Dissertations / Theses on the topic 'Coherent Illumination'

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Sombras e ilumina??o possuem um papel importante na s?ntese de cenas realistas em Computa??o Gr?fica. A maioria dos sistemas de Realidade Aumentada rastreia marcadores posicionados numa real, obtendo sua posi??o e orienta??o para servir como refer?ncia para o conte?do sint?tico, produzindo a cena aumentada. A exibi??o realista de conte?do aumentado com pistas visuais coerentes ? um objetivo desej?vel em muitas aplica??es de Realidade Aumentada. Contudo, renderizar uma cena aumentada com ilumina??o realista ? um tarefa complexa. Muitas abordagens existentes dependem de uma fase de pr?-processamento n?o automatizada para obter os par?metros de ilumina??o da cena. Outras t?cnicas dependem de marcadores espec?ficos que cont?m probes de luz para realizar a estima??o da ilumina??o do ambiente. Esse estudo se foca na cria??o de um m?todo para criar aplica??es de Realidade Aumentada com ilumina??o coerente e sombras, usando um cub?ide texturizado como marcador, n?o requerendo fase de treinamento para prover informa??o acerca da ilumina??o do ambiente. Um marcador desse tipo pode ser facilmente encontrado em ambientes comuns: a maioria das embalagens de produtos satisfaz essas caracter?sticas. Portanto, ese estudo prop?e uma maneira de estimar a configura??o de uma luz direcional utilizando o rastreamento de m?ltiplas texturas para renderizar cenas de Realidade Aumentada de maneira realista. Tamb?m ? proposto um novo descritor de features visuais que ? usado para realizar o rastreamento de m?ltiplas texturas. Esse descritor extende o descritor bin?rio e ? denominado descritor discreto. Ele supera o atual estado-da-arte em velocidade, enquanto mant?m n?veis similares de precis?o.
Shadows and illumination play an important role when generating a realistic scene in computer graphics. Most of the Augmented Reality (AR) systems track markers placed in a real scene and retrieve their position and orientation to serve as a frame of reference for added computer generated content, thereby producing an augmented scene. Realistic depiction of augmented content with coherent visual cues is a desired goal in many AR applications. However, rendering an augmented scene with realistic illumination is a complex task. Many existent approaches rely on a non automated pre-processing phase to retrieve illumination parameters from the scene. Other techniques rely on specific markers that contain light probes to perform environment lighting estimation. This study aims at designing a method to create AR applications with coherent illumination and shadows, using a textured cuboid marker, that does not require a training phase to provide lighting information. Such marker may be easily found in common environments: most of product packaging satisfies such characteristics. Thus, we propose a way to estimate a directional light configuration using multiple texture tracking to render AR scenes in a realistic fashion. We also propose a novel feature descriptor that is used to perform multiple texture tracking. Our descriptor is an extension of the binary descriptor, named discrete descriptor, and outperforms current state-of-the-art methods in speed, while maintaining their accuracy.

This thesis exploits so called “Optical Eigenmodes” (OEi) in the focal plane of an optical system. The concept of OEi is introduced and the OEi operator approach is outlined, for which quadratic measures of the light field are expressed as real eigenvalues of an Hermitian operator. As an example, the latter is employed to locally minimise the width of a focal spot. The limitations of implementing these spots with state of the art spatial beam shaping technique are explored and a selected spot with a by 40 % decreased core width is used to confocally scan an in focus pair of holes, delivering a two-point resolution enhanced by a factor of 1.3. As a second application, OEi are utilised for fullfield imaging. Therefore they are projected onto an object and for each mode a complex coupling coefficient describing the light-sample interaction is determined. The superposition of the OEi weighted with these coefficients delivers an image of the object. Compared to a point-by-point scan of the sample with the same number of probes, i.e. scanning points, the OEi image features higher spatial resolution and localisation of object features, rendering OEi imaging a compressive imaging modality. With respect to a raster scan a compression by a factor four is achieved. Compared to ghost imaging as another fullfield imaging method, 2-3 orders of magnitude less probes are required to obtain similar images. The application of OEi for imaging in transmission as well as for fluorescence and (surface enhanced) Raman spectroscopy is demonstrated. Finally, the applicability of the OEi concept for the coherent control of nanostructures is shown. For this, OEi are generated with respect to elements on a nanostructure, such as nanoantennas or nanopads. The OEi can be superimposed in order to generate an illumination of choice, for example to address one or multiple nanoelements with a defined intensity. It is shown that, compared to addressing such elements just with a focussed beam, the OEi concept reduces illumination crosstalk in addressing individual nanoelements by up to 70 %. Furthermore, a fullfield aberration correction is inherent to experimentally determined OEi, hence enabling addressing of nanoelements through turbid media.

