Global ETD Search

581	Parallel distributed-memory particle methods for acquisition-rate segmentation and uncertainty quantifications of large fluorescence microscopy images Afshar, Yaser 08 November 2016 (has links) (PDF) Modern fluorescence microscopy modalities, such as light-sheet microscopy, are capable of acquiring large three-dimensional images at high data rate. This creates a bottleneck in computational processing and analysis of the acquired images, as the rate of acquisition outpaces the speed of processing. Moreover, images can be so large that they do not fit the main memory of a single computer. Another issue is the information loss during image acquisition due to limitations of the optical imaging systems. Analysis of the acquired images may, therefore, find multiple solutions (or no solution) due to imaging noise, blurring, and other uncertainties introduced during image acquisition. In this thesis, we address the computational processing time and memory issues by developing a distributed parallel algorithm for segmentation of large fluorescence-microscopy images. The method is based on the versatile Discrete Region Competition (Cardinale et al., 2012) algorithm, which has previously proven useful in microscopy image segmentation. The present distributed implementation decomposes the input image into smaller sub-images that are distributed across multiple computers. Using network communication, the computers orchestrate the collective solving of the global segmentation problem. This not only enables segmentation of large images (we test images of up to 10^10 pixels) but also accelerates segmentation to match the time scale of image acquisition. Such acquisition-rate image segmentation is a prerequisite for the smart microscopes of the future and enables online data inspection and interactive experiments. Second, we estimate the segmentation uncertainty on large images that do not fit the main memory of a single computer. We there- fore develop a distributed parallel algorithm for efficient Markov- chain Monte Carlo Discrete Region Sampling (Cardinale, 2013). The parallel algorithm provides a measure of segmentation uncertainty in a statistically unbiased way. It approximates the posterior probability densities over the high-dimensional space of segmentations around the previously found segmentation. / Moderne Fluoreszenzmikroskopie, wie zum Beispiel Lichtblattmikroskopie, erlauben die Aufnahme hochaufgelöster, 3-dimensionaler Bilder. Dies führt zu einen Engpass bei der Bearbeitung und Analyse der aufgenommenen Bilder, da die Aufnahmerate die Datenverarbeitungsrate übersteigt. Zusätzlich können diese Bilder so groß sein, dass sie die Speicherkapazität eines einzelnen Computers überschreiten. Hinzu kommt der aus Limitierungen des optischen Abbildungssystems resultierende Informationsverlust während der Bildaufnahme. Bildrauschen, Unschärfe und andere Messunsicherheiten können dazu führen, dass Analysealgorithmen möglicherweise mehrere oder keine Lösung für Bildverarbeitungsaufgaben finden. Im Rahmen der vorliegenden Arbeit entwickeln wir einen verteilten, parallelen Algorithmus für die Segmentierung von speicherintensiven Fluoreszenzmikroskopie-Bildern. Diese Methode basiert auf dem vielseitigen "Discrete Region Competition" Algorithmus (Cardinale et al., 2012), der sich bereits in anderen Anwendungen als nützlich für die Segmentierung von Mikroskopie-Bildern erwiesen hat. Das hier präsentierte Verfahren unterteilt das Eingangsbild in kleinere Unterbilder, welche auf die Speicher mehrerer Computer verteilt werden. Die Koordinierung des globalen Segmentierungsproblems wird durch die Benutzung von Netzwerkkommunikation erreicht. Dies erlaubt die Segmentierung von sehr großen Bildern, wobei wir die Anwendung des Algorithmus auf Bildern mit bis zu 10^10 Pixeln demonstrieren. Zusätzlich wird die Segmentierungsgeschwindigkeit erhöht und damit vergleichbar mit der Aufnahmerate des Mikroskops. Dies ist eine Grundvoraussetzung für die intelligenten Mikroskope der Zukunft, und es erlaubt die Online-Betrachtung der aufgenommenen Daten, sowie interaktive Experimente. Wir bestimmen die Unsicherheit des Segmentierungsalgorithmus bei der Anwendung auf Bilder, deren Größe den Speicher eines einzelnen Computers übersteigen. Dazu entwickeln wir einen verteilten, parallelen Algorithmus für effizientes Markov-chain Monte Carlo "Discrete Region Sampling" (Cardinale, 2013). Dieser Algorithmus quantifiziert die Segmentierungsunsicherheit statistisch erwartungstreu. Dazu wird die A-posteriori-Wahrscheinlichkeitsdichte über den hochdimensionalen Raum der Segmentierungen in der Umgebung der zuvor gefundenen Segmentierung approximiert. Parallelverarbeitung verteilter Speicher Bildsegmentierung Segmentierungsunsicherheit Partikelmethode Aufnahmerate des Mikroskops Fluoreszenzmikroskopie-Bildern große Bilder 3-dimensionale Bilder verteilter paralleler Algorithmus Discrete Region Competition Discrete Region Sampling Markov-chain Monte Carlo parallel computing distributed-memory image segmentation segmentation uncertainty particle method acquisition-rate fluorescence microscopy images large images three-dimensional images distributed parallel algorithm Discrete Region Competition Discrete Region Sampling Markov-chain Monte Carlo ddc:004 rvk:ST 330
