre otras plataformas de integración. Pese a los múltiples dispositivos ya implementados en dicha tecnología, entre los que cabe destacar filtros WDM o moduladores electro-ópticos, todavía hay espacio para la mejora, sobre todo en cuanto a la reducción del foot-print de los dispositivos o a la creación de nuevas funcionalidades para la manipulación de la luz.
Dichas mejoras podrían llevarse a cabo mediante la integración de componentes con dimensiones sub-lambda surgidos en el campo conocido como plasmónica. Esta disciplina estudia la interacción entre la luz y los metales, que viene mediada por la existencia de ondas conocidas como plasmones de superficie. Una de las propiedades clave de los plasmones es su capacidad para confinar la luz muy por encima del límite de difracción, lo cual es limitante en el caso de la fotónica sobre silicio. Sin embargo, las pérdidas por absorción de los metales a frecuencias ópticas impiden su uso para el guiado de la luz en grandes distancias. Se hace evidente, por tanto, los beneficios de unificar estos dos mundos. Usando el silicio como material conductor de la señal óptica y el metal como eficiente interactor con la luz en estructuras sub-lambda, se pueden crear nuevos dispositivos para la manipulación de las propiedades de la luz en la nanoescala.
Esta Tesis está centrada en la integración de estructuras con dimensiones sub-lambda en guías de silicio y en su aplicación a nuevas funcionalidades de manipulación de la luz en chips de silicio. Dichas nanoestructuras sirven de transductores entre la luz guiada y la radiación en espacio libre, por lo que también pueden ser denominadas nanoantenas. Para empezar, se describen las propiedades de los modos guiados en guías de onda de silicio para la correcta excitación de las nanoantenas, seguido de la demostración de técnicas de integración de estas nanoestructuras en las propias guías para aumentar su eficiencia de interacción con la luz guiada. Además, se demuestra el control coherente de la absorción y el scattering de una nanoantenna metálica integrada en una guía de silicio. Por último, a partir del posicionamiento asimétrico de la nanoestructura con respecto a la guía, se proponen y demuestran nuevos métodos de manipulación de la polarización, como la capacidad para sintetizar estados de polarización deseados a escala nanométrica. Esto desembocará en la demostración teórica y experimental de un nanopolarímetro de Stokes, basado en tecnología fotónica sobre silicio, capaz de determinar el estado de polarización de manera local, óptima, y no destructiva, habilitándose su uso para medidas de polarización en tiempo real en circuitos integrados. / Silicon photonics has become the most important technology in integrated photonic chips production. Its great advantages, including its suitability for large-scale production and low-cost production, as a result of the possibility of using CMOS technology, are sufficient reason to justify its supremacy over other integration platforms. Despite the multiple devices already implemented in this technology, among which include WDM filters or electro-optical modulators, there is still room for improvement, especially in terms of reducing the devices footprint or the creation of new functionalities for the manipulation of light.
Such improvements could be carried out by integrating components with sub-lambda dimensions arising in the field known as plasmonics. This discipline studies the interaction between light and metals, which is mediated by the existence of waves known as surface plasmons. One of the key properties of plasmons is their ability to confine light well beyond the diffraction limit, which is limiting in the case of silicon photonics. However, losses due to the absorption of metals at optical frequencies prevent their use for guiding light over long distances. Therefore, the benefits of unifying these two worlds becomes evident. By using silicon as the conductive material of the optical signal and the metal as an efficient light interconnector in subwavelength structures, new devices can be created for the manipulation of the properties of light at the nanoscale.
This thesis is focused on the integration of structures with subwavelength dimensions in silicon waveguides and in their application to new functionalities of light manipulation in silicon chips. These nanostructures serve as transducers between guided light and free space radiation, so they can also be termed nanoantennas. To begin with, the guided modes properties in silicon waveguides are described for the correct excitation of the nanoantennas, followed by the demonstration of integration techniques of these nanostructures in these waveguides to increase their interaction efficiency with the guided light. In addition, the coherent control of the absorption and scattering of a metallic nanoantenna integrated in a silicon waveguide is demonstrated. Finally, from the asymmetric positioning of the nanostructure with respect to the waveguide, new polarization manipulation methods are proposed and demonstrated, such as the ability to synthesize desired states of polarization at the nanoscale. This will lead to the theoretical and experimental demonstration of a Stokes nanopolarimeter, based on photon-on-silicon technology, capable of determining the polarization state locally, optimally, and non-destructively, enabling its use for real-time polarization measurements in integrated circuits. / La fotònica sobre silici s'ha convertit en la tecnologia més important en la producció de xips integrats fotònics. Els seus grans avantatges, entre les quals destaquen la seva idoneïtat per a la fabricació a gran escala i el seu baix cost de producció, com a resultat de la possibilitat de l'ús tecnologia CMOS, són motiu suficient per justificar la seva supremacia sobre altres plataformes d'integració. Malgrat els múltiples dispositius ja implementats en aquesta tecnologia, entre els quals cal destacar filtres WDM o moduladors electro-òptics, encara hi ha espai per a la millora, sobretot quant a la reducció del foot-print dels dispositius o a la creació de noves funcionalitats per a la manipulació de la llum.
Aquestes millores podrien portar-se a terme mitjançant la integració de components amb dimensions sub-lambda sorgits en el camp conegut com plasmònica. Aquesta disciplina estudia la interacció entre la llum i els metalls, que ve intervinguda per l'existència d'ones conegudes com plasmons de superfície. Una de les propietats clau dels plasmons és la seva capacitat per confinar la llum molt per sobre del límit de difracció, la qual cosa és limitant en el cas de la fotònica sobre silici. No obstant això, les pèrdues per absorció dels metalls a freqüències òptiques impedeixen el seu ús per al guiat de la llum en grans distàncies. Es fa evident, per tant, els beneficis d'unificar aquests dos mons. Usant el silici com a material conductor del senyal òptic i el metall com eficient interactor amb la llum en estructures sub-lambda, es poden crear nous dispositius per a la manipulació de les propietats de la llum en la nanoescala.
Aquesta Tesi està centrada en la integració d'estructures amb dimensions sub-lambda en guies de silici i en la seva aplicació a noves funcionalitats de manipulació de la llum en xips de silici. Aquestes nanoestructures serveixen de transductors entre la llum guiada i la radiació en espai lliure, de manera que també poden ser denominades nanoantenes. Per començar, es descriuen les propietats de les maneres guiats en guies d'ona de silici per a la correcta excitació de les nanoantenes, seguit de la demostració de tècniques d'integració d'aquestes nanoestructures en les pròpies guies per augmentar la seva eficiència d'interacció amb la llum guiada. A més, es demostra el control coherent de l'absorció i el scattering d'una nanoantenna metàl·lica integrada en una guia de silici. Finalment, a partir del posicionament asimètric de la nanoestructura respecte a la guia, es proposen i demostren nous mètodes de manipulació de la polarització, com la capacitat per sintetitzar estats de polarització desitjats a escala nanomètrica. Això desembocarà en la demostració teòrica i experimental d'un nanopolarímetre de Stokes, basat en tecnologia fotònica sobre silici, capaç de determinar l'estat de polarització de manera local, òptima, i no destructiva, habilitant el seu ús per a mesures de polarització en temps real en circuits integrats. / Espinosa Soria, A. (2018). Design and implementation of nanoantennas on integrated guides and their application on polarization analysis and synthesis [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/105382
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