Simulation of light transport in a scene is an essential task in realistic image synthesis. However, an accurate simulation of light as it bounces in the scene is time consuming. It has been shown that a key to speeding up light transport simulation algorithms is to take advantage of the high degree of spatial, angular, and temporal coherence. In this thesis we make three contributions in this area. First, we propose spatial directional radiance caching (SDRC) for accelerating the light transport simulation in scenes with glossy surfaces. The SDRC algorithm takes advantage of the smoothness of shading on glossy surfaces by interpolating the indirect illumination from a set of sparsely distributed radiance samples that are both spatially and directionally close. In the next part of the thesis, we propose an efficient and accurate local principal component analysis (LPCA) algorithm for dimensionality reduction and data compression of large data sets. To achieve efficiency our new algorithm, called SortCluster-LPCA, passes various information from previous iteration to the next. Improved accuracy is achieved through better initial seeding of cluster centroids in LPCA. Finally, we describe a work in progress focusing on the development of an algorithm for interactive relighting of animation sequences with indirect illumination. We formulate the relighting problem as a large 3D array expressing light propagation in a scene over multiple frames. We suggest an adaptive algorithm to make the pre-computation tractable exploiting coherence in light transport
La simulation de la propagation de la lumière dans une scène est une tâche essentielle en synthèse d'images réalistes. Cependant, une simulation correcte de la lumière ainsi que ses différents rebonds dans la scène reste couteuse en temps de calcul. Premièrement, nous proposons l'algorithme de cache de luminance spatial et directionnel SDRC. L'algorithme SDRC tire parti du fait que les variations d'éclairage sont douces sur les surfaces brillantes. L'éclairage en un point de la scène est alors calculé en interpolant l'éclairage indirect connu pour un ensemble d'échantillons de luminance spatialement proches et de directions similaires. Dans la partie suivante, nous présentons un algorithme efficace et précis d'analyse locale en composantes principales LPCA pour réduire la dimension et compresser un grandensemble de données. Pour améliorer l'efficacité de notre nouvel algoritme celui-ci propage les informations issues d'une itération à une itération suivante. En choisissant une meilleure graine initiale pour les centroïdes des clusters dans LPCA, la précision de la méthode est améliorée et produit une meilleure classification des données. Enfin, nous décrivons des travaux en cours de réalisation concernant une méthode de ré-éclairage interactif d'une séquence animée en prenant en compte l'éclairage indirect. Le problème de ré-éclairage est représenté sous la forme d'une grande matrice 3D représentant la propagation de la lumière dans la scène pour plusieurs images de la séquence. Un algorithme adaptatif pré-calcule la propagation de la lumière en exploitant les cohérences potentielles

