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Desenvolvimento e caracterização do filtro óptico de interferência variável para detectores de alta resolução espectral e biossensores. / Development and characterisation of optical filter of variable interference for detectors of high resolution spectral and biosensors.Celso Manoel da Silva 01 March 2016 (has links)
O presente trabalho está fundamentado no desenvolvimento de uma metodologia e/ou uma tecnologia de obtenção e caracterização de filtros ópticos de interferência de banda passante variável [C.M. da Silva, 2010] e de banda de corte variáveis, constituídos por refletores dielétricos multicamadas de filmes finos intercalados por cavidades de Fabry-Perot não planares com espessuras linearmente variáveis, que apresentam a propriedade do deslocamento linear da transmitância máxima espectral em função da posição, isto é, um Filtro de Interferência Variável (FIV). Este método apresenta novas e abrangentes possibilidades de confecção de filtros ópticos de interferência variável: lineares ou em outras formas desejadas, de comprimento de onda de corte variável (passa baixa ou alta) e filtros de densidade neutra variável, através da deposição de metais, além de aplicações em uma promissora e nova área de pesquisa na deposição de filmes finos não uniformes. A etapa inicial deste desenvolvimento foi o estudo da teoria dos filtros ópticos dielétricos de interferência para projetar e construir um filtro óptico banda passante convencional de um comprimento de onda central com camadas homogêneas. A etapa seguinte, com base na teoria óptica dos filmes finos já estabelecida, foi desenvolver a extensão destes conhecimentos para determinar que a variação da espessura em um perfil inclinado e linear da cavidade entre os refletores de Bragg é o principal parâmetro para produzir o deslocamento espacial da transmitância espectral, possibilitando o uso de técnicas especiais para se obter uma variação em faixas de bandas de grande amplitude, em um único filtro. Um trabalho de modelagem analítica e análise de tolerância de espessuras dos filmes depositados foram necessários para a seleção da estratégia do \"mascaramento\" seletivo do material evaporado formado na câmara e-Beam (elétron-Beam) com o objetivo da obtenção do filtro espectral linear variável de características desejadas. Para tanto, de acordo com os requisitos de projeto, foram necessárias adaptações em uma evaporadora por e-Beam para receber um obliterador mecânico especialmente projetado para compatibilizar os parâmetros das técnicas convencionais de deposição com o objetivo de se obter um perfil inclinado, perfil este previsto em processos de simulação para ajustar e calibrar a geometria do obliterador e se obter um filme depositado na espessura, conformação e disposição pretendidos. Ao final destas etapas de modelagem analítica, simulação e refinamento recorrente, foram determinados os parâmetros de projeto para obtenção de um determinado FIV (Filtro de Interferência Variável) especificado. Baseadas nos FIVs muitas aplicações são emergentes: dispositivos multi, hiper e ultra espectral para sensoriamento remoto e análise ambiental, sistemas Lab-on-Chip, biossensores, detectores chip-sized, espectrofotometria de fluorescência on-chip, detectores de deslocamento de comprimento de onda, sistemas de interrogação, sistemas de imageamento espectral, microespectrofotômetros e etc. No escopo deste trabalho se pretende abranger um estudo de uma referência básica do emprego do (FIV) filtro de interferência variável como detector de varredura de comprimento de ondas em sensores biológicos e químicos compatível com pós processamento CMOS. Um sistema básico que é constituído por um FIV montado sobre uma matriz de sensores ópticos conectada a um módulo eletrônico dedicado a medir a intensidade da radiação incidente e as bandas de absorção das moléculas presentes em uma câmara de detecção de um sistema próprio de canais de microfluidos, configurando-se em um sistema de aquisição e armazenamento de dados (DAS), é proposto para demonstrar as possibilidades do FIV e para servir de base para estudos exploratórios das suas diversas potencialidades que, entre tantas, algumas são mencionadas ao longo deste trabalho. O protótipo obtido é capaz de analisar fluidos químicos ou biológicos e pode ser confrontado com os resultados obtidos por equipamentos homologados de uso corrente. / This work presents the development of a method to obtain and characterize a variable interference optical band pass filter, made