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111	Études et conception d'algorithmes de reconstruction 3D sur tablettes : génération automatique de modèles 3D éditables de bâtiments existants / Study and Conception of 3D Reconstruction Algorithms on Tablets : Automatic Generation of 3D Editable Models of Existing Buildings Arnaud, Adrien 03 December 2018 (has links) L'objectif de ces travaux de thèse consiste à mettre en place des solutions algorithmiques permettant de reconstruire un modèle 3D éditable d'un environnement intérieur à l'aide d'une tablette équipée d'un capteur de profondeur.Ces travaux s'inscrivent dans le contexte de la rénovation d'intérieur. Les normes Européennes poussent à la rénovation énergétique et à la modélisation 3D des bâtiments existants. Des outils professionnels utilisant des capteurs de type LIDAR permettent de reconstruire des nuages de points de très grande qualité, mais sont coûteux et longs à mettre en œuvre. De plus, il est très difficile d'identifier automatiquement les constituants d'un bâtiment pour en exporter un modèle 3D éditable complet.Dans le cadre de la rénovation d’intérieur, il n'est pas nécessaire de disposer des informations sur l'ensemble du bâtiment, seules les principales dimensions et surfaces sont nécessaires. Nous pouvons alors envisager d'automatiser complètement le processus de modélisation 3D.La mise sur le marché de capteurs de profondeur intégrables sur tablettes, et l'augmentation des capacités de calcul de ces dernières nous permet d'envisager l'adaptation d'algorithmes de reconstruction 3D classiques à ces supports.Au cours de ces travaux, nous avons envisagé deux approches de reconstruction 3D différentes. La première approche s'appuie sur des méthodes de l'état de l'art. Elle consiste à générer un maillage 3D d'un environnement intérieur en temps réel sur tablette, puis d'utiliser ce maillage 3D pour identifier la structure globale du bâtiment (murs, portes et fenêtres). La deuxième approche envisagée consiste à générer un modèle 3D éditable en temps réel, sans passer par un maillage intermédiaire. De cette manière beaucoup plus d'informations sont disponibles pour pouvoir détecter les éléments structuraux. Nous avons en effet à chaque instant donné un nuage de points complet ainsi que l'image couleur correspondante. Nous avons dans un premier temps mis en place deux algorithmes de segmentation planaire en temps réel. Puis, nous avons mis en place un algorithme d'analyse de ces plans permettant d'identifier deux plans identiques sur plusieurs prises de vue différentes. Nous sommes alors capables d'identifier les différents murs contenus dans l'environnement capturé, et nous pouvons mettre à jour leurs informations géométriques en temps réel. / This thesis works consisted to implement algorithmic solutions to reconstruct an editable 3D model of an indoor environment using a tablet equipped with a depth sensor.These works are part of the context of interior renovation. European standards push for energy renovation and 3D modeling of existing buildings. Professional tools using LIDAR-type sensors make it possible to reconstruct high-quality point clouds, but are costly and time-consuming to implement. In addition, it is very difficult to automatically identify the constituents of a building to export a complete editable 3D model.As part of the interior renovation, it is not necessary to have information on the whole building, only the main dimensions and surfaces are necessary. We can then consider completely automating the 3D modeling process.The recent development of depth sensors that can be integrated on tablets, and the improvement of the tablets computation capabilities allows us to consider the adaptation of classical 3D reconstruction algorithms to these supports.During this work, we considered two different 3D reconstruction approaches. The first approach is based on state-of-the-art methods. It consists of generating a 3D mesh of an interior environment in real time on a tablet, then using this 3D mesh to identify the overall structure of the building (walls, doors and windows). The second approach envisaged is to generate a 3D editable model in real time, without passing through an intermediate mesh. In this way much more information is available to be able to detect the structural elements. We have in fact at each given time a complete point cloud as well as the corresponding color image. In a first time we have set up two planar segmentation algorithms in real time. Then, we set up an analysis algorithm of these plans to identify two identical planes on different captures. We are then able to identify the different walls contained in the captured environment, and we can update their geometric information in real-time. Reconstruction 3D Systèmes mobiles Segmentation 3D 3D reconstruction Mobile devices 3D segmentation