This thesis is concerned with the optimization and development of the production of nanofocusing refractive x-ray lenses. These optics made of either silicon or diamond are well-suited for high resolution x-ray microscopy. The goal of this work is the design of a reproducible manufacturing process which allows the production of silicon lenses with high precision, high quality and high piece number. Furthermore a process for the production of diamond lenses is to be developed and established. In this work, the theoretical basics of x-rays and their interaction with matter are described. Especially, aspects of synchrotron radiation are emphasized. Important in x-ray microscopy are the different optics. The details, advantages and disadvantages, in particular those of refractive lenses are given. To achieve small x-ray beams well beyond the 100nm range a small focal length is required. This is achieved in refractive lenses by moving to a compact lens design where several single lenses are stacked behind each other. The, so-called nanofocusing refractive lenses (NFLs) have a parabolic cylindrical shape with lateral structure sizes in the micrometer range. NFLs are produced by using micro-machining techniques. These micro-fabrication processes and technologies are introduced. The results of the optimization and the final fabrication process for silicon lenses are presented. Subsequently, two experiments that are exemplary for the use of NFLs, are introduced. The first one employs a high-resolution scanning fluorescence mapping of a geological sample, and the second one is a coherent x-ray diffraction imaging (CXDI) experiment. CXDI is able to reconstruct the illuminated object from recorded coherent diffraction patterns. In a scanning mode, referred to as ptychography, this method is even able to reconstruct the illumination and the object simultaneously. Especially the reconstructed illumination and the possibility of computed propagation of the wavefield along the focused beam yields findings about the optic used. The collected data give interesting information about the lenses and their aberrations. Comparison of simulated and measured data shows good agreement. Following this, the fabrication process of diamond lenses is described. Diamond with its extraordinary properties is well-suited as lens material for refractive lenses. Finally, a concluding overview of the present and future work of nanofocusing lenses is given
Diese Dissertation beschäftigt sich mit der Entwicklung und Optimierung der Herstellungsprozesse von refraktiven nanofokussierenden Röntgenlinsen. Diese aus Silizium oder Diamant hergestellten Optiken, sind hervorragend für hochauflösende Röntgen\-mikroskopie geeignet. Ziel dieser Arbeit ist es, einen reproduzierbaren Herstellungsprozess zu erarbeiten, der es erlaubt, Siliziumlinsen von hoher Präzision, Qualität und Quantität zu fertigen. Zusätzlich soll ein Prozess für Diamantlinsen entwickelt und etabliert werden. In der folgenden Arbeit werden die theoretischen Grundlagen von Röntgenstrahlung und deren Wechselwirkung mit Materie beschrieben. Spezielle Aspekte der Synchrotronstrahlung werden hervorgehoben. Wichtig im Zusammenhang mit Röntgenmikroskopie sind die verschieden Optiken. Deren Details, Vor- und Nachteile, insbesondere die der brechenden Linsen, werden genannt. Zur Erzeugung fein gebündelter Röntgenmikrostrahlen im Bereich unter 100nm lateraler Größe benötigt man sehr kurze Brennweiten. Mit brechenden Linsen lässt sich dieses mittels eines kompakten Linsendesigns von vielen hintereinander gestapelten Einzellinsen realisieren. Die so genannten refraktiven nanofokussierenden Linsen (NFLs) besitzen eine parabolische Zylinderform mit lateralen Strukturgrößen im Mikrometerbereich. NFLs werden mittels spezieller Technologien der Mikroprozessierung hergestellt. Diese Mikrostrukturierungsverfahren werden mit ihren jeweiligen Prozessschritten und zugehörenden Technologien vorgestellt. Die Ergebnisse der Optimierung und der endgültige Mikrostrukturierungsprozess für Siliziumlinsen werden dargelegt. Im Anschluss daran werden zwei Experimente erläutert, die beispielhaft für die Anwendung von NFLs stehen. Ersteres ist ein ortsaufgelöstes Fluoreszenzrasterexperiment einer geologischen Probe und das zweite ein kohärentes Röntgen-Beugungsexperiment (CXDI). CXDI ist in der Lage, aus kohärent aufgenommen Beugungsbildern das beleuchtete Objekt zu rekonstruieren. Kombiniert mit einem rasternden Verfahren, welches Ptychographie genannt wird, ist diese Methode in der Lage, die Beleuchtungsfunktion und das Objekt gleichzeitig zu rekonstruieren. Besonderes die rekonstruierte Beleuchtungsfunktion und die Möglichkeit der computergestützten Propagation des Wellenfeldes entlang des fokussierten Strahls, geben aufschlussreiche Informationen über die verwendete Optik. Neue Erkenntnisse über die Linsen und deren Aberrationen können so gewonnen werden. Vergleiche von simulierten mit gemessenen Daten zeigen gute Übereinstimmung. Daran anschließend erfolgt die Beschreibung der Entwicklung eines Fabrikationsprozess für Diamantlinsen. Diamant mit seinen außergewöhnlichen Materialeigenschaften ist besonders gut als Linsenmaterial für refraktive Röntgenlinsen geeignet. Abschliessend wird ein zusammenfassender Überblick über die derzeitigen und die zu erwartenden Entwicklungen bei refraktiven Linsen gegeben