up of a number of thin films forming dielectrical reflectors intercalated by non flat Fabry-Perot cavities whose thickness varies linearly. These filters present the propriety of a linear variation in the maximum spectral transmittance as a function of the position in the filter, for this reason this is called Variable Interference Filter (VIF). This method allows of manufacturing linear interference filters or any other function desired, variable cut wavelength (low or high pass) and variable neutral density filters by means of metallic depositions. The first step in this work was to design and built a conventional filter, with homogeneous layers and a fixed central wavelength. The following step was, using basics of the Optical theory of thin films, introduce the variation in the thickness of the layers in a linear inclined outline. Accordingly with the design requirements, it was made some adaptations in an e-beam evaporator (electron-beam), adding a mechanical obliterator adjusted with series of depositions and characterizations of a single layers in order to find a linearly inclined outline. In the end of this step it was designed and built the specified VIF. It is also described a possible application of this VIF: a multispectral device for biological analysis. Among many applications, others can be cited, such as: Lab-on-Chip systems, biosensors chip-sized detectors, on-chip fluorescence spectrometry, shift wavelength detectors, interrogation systems, environmental analysis systems, etc. The scope of this work covers the study of variable interference filters as a wavelength scanning detector in biological and chemical sensors compatible with CMOS post-processing. To demonstrate the viability, and enable the exploration of other applications, it is proposed a basic system composed of a VIF, mounted on top of a matrix of sensors connected to a dedicated electronic module, to measure and store the intensity of the incident radiation data and the absorption spectra of molecules present in a detection chamber of a microfluidic system. Other applications of this basic structure are mentioned. This prototype is aimed to analyze biological fluids and results will be compared with results obtained using standard commercial instruments.
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Desenvolvimento e caracterização do filtro óptico de interferência variável para detectores de alta resolução espectral e biossensores. / Development and characterisation of optical filter of variable interference for detectors of high resolution spectral and biosensors.Silva, Celso Manoel da 01 March 2016 (has links)
O presente trabalho está fundamentado no desenvolvimento de uma metodologia e/ou uma tecnologia de obtenção e caracterização de filtros ópticos de interferência de banda passante variável [C.M. da Silva, 2010] e de banda de corte variáveis, constituídos por refletores dielétricos multicamadas de filmes finos intercalados por cavidades de Fabry-Perot não planares com espessuras linearmente variáveis, que apresentam a propriedade do deslocamento linear da transmitância máxima espectral em função da posição, isto é, um Filtro de Interferência Variável (FIV). Este método apresenta novas e abrangentes possibilidades de confecção de filtros ópticos de interferência variável: lineares ou em outras formas desejadas, de comprimento de onda de corte variável (passa baixa ou alta) e filtros de densidade neutra variável, através da deposição de metais, além de aplicações em uma promissora e nova área de pesquisa na deposição de filmes finos não uniformes. A etapa inicial deste desenvolvimento foi o estudo da teoria dos filtros ópticos dielétricos de interferência para projetar e construir um filtro óptico banda passante convencional de um comprimento de onda central com camadas homogêneas. A etapa seguinte, com base na teoria óptica dos filmes finos já estabelecida, foi desenvolver a extensão destes conhecimentos para determinar que a variação da espessura em um perfil inclinado e linear da cavidade entre os refletores de Bragg é o principal parâmetro para produzir o deslocamento espacial da transmitância espectral, possibilitando o uso de técnicas especiais para se obter uma variação em faixas de bandas de grande amplitude, em um único filtro. Um trabalho de modelagem analítica e análise de tolerância de espessuras dos filmes depositados foram necessários para a seleção da estratégia do \"mascaramento\" seletivo do material evaporado formado na câmara e-Beam (elétron-Beam) com o objetivo