112	Reconstruction 3D infrarouge par perception active / 3D infrared reconstruction with active perception Ducarouge, Benoit 26 September 2011 (has links) Ces travaux de thèse ont été menés dans le contexte du projet ANR blanc "Real Time and True Temperature measurement" (R3T), dédié à la métrologie thermique à partir de mesures dans l'infrarouge. L'estimation d'une température vraie à partir d'une mesure de température apparente par une caméra infrarouge, exploite un modèle radiométrique dans lequel apparaît des facteurs qui dépendent de la nature et de la forme de l'objet considéré. Ces travaux portent sur la construction d'un modèle géométrique de l'objet à partir de caméras infrarouges déplacées par un robot autour d'un objet.Ces caméras, par rapport à des caméras standards, ont des caractéristiques spécifiques : faible résolution, peu de texture. Afin de faciliter la mise en œuvre et de minimiser la complexité du système final, nous avons choisi une approche de stéréovision non calibrée. Nous avons donc un banc de stéréovision infrarouge embarqué sur un robot cartésien, pour acquérir plusieurs vues de l'objet d'intérêt ; les principales étapes concernent la rectification non calibrée des images acquises par le banc stéréo, puis le calibrage des caméras rectifiées et de la relation main-œil sans utilisation de mire, puis la construction de modèles 3D locaux denses et le recalage de ces modèles partiels pour construire un modèle global de l'objet. Les contributions portent sur les deux premières étapes, rectification et calibrage pour la stéréovision. Pour la rectification non calibrée, il est proposé une approche d'optimisation sous contraintes qui estime les homographies, à appliquer sur ces images pour les rectifier, sans calcul préalable de la matrice Fondamentale, tout en minimisant les déformations projectives entre images d'origine et images rectifiées. La fonction coût est calculée à partir de la distance de Sampson avec une décomposition de la matrice fondamentale. Deux types de contraintes, géométriques et algébriques, sont comparés pour minimiser les déformations projectives. L'approche proposée est comparée aux méthodes proposées par Loop et Zhang, Hartley, Mallon et al... sur des jeux de données classiques de la littérature. Il est montré que les résultats sont au moins équivalents sur des images classiques et meilleurs sur des images de faible qualité comme des images infrarouges.Pour le calibrage sans mire, l'auteur propose de calibrer les caméras ainsi que la transformation main-œil, indispensable dès lors que le banc stéréo est porté par un robot, en une seule étape ; l'une des originalités est que cette méthode permet de calibrer les caméras préalablement rectifiées et ainsi de minimiser le nombre de paramètres à estimer. De même plusieurs critères sont proposés et évalués par de nombreux résultats sur des données de synthèse et sur des données réelles. Finalement, les méthodes de stéréovision testées pour ce contexte applicatif sont rapidement décrites ; des résultats expérimentaux acquis sur des objets sont présentés ainsi que des comparaisons vis-à-vis d'une vérité terrain connue / This dissertation was lead in the context of the R3T project (Real Time and True Temperature measurement), dedicated to metrology from thermal infrared measurements. The estimation of true temperature from apparent temperature measurement by an infrared camera uses a radiometric model which depends on nature and shape of the considered object. This work focuses on the construction of a geometric model from infrared cameras moved by a robot around an object.Those cameras, in comparison with standard ones, have specific characteristics : low resolution, low texture. To minimize the complexity and easily implement the final system, we chose a stereo approach using uncalibrated cameras. So we have an infrared stereoring embeded on a Cartesian robot, to acquire multiple views of the object of interest. First, the main steps implemented concern uncalibrated images rectification and autocalibration of infrared stereoring and hand-eye transformation without use of a calibration pattern. Then, the reconstruction of locals 3D models and the merge of these models was done to reach a global model of the object. The contributions cover the first two stages, rectification and autocalibration, for the other stereo reconstruction steps, different algorithms were tested and the best was chosen for our application.For the uncalibrated images rectification, an optimization approach under constraints is proposed. The estimation of rectification homographies is done, without the Fundamental matrix determination, while minimizing the distortion between original and corrected images. The cost function is based on the Sampson's distance with breakdown of the Fundamental matrix. Two constraints, geometrical and analytical, are compared to minimize distortion. The proposed approach is compared to methods proposed by Loop and Zhang, Hartley, Mallon et al ... on data sets from state of art. It is shown that the results are at least equivalent on conventional images and better on low quality images such as infrared images.For the autocalibration, the author proposes to calibrate cameras and hand-eye transformation, essential whenever the stereoring is embedded on a robot, in one step. One of the originality is that this method allows to calibrate rectified cameras and so minimize the number of parameters to estimate. Similarly, several criteria are proposed and evaluated by numerous results on synthetic and real data.Finally, all methods of stereovision tested for this application context are briefly described, the experimental results obtained on objects are presented and compared to ground truth Infrarouge Stéréovision Autocalibrage Reconstruction 3D Infrared Stereovision Rectification Autocalibration 3D reconstruction 621.3