Reflected-light digital holographic microscope developed at IPE FME BUT uses off-axis holography principle and low spatial and temporal coherence illumination. Microscope allows reconstruction of the image amplitude and the image phase, which can be handled in real time. The only limiting factors are imaging speed of the detector and computer performance when processing holograms. Reconstruction of image phase and amplitude allows high-resolution profilometric measurements in the vertical axis direction. This thesis deals with the automatization of profilometric measurement method proposed in [2]. Proposed method uses the combination of the image phase and the image amplitude for the measurement of specimens with surface structure the vertical size of which cause the uncertainty of the image phase by a factor of 2pí. Futher the thesis deals with the construction design of the illumination system of the microscope and its realization together with experimental verification of functionality of proposed method automatization.

Cette thèse a pour objectif l’étude d’un lien effectif potentiel entre la motilité cellulaire, la mécanique cellulaire, et l’activité biochimique de ces mêmes cellules. Ce couplage a été étudié dans divers systèmes biologiques, et aussi bien dans des cultures de cellules qu’à l’intérieur de tissus plus complexes. Notamment, nous avons particulièrement cherché à détecter un couplage électromécanique dans des neurones qui pourrait être impliqué dans la propagation du message nerveux.Pour ce faire, nous avons dû développer deux microscopes optiques à la sensibilité extrême. Ces microscopes se composent de deux parties principales. La première sert à détecter des mouvements axiaux plus petits que la longueur d’onde optique, soit en dessous de 100 nanomètres. La deuxième partie permet la détection d’un signal de fluorescence, offrant la possibilité de suivre l’évolution biochimique de la cellule. Avec ces deux microscopes multimodaux, il est donc possible de suivre de manière simultanée un contraste de motilité, un contraste mécanique, un contraste structurel et un contraste biochimique. Si l’un de ces systèmes est basé sur la tomographie de cohérence optique plein champ et permet de faire de telles mesures en 3-D et en profondeur dans les tissus biologiques, le second ne permet que des mesures dans des cultures de cellules, mais est bien plus robuste au bruit mécanique. Dans ce manuscrit, nous allons essentiellement décrire le développement de ces deux appareils, et préciser les contrastes auxquels ils sont sensibles spécifiquement.Nous développerons également deux des applications principales de ces microscopes que nous avons étudié dans le détail au cours de cette thèse. La première application développe l’intérêt d’un de nos microscopes pour la détection sans marquage des principaux composants cellulaires et structuraux de la cornée et de la rétine. La seconde application tend à détecter et à suivre des ondes électromécaniques dans des neurones de mammifères
This PhD project aims to explore the relationship that might exist between the dynamic motility and mechanical behavior of different biological systems and their biochemical activity. In particular,we were interested in detecting the electromechanical coupling that may happen in active neurons, and may assist in the propagation of the action potential. With this goal in mind, we have developed two highly sensitive optical microscopes that combine one modality that detects sub-wavelength axial displacements using optical phase imaging and another modality that uses a fluorescence path. Therefore, these multimodal microscopes can combine a motility, a mechanical,a structural and a biochemical contrast at the same time. One of this system is based ona multimodal combination of full-field optical coherence tomography (FF-OCT) and allows the observation of such contrast inside thick and scattering biological tissues. The other setup provides a higher displacement sensitivity, but is limited to measurements in cell cultures. In this manuscript, we mainly discuss the development of both systems and describe the various contrastst hey can reveal. Finally, we have largely used our systems to investigate diverse functions of the eye and to look for electromechanical waves in cell cultures. The thorough description of both biological applications is also provided in the manuscript