da obtenção do filtro espectral linear variável de características desejadas. Para tanto, de acordo com os requisitos de projeto, foram necessárias adaptações em uma evaporadora por e-Beam para receber um obliterador mecânico especialmente projetado para compatibilizar os parâmetros das técnicas convencionais de deposição com o objetivo de se obter um perfil inclinado, perfil este previsto em processos de simulação para ajustar e calibrar a geometria do obliterador e se obter um filme depositado na espessura, conformação e disposição pretendidos. Ao final destas etapas de modelagem analítica, simulação e refinamento recorrente, foram determinados os parâmetros de projeto para obtenção de um determinado FIV (Filtro de Interferência Variável) especificado. Baseadas nos FIVs muitas aplicações são emergentes: dispositivos multi, hiper e ultra espectral para sensoriamento remoto e análise ambiental, sistemas Lab-on-Chip, biossensores, detectores chip-sized, espectrofotometria de fluorescência on-chip, detectores de deslocamento de comprimento de onda, sistemas de interrogação, sistemas de imageamento espectral, microespectrofotômetros e etc. No escopo deste trabalho se pretende abranger um estudo de uma referência básica do emprego do (FIV) filtro de interferência variável como detector de varredura de comprimento de ondas em sensores biológicos e químicos compatível com pós processamento CMOS. Um sistema básico que é constituído por um FIV montado sobre uma matriz de sensores ópticos conectada a um módulo eletrônico dedicado a medir a intensidade da radiação incidente e as bandas de absorção das moléculas presentes em uma câmara de detecção de um sistema próprio de canais de microfluidos, configurando-se em um sistema de aquisição e armazenamento de dados (DAS), é proposto para demonstrar as possibilidades do FIV e para servir de base para estudos exploratórios das suas diversas potencialidades que, entre tantas, algumas são mencionadas ao longo deste trabalho. O protótipo obtido é capaz de analisar fluidos químicos ou biológicos e pode ser confrontado com os resultados obtidos por equipamentos homologados de uso corrente. / This work presents the development of a method to obtain and characterize a variable interference optical band pass filter, made up of a number of thin films forming dielectrical reflectors intercalated by non flat Fabry-Perot cavities whose thickness varies linearly. These filters present the propriety of a linear variation in the maximum spectral transmittance as a function of the position in the filter, for this reason this is called Variable Interference Filter (VIF). This method allows of manufacturing linear interference filters or any other function desired, variable cut wavelength (low or high pass) and variable neutral density filters by means of metallic depositions. The first step in this work was to design and built a conventional filter, with homogeneous layers and a fixed central wavelength. The following step was, using basics of the Optical theory of thin films, introduce the variation in the thickness of the layers in a linear inclined outline. Accordingly with the design requirements, it was made some adaptations in an e-beam evaporator (electron-beam), adding a mechanical obliterator adjusted with series of depositions and characterizations of a single layers in order to find a linearly inclined outline. In the end of this step it was designed and built the specified VIF. It is also described a possible application of this VIF: a multispectral device for biological analysis. Among many applications, others can be cited, such as: Lab-on-Chip systems, biosensors chip-sized detectors, on-chip fluorescence spectrometry, shift wavelength detectors, interrogation systems, environmental analysis systems, etc. The scope of this work covers the study of variable interference filters as a wavelength scanning detector in biological and chemical sensors compatible with CMOS post-processing. To demonstrate the viability, and enable the exploration of other applications, it is proposed a basic system composed of a VIF, mounted on top of a matrix of sensors connected to a dedicated electronic module, to measure and store the intensity of the incident radiation data and the absorption spectra of molecules present in a detection chamber of a microfluidic system. Other applications of this basic structure are mentioned. This prototype is aimed to analyze biological fluids and results will be compared with results obtained using standard commercial instruments.