113	Geometric and electrochemical characteristics of lithium ion batteries Kang, Huixiao 05 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The geometric and electrochemical characteristics of different lithium ion batteries (LIBs) are investigated in this study. The core work is to study the impact of the calendering process on NMC cathode electrodes performance. X-ray CT image processing by Python, MATLAB, ImageJ and Avizo is utilized in this study. NMC electrodes with different calendering conditions were fabricated to calculate electrochemical properties of the cells. Charge/discharge of the electrodes under 0.1C, 0.2C, 0.4C, 1C, 2C, 4C and 0.1C (retention test) rates were cycled for three times respectively between 4.2 V and 3.0 V. Electrochemical impedance spectroscopy testing was used to further explain the effects of NMC density on rate capability. Geometric properties of NMC electrodes with different calendering conditions were calculated from the computed tomography data of the electrodes. A synchrotron transmission X-ray microscopy tomography system at the Advanced Photon Source of the Argonne National Laboratory was employed to obtain the tomography data. X-ray CT image processing before the data analysis was introduced. Python based Tomopy and ASTRA toolbox were used to filter the original HDF5 data and reconstruction. ImageJ was used to help remove noise, adjust contrast and cropping. Iso2mesh and image processing tool box were used in MATLAB to generate meshed 3D structure of CT data. Geometric properties of NMC electrodes including porosity, pore size distribution, particle size distribution, specific surface area and tortuosity were calculated from the computed tomography data of the electrodes. The geometric and electrochemical analysis show that calendering can increase the electrochemically active area, which lead to improving of the rate capability. However, more calendering will result in crushing of NMC particles, which can reduce the electrode capacity at relatively high C rates. This study shows that the optimum electrochemical performance of NMC electrode at 94:3:3 weight ratio of NMC:binder:carbon black can be achieved by calendering to 3.0 g/cm3 NMC density. LTAP solid electrolyte and NMC cathode material mix electrode-electrolyte X-ray CT data was studied in last chapter. By using 8 kev X-ray energy, we could distinguish NMC active material, LTAP solid electrolyte and the others three phase. On the basis of NMC electrode image processing method, dilation and multiply threshold method is applied to get three-phase 3D geometry. A comparing of connection area between NMC and LTAP of 700psi and 1300psi electrode was analyzed. Geometric properties like tortuosity, di_usion length and e_ective di_usivity were generated from the CT data. Lithium ion battery NMC LTAP X-ray CT Geometric analysis 3D reconstruction Solid electrolyte
114	Získání 3D informací o struktuře vyvíjeného materiálu Si3N4 pro válcovávání legovaných drátů / 3D microstructure evaluation of developed Si3N4 material for alloyed wire rolling applications Lövy, Vít January 2014 (has links) This diploma thesis is devoted to the use of 3D reconstruction using EBSD method for microstructural analysis of silicon nitride ceramic material predetermined for the rolling-mill used in the wire production. Application of this method can be used for the grain structure reconstruction and basic microstructural parameters can be than extracted. The development of a suitable method for 3D reconstruction of the structure of the materials the main aim of this work. There are described the different steps begun by sample preparation from the investigated material trough the optimisation of analysis parameters up to the visualization of the grain structure. New type of sample geometry has been designed which leads to the better and faster observation of the microstructure of ceramic materials. This thesis also describes optimal reconstruction parameters such as the geometry of the assembly used in the microscope without mechanical movement of the sample or the influence of conductive coating prepared via in-situ sputtering of suitable metal, or adjustment of the electron and ion beams. Further are described two options of software which can be used for the final generation of 3D structure information and are assessed their advantages and disadvantages. The effect of the filter setting and other parameters and their influence on the resulting structural parameters are also evaluated.