Dans le cadre de la théorie mathématique de l’échantillonnage comprimé (Compressed Sensing, CS), développée récemment, il est possible de reconstruire un signal ou une image à partir de très peu d’acquisitions. Dans cette thèse, nous étudions comment cette théorie peut être adaptée à deux techniques de microscopie optique : la microscopie à fluorescence, et la tomographie en cohérence optique. Ces deux technologies présentent chacune des limitations, qui peuvent être corrigées par prise en compte de stratégies d’échantillonnage comprimé, que l’on peut diviser en deux catégories : des solutions algorithmiques propres au traitement d’image, et des techniques d’acquisition optique
The mathematical theory of Compressed Sensing (CS) is a recently developed framework that enables the reconstruction of a signal or an image from very few measurements. In this thesis, we investigate how this theory can be implemented in the context of two optical microscopy techniques : fluorescence microscopy, and optical coherence tomography. Both technologies present different limitations which we prove can be tackled by the embedding of CS driven strategies. The latter can be divided into two categories : image processing algorithmic solutions, and optical acquisition techniques

Tato diplomová práce se zabývá výzkumem na téma vlivu prostorové koherence osvětlení. Účelem je určit schopnost osové lokalizace při zobrazení Koherencí řízeným holografickým mikroskopem (CCHM) v závislosti na různé prostorové koherenci světelného zdroje. Osová lokalizace je v tomto případě zkoumána jako kvalita rozlišení drobných detailů trojrozměrného vzorku, umístěných nad sebou. Teorie zobrazení holografickým mikroskopem a teorie rozptylu v nehomogenních prostředích je shrnuta v první části práce, v rozsahu nutném pro pochopení části praktické. Základní princip fungování mikroskopu a přesný popis jeho uspořádání je zde podrobně popsán. Proběhl mechanický návrh stavební úpravy mikroskopu tak, aby bylo možno využívat kondenzorovou optiku s vysokou numerickou aperturou a omezenými optickými vadami. Několik různých přístupů, které by mohly vést ke zlepšení zobrazovacích vlastností mikroskopu, bylo navrženo a vyzkoušeno a jsou zde popsány i s jejich výhodami a nevýhodami. Pro experimentální část práce byl vyroben modelový vzorek. Závislost osové lokalizace na prostorové koherenci osvětlení byla demonstrována pomocí simulace a následně ověřena experimentálně, pozorováním vyrobeného modelového vzorku. Experimentální výsledky potvrzují základní principy vycházející ze zmíněné teorie. Na závěr jsou navržena možná vylepšení, pro budoucí zpřesnění výsledků.

碩士
國立中正大學
資訊工程研究所
103
Indocyanine green (ICG) angiography is an imagingmethod for doctor to observe choroidal abnormalities. But, IGC angiography often has unfixed viewpoint and shadows which makes it difficult to be used in clinical practice. In this thesis, we propose a novel illumination normalization method to alleviate the shadows in ICG angiography. In particular, we first align the viewpoint of the input ICG angiography using an existing image registration method. Then, we can acquire temporal information using time-dependent intrinsic image and compute the corresponding illumination image. Finally, we can remove shadow from the illumination image by estimating contrast and luminosity distortion. In our experimental validation, we use two video quality assessment methods to evaluate the performance of our proposed illumination normalization method. The results show that our proposed method can help improve the visual quality of ICG angiography.