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Entwicklung eines integrierten Mikroresonators für die kernmagnetische Resonanzspektroskopie kleinster ProbenvolumenLeidich, Stefan 09 April 2010 (has links) (PDF)
In der vorliegenden Arbeit wird ein Mikroresonator für die kernmagnetische
Resonanzspektroskopie kleinster Probenvolumen entwickelt. Der Resonator
besteht aus einem Mikrodetektor und einer elektrisch steuerbaren Kapazität für
den Resonanzabgleich. Beide Bauteile sind speziell an die Anforderungen des
Messverfahrens angepasst. Der Mikrodetektor, welcher die Funktion der
Erregung der Kernspins und die Detektion des Messsignals erfüllt, weist
aufgrund seiner besonderen Geometrie ein weitgehend homogenes statisches
Magnetfeld im Bereich des Probenvolumens auf. Daraus resultieren eine
Verbesserung der spektralen Auflösung und eine Steigerung der
Empfindlichkeit. Die elektrisch steuerbare Kapazität weist eine hohe elektrische
Güte und eine hohe Spannungsfestigkeit auf, wodurch die Verwendung von
hohen Pulsleistungen möglich ist. Der Nachweis der Funktionalität des Systems
erfolgt durch die Integration des Mikroresonators in einen Probenkopf, welcher
zur Messung von Test- und Referenzsignalen eingesetzt wird. Anhand der
Messwerte wird gezeigt, dass die neue Entwicklung eine sehr hohe
Empfindlichkeit und eine deutlich höhere spektrale Auflösung als andere
Detektorsysteme dieser Art aufweist und somit besonders gut für die Messung
von sehr kleinen Probenvolumen geeignet ist. / The thesis describes the development of a micro resonator for nuclear magnetic resonance (NMR) spectroscopy of very small sample volumes. The resonator consists of a microcoil and an electrically adjustable capacitance for resonance tuning. Both components are specially designed for the purpose of NMR. The microcoil excites the nuclear spins and detects the measurement signal. Due to the special cylindrical geometry, the detector provides a very homogenous spatial distribution of the static magnetic field at the location of the sample. This leads to improved spectral resolution and increased sensitivity. The electrically adjustable capacitance provides a high quality factor and high voltage stability. Hence, short excitation pulses with high bandwidth can be applied. The components are integrated into a specially designed probe. The functionality of the system is demonstrated by test and reference measurements. The measurement results verify the high sensitivity and the high spectral resolution. Hence, the system is applicable and well suited for NMR measurements of small sample volumes.
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Multispektrální analýza obrazových dat / Multispectral Analyse of Image DataNovotný, Jan January 2009 (has links)
The airborne hyperspectral remote sensing is used as an approach to monitor actual state of environmental components. This thesis covers priority treatment to analyse of hyperspectral data with the aim of a tree crowns delineation. Specific algorithm applying adaptive equalization and the Voronoi diagrams is designed to subdivide a forest area into individual trees. A computer program executes the algorithm and allows testing it on real data, checking and analyzing the results.