115	Study on High-resolution 3D Reconstruction using Linear CCD Imagers / 線形イメージセンサーを用いた高解像度３次元画像構築に関する研究 Zhang, Pengchang 23 March 2016 (has links) 京都大学 / 0048 / 新制・課程博士 / 博士(工学) / 甲第19700号 / 工博第4155号 / 新制\|\|工\|\|1641(附属図書館) / 32736 / 京都大学大学院工学研究科機械理工学専攻 / (主査)教授井手亜里, 教授松野文俊, 教授蓮尾昌裕 / 学位規則第4条第1項該当 / Doctor of Philosophy (Engineering) / Kyoto University / DGAM High resolution High color fidelity 3D reconstruction Linear image sensor 500
116	3-Dimensional Analysis of the Renal Fornix in Normal and Obstructed Mice Hunter, Leah Danielle January 2018 (has links) No description available. Anatomy and Physiology Medicine
117	A Structured Light Based 3D Reconstruction Using Combined Circular Phase Shifting Patterns Zhang, Yujia 11 July 2019 (has links) No description available. Civil Engineering Earth Geography Optics
118	3D Image Reconstruction and Level Set Methods Patty, Spencer R. 13 July 2011 (has links) (PDF) We give a concise explication of the theory of level set methods for modeling motion of an interface as well as the numerical implementation of these methods. We then introduce the geometry of a camera and the mathematical models for 3D reconstruction with a few examples both simulated and from a real camera. We finally describe the model for 3D surface reconstruction from n-camera views using level set methods. Level Set Method PDE Differential Geometry Computer Vision 3D Reconstruction Mathematics
119	Quality Analysis of UAV based 3D Reconstruction and its Applications in Path Planning Rathore, Aishvarya 04 October 2021 (has links) No description available. Computer Science UAV 3D Reconstruction Drone Quality Analysis Path Planning Algorithm
120	Multi-view Approaches To Tracking, 3d Reconstruction And Object Class Detection Khan, Saad 01 January 2008 (has links) Multi-camera systems are becoming ubiquitous and have found application in a variety of domains including surveillance, immersive visualization, sports entertainment and movie special effects amongst others. From a computer vision perspective, the challenging task is how to most efficiently fuse information from multiple views in the absence of detailed calibration information and a minimum of human intervention. This thesis presents a new approach to fuse foreground likelihood information from multiple views onto a reference view without explicit processing in 3D space, thereby circumventing the need for complete calibration. Our approach uses a homographic occupancy constraint (HOC), which states that if a foreground pixel has a piercing point that is occupied by foreground object, then the pixel warps to foreground regions in every view under homographies induced by the reference plane, in effect using cameras as occupancy detectors. Using the HOC we are able to resolve occlusions and robustly determine ground plane localizations of the people in the scene. To find tracks we obtain ground localizations over a window of frames and stack them creating a space time volume. Regions belonging to the same person form contiguous spatio-temporal tracks that are clustered using a graph cuts segmentation approach. Second, we demonstrate that the HOC is equivalent to performing visual hull intersection in the image-plane, resulting in a cross-sectional slice of the object. The process is extended to multiple planes parallel to the reference plane in the framework of plane to plane homologies. Slices from multiple planes are accumulated and the 3D structure of the object is segmented out. Unlike other visual hull based approaches that use 3D constructs like visual cones, voxels or polygonal meshes requiring calibrated views, ours is purely-image based and uses only 2D constructs i.e. planar homographies between views. This feature also renders it conducive to graphics hardware acceleration. The current GPU implementation of our approach is capable of fusing 60 views (480x720 pixels) at the rate of 50 slices/second. We then present an extension of this approach to reconstructing non-rigid articulated objects from monocular video sequences. The basic premise is that due to motion of the object, scene occupancies are blurred out with non-occupancies in a manner analogous to motion blurred imagery. Using our HOC and a novel construct: the temporal occupancy point (TOP), we are able to fuse multiple views of non-rigid objects obtained from a monocular video sequence. The result is a set of blurred scene occupancy images in the corresponding views, where the values at each pixel correspond to the fraction of total time duration that the pixel observed an occupied scene location. We then use a motion de-blurring approach to de-blur the occupancy images and obtain the 3D structure of the non-rigid object. In the final part of this thesis, we present an object class detection method employing 3D models of rigid objects constructed using the above 3D reconstruction approach. Instead of using a complicated mechanism for relating multiple 2D training views, our approach establishes spatial connections between these views by mapping them directly to the surface of a 3D model. To generalize the model for object class detection, features from supplemental views (obtained from Google Image search) are also considered. Given a 2D test image, correspondences between the 3D feature model and the testing view are identified by matching the detected features. Based on the 3D locations of the corresponding features, several hypotheses of viewing planes can be made. The one with the highest confidence is then used to detect the object using feature location matching. Performance of the proposed method has been evaluated by using the PASCAL VOC challenge dataset and promising results are demonstrated. Computer vision visual tracking 3D reconstruction object detection Computer Sciences Engineering

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