碩士
國立中央大學
光電科學與工程學系
103
Optical microscopies have been applied widely for observations and measurements in fields of biology, materials, etc., mainly because of its non-invasive nature. However, the wave properties of light have limited the lateral resolutions of far-field optical microscopies to half of its excitation wavelength. Yet, as technology has greatly advanced, the expectations for the resolving power of optical microscopies have also grown a lot higher. This article will introduce “Structured Illumination Microscopy (SIM),” a commonly applied far-field and super-resolution microscopy technique, and the principles of its image reconstruction.Since conventional structured illumination microscopies can only be used to observe samples with fluorescent properties, we’ve set up a coherent structured illumination microscopy system, and with the use of a phase-step algorithm, not only will the system’s resolution improve, it will also prevent photo bleaching in samples. In our system, a structured illumination pattern is produced by having two parallel lights interfere on the image plane, which is then used to excite the sample. And by obtaining the scattering images of different pattern directions and phases, we can solve the high frequency information. After setting up the system, we observed gold-nanoparticles, yet the resolution is enhanced only up to a factor of 1.2, which doesn’t match up with the theoretical value, 1.44. We will discuss the reasons of experimental errors later in this thesis.

Optical microscopy plays a crucial role in the biological sciences for its ability to enable visualization of biological samples at sub-cellular levels. Many imaging subdivisions exist under this umbrella of general microscopy, and each are tailored towards specific design, contrast, and visualization constraints. Standard examples that have found widespread use include dark-field, phase-contrast, holographic, and fluorescent microscopies. However, a critical factor that physically limits the optical resolution of general microscopy is diffraction. Unfortunately, this “diffraction-limit” can prevent visualization of significant biologically relevant structures, which in turn can limit biological insights. In response to such a limit, several works have advanced the field of sub-diffraction resolution imaging, which consist of optical imaging techniques that seek to achieve imaging resolutions beyond that which is allowed by the diffraction-limit. This set of techniques can largely be divided into two classes. The first class of sub-diffraction techniques is targeted towards cases where the sample is coherently illuminated and diffracts into the imaging system’s aperture. For such cases, synthetic aperture (SA) is a popular choice and operates by using oblique illuminations to spatiotemporally synthesize a wider frequency support into the image than allowed by the diffraction limit. The second class of sub-diffraction techniques, often referred to as "super-resolution" techniques, typically utilize specialized fluorophores with either photoswitching or depletion capabilities. Photoactivated localization microscopy (PALM) is a super-resolution example that localizes photoswitchable fluorophores to sub-diffraction resolutions per acquisition, before combining into a final super-resolved image. Stimulated emission depletion (STED) is another super-resolution example that spatially modulates its excitation to narrow its optical point-spread-function. Unfortunately, SA and fluorescent super-resolution techniques are generally incompatible for sub-diffraction resolution fluorescent and coherent imaging, respectively – thus, a multimodal sub-diffraction imaging solution compatible with both coherent and fluorescent imaging has remained elusive.

In this dissertation, we demonstrate that structured illumination (SI) is a sub-diffraction technique compatible with both diffractive and fluorescent imaging. We first develop the theoretical framework that extends SI to coherent imaging and experimentally demonstrate SI’s capabilities for 2D sub-diffraction resolution imaging of coherently diffractive samples. Sub-diffraction resolution imaging based on scattering intensity and transmission-based quantitative-phase (QP) are shown. In addition, we show extend SI to 3D coherent imaging, and show applications of this towards 3D QP and refractive-index (RI) tomography. Finally, we show multimodal applications of SI that allow sub-diffraction resolution fluorescent and coherent imaging, which has great potential utility for the biological sciences.