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Material Related Effects on the Structural Thermal Optical Performance of a Thermally Tunable Narrowband Interferometric Spectral FilterSeaman, Shane Thomas 01 July 2019 (has links)
High Spectral Resolution Lidar (HSRL) is a backscatter lidar technique that employs an optical/spectral filter to distinguish between particulate (Mie) and molecular (Rayleigh) backscattered light. By separating the two types of returns, higher accuracy measurements are possible that will enable improved climate models, air quality measurements, and climate forecasting. A spaceborne HSRL instrument can provide great impact in these areas by enabling near-continuous measurements across the Earth, however the optical filter technology has typically been too complex for reliable long-duration space flight due to the need for complicated and costly electro-optic feedback loops, extra alignment detectors, and additional laser sources. Furthermore, these complexities limit the filter from use in other applications. In this research, a high-performance, ultra-narrowband interferometric optical filter with a specific thermo-optical behavior has been designed and built. The interferometer has been designed such that it can be reliably adjusted/tuned by simply monitoring and adjusting the temperature. The greatly reduced operational complexity was made possible through high-accuracy thermal characterization of the interferometer materials, combined with detailed Structural-Thermal-Optical-Performance (STOP) modeling to capture the complicated interactions between the materials. The overall design process, fabrication procedures, and characterization of the optical filter are presented. / Doctor of Philosophy / LiDAR (an acronym for Light Detection and Ranging) is a technology that can be used to measure properties of the atmosphere. It is similar to radar, but uses much smaller light waves rather than larger radio waves, enabling more detailed information to be obtained. High Spectral Resolution Lidar (HSRL) is a lidar technique that uses a high precision optical filter to distinguish between light that scatters from particulates (such as dust, smoke, or fog) and light that scatters from molecules (such as oxygen, nitrogen, or carbon dioxide) in the atmosphere. By separating the two types of backscattered light, higher accuracy measurements are possible that will enable improvements in climate models, air quality measurements, and climate forecasting. A spaceborne HSRL instrument can provide great impact in these areas by enabling near-continuous measurements across the Earth; however, the optical filter technology has typically been too complex for reliable long-duration spaceflight due to the need for complicated and expensive additional hardware. In this research, a high-performance HSRL optical filter that can be reliably operated by simply monitoring and adjusting the temperature has been designed, built, and tested. The greatly-reduced operational complexity has been made possible through a new process that enables more accurate prediction of the complicated interactions between the materials of the optical filter. This process is based on a combination of high-accuracy characterization of the materials and detailed structural-thermal-optical-performance (STOP) modeling. The overall design process, fabrication procedures, and characterization of the optical filter are presented.
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Conception, réalisation et mise en oeuvre d'un microsystème pour la micro spectroscopie par résonance magnétique nucléaire / Design, development and experimental evaluation of an analysis micro system for NMRPasquet, Guillaume 10 July 2009 (has links)
Ce travail de thèse porte sur la conception, la réalisation et l’évaluation expérimentale d’ un microsystème d’analyse dont l’originalité repose sur l’intégration d’une micro antenne planaire de spectroscopie par résonance magnétique nucléaire (SRMN) sur un système micro fluidique à base d’un polymère, le Cyclique Oléfine Copolymère (COC). La détermination des caractéristiques géométriques optimales du microsystème afin d’optimiser le couplage électromagnétique entre la micro antenne de détection et l’échantillon est effectuée à l’aide d’un modèle de calcul numérique, ce qui permet l’optimisation du rapport signal sur bruit (RSB). La réalisation du microsystème avec des procédés de micro fabrication développés au laboratoire ont permis de valides son fonctionnement dans un spectromètre dont le champ magnétique statique atteint 11.74 Tesla (fréquence de Larmor du proton égale à 500MHz). Travailler dans un champ aussi intense permet d’améliorer la sensibilité de détection mais nécessite de porter une attention particulière à l’homogénéité du champ magnétique qui, dans notre cas, peut être dégradée en raison de l’introduction du microsystème dans le spectromètre. En effet, les distorsions du champ magnétique, dues aux différentes susceptibilités magnétiques des matériaux constituant