582	Duas abordagens para casamento de padrões de pontos usando relações espaciais e casamento entre grafos / Two approaches for point set matching using spatial relations for graph matching Noma, Alexandre 07 July 2010 (has links) Casamento de padrões de pontos é um problema fundamental em reconhecimento de padrões. O objetivo é encontrar uma correspondência entre dois conjuntos de pontos, associados a características relevantes de objetos ou entidades, mapeando os pontos de um conjunto no outro. Este problema está associado a muitas aplicações, como por exemplo, reconhecimento de objetos baseado em modelos, imagens estéreo, registro de imagens, biometria, entre outros. Para encontrar um mapeamento, os objetos são codificados por representações abstratas, codificando as características relevantes consideradas na comparação entre pares de objetos. Neste trabalho, objetos são representados por grafos, codificando tanto as características `locais\' quanto as relações espaciais entre estas características. A comparação entre objetos é guiada por uma formulação de atribuição quadrática, que é um problema NP-difícil. Para estimar uma solução, duas técnicas de casamento entre grafos são propostas: uma baseada em grafos auxiliares, chamados de grafos deformados; e outra baseada em representações `esparsas\', campos aleatórios de Markov e propagação de crenças. Devido as suas respectivas limitações, as abordagens são adequadas para situações específicas, conforme mostrado neste documento. Resultados envolvendo as duas abordagens são ilustrados em quatro importantes aplicações: casamento de imagens de gel eletroforese 2D, segmentação interativa de imagens naturais, casamento de formas, e colorização assistida por computador. / Point set matching is a fundamental problem in pattern recognition. The goal is to match two sets of points, associated to relevant features of objects or entities, by finding a mapping, or a correspondence, from one set to another set of points. This issue arises in many applications, e.g. model-based object recognition, stereo matching, image registration, biometrics, among others. In order to find a mapping, the objects can be encoded by abstract representations, carrying relevant features which are taken into account to compare pairs of objects. In this work, graphs are adopted to represent the objects, encoding their `local\' features and the spatial relations between these features. The comparison of two given objects is guided by a quadratic assignment formulation, which is NP-hard. In order to estimate the optimal solution, two approximations techniques, via graph matching, are proposed: one is based on auxiliary graphs, called deformed graphs; the other is based on `sparse\' representations, Markov random fields and belief propagation. Due to their respective limitations, each approach is more suitable to each specific situation, as shown in this document. The quality of the two approaches is illustrated on four important applications: 2D electrophoresis gel matching, interactive natural image segmentation, shape matching, and computer-assisted colorization. 2D electrophoresis gel matching attributed relational graphs belief propagation campos aleatórios de Markov casamento de formas Casamento de padrões de pontos casamento entre grafos colorização assistida por computador. computer-assisted colorization. deformed graphs formulação de atribuição quadrática grafos deformados grafos relacionais com atributos graph matching interactive natural image segmentation Markov random fields pattern recognition point pattern matching Point set matching propagação de crenças quadratic assingment formulation reconhecimento de padrões shape matching
583	Imaging of fluorescence emission signals from healthy and infected leaf tissues / Imaging of fluorescence emission signals from healthy and infected leaf tissues BENEDIKTYOVÁ, Zuzana January 2009 (has links) Auto-fluorescence emission of plant tissues can be a powerful reporter on plant biochemistry and physiology since it originates in substances inherent to primary or secondary metabolism. Plant bodies contain a plethora of intrinsic fluorescent compounds emitting practically all wavelengths of visible light. Moreover, the spectrum of fluorescent reporter signals was recently extended by a variety of fluorescent proteins that provide a new tool to mark whole cells or sub-cellular structures, study protein localization and monitor gene expression and molecule interactions. The imaging of such fluorescence signals reveals a possibility to acquire the information from as many as millions of points simultaneously, in vivo and in a non-invasive way thereby preserving integrity of cells and whole organisms. Imaging is particularly suited to visualize heterogeneity such as a localized immune response to invading pathogens. It can be applied both at macro- as well as micro-scales in two and three dimensions. The recent advancement in microscopy, the multi-photon microscopy, has made possible to monitor fluorescence signals, such as NAD(P)H fluorescence from intact leaf interior, that have been hidden to single-photon techniques.