Dissertation

Realistic computer generated images are computed by combining geometric effects, reflectance models for several captured and phenomenological materials, and real-world lighting according to mathematical models of physical light transport. Several important lighting phenomena should be considered when targeting realistic image simulation. A combination of soft and hard shadows, which arise from the interaction of surface and light geometries, provide necessary shape perception cues for a viewer. A wide variety of realistic materials, from physically-captured reflectance datasets to empirically designed mathematical models, modulate the virtual surface appearances in a manner that can further dissuade a viewer from considering the possibility of computational image synthesis over that of reality. Lastly, in many important cases, light reflects off many different surfaces before entering the eye. These secondary effects can be critical in grounding the viewer in a virtual world, since the human visual system is adapted to the physical world, where such effects are constantly in play. Simulating each of these effects is challenging due to their individual underlying complexity. The net complexity is compounded when several effects are combined. This thesis will investigate real-time approaches for simulating these effects under stringent performance and memory constraints, and with varying degrees of interactivity. In order to make these computations tractable given these added constraints, I will use data and signal analysis techniques to identify predictable patterns in the different spatial and angular signals used during image synthesis. The results of this analysis will be exploited with several analytic and data-driven mathematical models that are both efficient, and yield accurate approximations with predictable and controllable error.

This thesis is concerned with the optimization and development of the production of nanofocusing refractive x-ray lenses. These optics made of either silicon or diamond are well-suited for high resolution x-ray microscopy. The goal of this work is the design of a reproducible manufacturing process which allows the production of silicon lenses with high precision, high quality and high piece number. Furthermore a process for the production of diamond lenses is to be developed and established. In this work, the theoretical basics of x-rays and their interaction with matter are described. Especially, aspects of synchrotron radiation are emphasized. Important in x-ray microscopy are the different optics. The details, advantages and disadvantages, in particular those of refractive lenses are given. To achieve small x-ray beams well beyond the 100nm range a small focal length is required. This is achieved in refractive lenses by moving to a compact lens design where several single lenses are stacked behind each other. The, so-called nanofocusing refractive lenses (NFLs) have a parabolic cylindrical shape with lateral structure sizes in the micrometer range. NFLs are produced by using micro-machining techniques. These micro-fabrication processes and technologies are introduced. The results of the optimization and the final fabrication process for silicon lenses are presented. Subsequently, two experiments that are exemplary for the use of NFLs, are introduced. The first one employs a high-resolution scanning fluorescence mapping of a geological sample, and the second one is a coherent x-ray diffraction imaging (CXDI) experiment. CXDI is able to reconstruct the illuminated object from recorded coherent diffraction patterns. In a scanning mode, referred to as ptychography, this method is even able to reconstruct the illumination and the object simultaneously. Especially the reconstructed illumination and the possibility of computed propagation of the wavefield along the focused beam yields findings about the optic used. The collected data give interesting information about the lenses and their aberrations. Comparison of simulated and measured data shows good agreement. Following this, the fabrication process of diamond lenses is described. Diamond with its extraordinary properties is well-suited as lens material for refractive lenses. Finally, a concluding overview of the present and future work of nanofocusing lenses is given.
Diese Dissertation beschäftigt sich mit der Entwicklung und Optimierung der Herstellungsprozesse von refraktiven nanofokussierenden Röntgenlinsen. Diese aus Silizium oder Diamant hergestellten Optiken, sind hervorragend für hochauflösende Röntgen\-mikroskopie geeignet. Ziel dieser Arbeit ist es, einen reproduzierbaren Herstellungsprozess zu erarbeiten, der es erlaubt, Siliziumlinsen von hoher Präzision, Qualität und Quantität zu fertigen. Zusätzlich soll ein Prozess für Diamantlinsen entwickelt und etabliert werden. In der folgenden Arbeit werden die theoretischen Grundlagen von Röntgenstrahlung und deren Wechselwirkung mit Materie beschrieben. Spezielle Aspekte der Synchrotronstrahlung werden hervorgehoben. Wichtig im Zusammenhang mit Röntgenmikroskopie sind die verschieden Optiken. Deren Details, Vor- und Nachteile, insbesondere die der brechenden Linsen, werden genannt. Zur Erzeugung fein gebündelter Röntgenmikrostrahlen im Bereich unter 100nm lateraler Größe benötigt man sehr kurze Brennweiten. Mit brechenden Linsen lässt sich dieses mittels eines kompakten Linsendesigns von vielen hintereinander gestapelten Einzellinsen realisieren. Die so genannten refraktiven nanofokussierenden Linsen (NFLs) besitzen eine parabolische Zylinderform mit lateralen Strukturgrößen im Mikrometerbereich. NFLs werden mittels spezieller Technologien der Mikroprozessierung hergestellt. Diese Mikrostrukturierungsverfahren werden mit ihren jeweiligen Prozessschritten und zugehörenden Technologien vorgestellt. Die Ergebnisse der Optimierung und der endgültige Mikrostrukturierungsprozess für Siliziumlinsen werden dargelegt. Im Anschluss daran werden zwei Experimente erläutert, die beispielhaft für die Anwendung von NFLs stehen. Ersteres ist ein ortsaufgelöstes Fluoreszenzrasterexperiment einer geologischen Probe und das zweite ein kohärentes Röntgen-Beugungsexperiment (CXDI). CXDI ist in der Lage, aus kohärent aufgenommen Beugungsbildern das beleuchtete Objekt zu rekonstruieren. Kombiniert mit einem rasternden Verfahren, welches Ptychographie genannt wird, ist diese Methode in der Lage, die Beleuchtungsfunktion und das Objekt gleichzeitig zu rekonstruieren. Besonderes die rekonstruierte Beleuchtungsfunktion und die Möglichkeit der computergestützten Propagation des Wellenfeldes entlang des fokussierten Strahls, geben aufschlussreiche Informationen über die verwendete Optik. Neue Erkenntnisse über die Linsen und deren Aberrationen können so gewonnen werden. Vergleiche von simulierten mit gemessenen Daten zeigen gute Übereinstimmung. Daran anschließend erfolgt die Beschreibung der Entwicklung eines Fabrikationsprozess für Diamantlinsen. Diamant mit seinen außergewöhnlichen Materialeigenschaften ist besonders gut als Linsenmaterial für refraktive Röntgenlinsen geeignet. Abschliessend wird ein zusammenfassender Überblick über die derzeitigen und die zu erwartenden Entwicklungen bei refraktiven Linsen gegeben.