la microsonde, ont un impact direct sur la résolution spectrale. C’est pourquoi, une modélisation 3D par éléments finis est proposée afin de prévoir l’influence du microsystème sur la forme des raies spectrales et donc d’en déduire la résolution spectrale pouvant être espérée. La comparaison des résultats expérimentaux et ceux issus des simulations permet de valider le modèle de calcul numérique. Il apparait cependant nécessaire d’inclure le phénomène d’amortissement radiatif afin de pouvoir rendre compte des résultats expérimentaux relatifs à la résolution spectrale effectivement observée. / The work presented in this thesis involves the design, the development and the experimental evaluation of an analysis micro system. The originality of the work lies in the integration of a planar micro coil of spectroscopy by nuclear magnetic resonance (SNMR) on a micro fluidic system based on a polymer, cyclo olefin copolymer (COC). The determination of the optimum geometric characteristics of the micro system to improve electromagnetic coupling between the detection micro coil and the sample is performed with the aid of a numerical model that ensures the optimization of the signal to noise ratio (SNR). Using micro fabrication techniques developed in the laboratory, the micro system was developed and its behaviour was validated in spectrometer producing a static magnetic field off 11.74 Tesla (Larmor frequency of the proton equal to 500MHz). Working in such an intense field results in improved sensitivity of detection but requires paying close attention to the homogeneity of magnetic field. In this case the homogeneity can be degraded due to the introduction of the micro system in the spectrometer. Indeed, the distortions of the magnetic field, due to the different magnetic susceptibilities of the materials constituting the microprobe, have a direct impact on the spectral resolution. As such, 3D modelling by finite elements is proposed to predict the influence of the micro system on the shape of the spectral lines and to determine the best expected spectral resolution. The comparison of the experimental results to those obtained from simulation allows the validation of the numerical model. However, it appears necessary to include the effect of the radiation damping in the model to be able to justify the experimental results relative to the spectral resolution that was observed.
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Entwicklung eines integrierten Mikroresonators für die kernmagnetische Resonanzspektroskopie kleinster ProbenvolumenLeidich, Stefan 26 February 2010 (has links)
In der vorliegenden Arbeit wird ein Mikroresonator für die kernmagnetische
Resonanzspektroskopie kleinster Probenvolumen entwickelt. Der Resonator
besteht aus einem Mikrodetektor und einer elektrisch steuerbaren Kapazität für
den Resonanzabgleich. Beide Bauteile sind speziell an die Anforderungen des
Messverfahrens angepasst. Der Mikrodetektor, welcher die Funktion der
Erregung der Kernspins und die Detektion des Messsignals erfüllt, weist
aufgrund seiner besonderen Geometrie ein weitgehend homogenes statisches
Magnetfeld im Bereich des Probenvolumens auf. Daraus resultieren eine
Verbesserung der spektralen Auflösung und eine Steigerung der
Empfindlichkeit. Die elektrisch steuerbare Kapazität weist eine hohe elektrische
Güte und eine hohe Spannungsfestigkeit auf, wodurch die Verwendung von
hohen Pulsleistungen möglich ist. Der Nachweis der Funktionalität des Systems
erfolgt durch die Integration des Mikroresonators in einen Probenkopf, welcher
zur Messung von Test- und Referenzsignalen eingesetzt wird. Anhand der
Messwerte wird gezeigt, dass die neue Entwicklung eine sehr hohe
Empfindlichkeit und eine deutlich höhere spektrale Auflösung als andere
Detektorsysteme dieser Art aufweist und somit besonders gut für die Messung
von sehr kleinen Probenvolumen geeignet ist. / The thesis describes the development of a micro resonator for nuclear magnetic resonance (NMR) spectroscopy of very small sample volumes. The resonator consists of a microcoil and an electrically adjustable capacitance for resonance tuning. Both components are specially designed for the purpose of NMR. The microcoil excites the nuclear spins and detects the measurement signal. Due to the special cylindrical geometry, the detector provides a very homogenous spatial distribution of the static magnetic field at the location of the sample. This leads to improved spectral resolution and increased sensitivity. The electrically adjustable capacitance provides a high quality factor and high voltage stability. Hence, short excitation pulses with high bandwidth can be applied. The components are integrated into a specially designed probe. The functionality of the system is demonstrated by test and reference measurements. The measurement results verify the high sensitivity and the high spectral resolution. Hence, the system is applicable and well suited for NMR measurements of small sample volumes.
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