Although current augmented, virtual, and mixed reality (AR/VR/MR) systems are facing advanced and immersive experience in the entertainment industry with countless media forms. Theses systems suffer a lack of correct direct and indirect illumination modeling where the virtual objects render with the same lighting condition as the real environment. Some systems are using baked GI, pre-recorded textures, and light probes that are mostly accomplished offline to compensate for precomputed real-time global illumination (GI). Thus, illumination information can be extracted from the physical scene for interactively rendering the virtual objects into the real world which produces a more realistic final scene in real-time. This work approaches the problem of visual coherence in AR by proposing a system that detects the real-world lighting conditions in dynamic scenes, then uses the extracted illumination information to render the objects added to the scene. The system covers several major components to achieve a more realistic augmented reality outcome. First, the detection of the incident light (direct illumination) from the physical scene with the use of computer vision techniques based on the topological structural analysis of 2D images using a live-feed 360^o camera instrumented on an AR device that captures the entire radiance map. Also, the physics-based light polarization eliminates or reduces false-positive lights such as white surfaces, reflections, or glare which negatively affect the light detection process. Second, the simulation of the reflected light (indirect illumination) that bounce between the real-world surfaces to be rendered into the virtual objects and reflect their existence in the virtual world. Third, defining the shading characteristic/properties of the virtual object to depict the correct lighting assets with a suitable shadow casting. Fourth, the geometric properties of real-scene including plane detection, 3D surface reconstruction, and simple meshing are incorporated with the virtual scene for more realistic depth interactions between the real and virtual objects. These components are developed methods which assumed to be working simultaneously in real-time for photo-realistic AR. The system is tested with several lighting conditions to evaluate the accuracy of the results based on the error incurred between the real/virtual objects casting shadow and interactions. For system efficiency, the rendering time is compared with previous works and research. Further evaluation of human perception is conducted through a user study. The overall performance of the system is investigated to reduce the cost to a minimum.