584	Duas abordagens para casamento de padrões de pontos usando relações espaciais e casamento entre grafos / Two approaches for point set matching using spatial relations for graph matching Alexandre Noma 07 July 2010 (has links) Casamento de padrões de pontos é um problema fundamental em reconhecimento de padrões. O objetivo é encontrar uma correspondência entre dois conjuntos de pontos, associados a características relevantes de objetos ou entidades, mapeando os pontos de um conjunto no outro. Este problema está associado a muitas aplicações, como por exemplo, reconhecimento de objetos baseado em modelos, imagens estéreo, registro de imagens, biometria, entre outros. Para encontrar um mapeamento, os objetos são codificados por representações abstratas, codificando as características relevantes consideradas na comparação entre pares de objetos. Neste trabalho, objetos são representados por grafos, codificando tanto as características `locais\' quanto as relações espaciais entre estas características. A comparação entre objetos é guiada por uma formulação de atribuição quadrática, que é um problema NP-difícil. Para estimar uma solução, duas técnicas de casamento entre grafos são propostas: uma baseada em grafos auxiliares, chamados de grafos deformados; e outra baseada em representações `esparsas\', campos aleatórios de Markov e propagação de crenças. Devido as suas respectivas limitações, as abordagens são adequadas para situações específicas, conforme mostrado neste documento. Resultados envolvendo as duas abordagens são ilustrados em quatro importantes aplicações: casamento de imagens de gel eletroforese 2D, segmentação interativa de imagens naturais, casamento de formas, e colorização assistida por computador. / Point set matching is a fundamental problem in pattern recognition. The goal is to match two sets of points, associated to relevant features of objects or entities, by finding a mapping, or a correspondence, from one set to another set of points. This issue arises in many applications, e.g. model-based object recognition, stereo matching, image registration, biometrics, among others. In order to find a mapping, the objects can be encoded by abstract representations, carrying relevant features which are taken into account to compare pairs of objects. In this work, graphs are adopted to represent the objects, encoding their `local\' features and the spatial relations between these features. The comparison of two given objects is guided by a quadratic assignment formulation, which is NP-hard. In order to estimate the optimal solution, two approximations techniques, via graph matching, are proposed: one is based on auxiliary graphs, called deformed graphs; the other is based on `sparse\' representations, Markov random fields and belief propagation. Due to their respective limitations, each approach is more suitable to each specific situation, as shown in this document. The quality of the two approaches is illustrated on four important applications: 2D electrophoresis gel matching, interactive natural image segmentation, shape matching, and computer-assisted colorization. campos aleatórios de Markov casamento de formas Casamento de padrões de pontos casamento entre grafos colorização assistida por computador. formulação de atribuição quadrática grafos deformados grafos relacionais com atributos propagação de crenças reconhecimento de padrões 2D electrophoresis gel matching attributed relational graphs belief propagation computer-assisted colorization. deformed graphs graph matching interactive natural image segmentation Markov random fields pattern recognition point pattern matching Point set matching quadratic assingment formulation shape matching
585	Automatické třídění fotografií podle obsahu / Automatic Photography Categorization Veľas, Martin January 2013 (has links) This thesis deals with content based automatic photo categorization. The aim of the work is to experiment with advanced techniques of image represenatation and to create a classifier which is able to process large image dataset with sufficient accuracy and computation speed. A traditional solution based on using visual codebooks is enhanced by computing color features, soft assignment of visual words to extracted feature vectors, usage of image segmentation in process of visual codebook creation and dividing picture into cells. These cells are processed separately. Linear SVM classifier with explicit data embeding is used for its efficiency. Finally, results of experiments with above mentioned techniques of the image categorization are discussed.
586	Parallel distributed-memory particle methods for acquisition-rate segmentation and uncertainty quantifications of large fluorescence microscopy images Afshar, Yaser 17 October 2016 (has links) Modern fluorescence microscopy modalities, such as light-sheet microscopy, are capable of acquiring large three-dimensional images at high data rate. This creates a bottleneck in computational processing and analysis of the acquired images, as the rate of acquisition outpaces the speed of processing. Moreover, images can be so large that they do not fit the main memory of a single computer. Another issue is the information loss during image acquisition due to limitations of the optical imaging systems. Analysis of the acquired images may, therefore, find multiple solutions (or no solution) due to imaging noise, blurring, and other uncertainties introduced during image acquisition. In this thesis, we address the computational processing time and memory issues by developing a distributed parallel algorithm for segmentation of large fluorescence-microscopy images. The method is based on the versatile Discrete Region Competition (Cardinale et al., 2012) algorithm, which has previously proven useful in microscopy image segmentation. The present distributed implementation decomposes the input image into smaller sub-images that are distributed across multiple computers. Using network communication, the computers orchestrate the collective solving of the global segmentation problem. This not only enables segmentation of large images (we test images of up to 10^10 pixels) but also accelerates segmentation to match the time scale of image acquisition. Such acquisition-rate image segmentation is a prerequisite for the smart microscopes of the future and enables online data inspection and interactive experiments. Second, we estimate the segmentation uncertainty on large images that do not fit the main memory of a single computer. We there- fore develop a distributed parallel algorithm for efficient Markov- chain Monte Carlo Discrete Region Sampling (Cardinale, 2013). The parallel algorithm provides a measure of segmentation uncertainty in a statistically unbiased way. It approximates the posterior probability densities over the high-dimensional space of segmentations around the previously found segmentation. / Moderne Fluoreszenzmikroskopie, wie zum Beispiel Lichtblattmikroskopie, erlauben die Aufnahme hochaufgelöster, 3-dimensionaler Bilder. Dies führt zu einen Engpass bei der Bearbeitung und Analyse der aufgenommenen Bilder, da die Aufnahmerate die Datenverarbeitungsrate übersteigt. Zusätzlich können diese Bilder so groß sein, dass sie die Speicherkapazität eines einzelnen Computers überschreiten. Hinzu kommt der aus Limitierungen des optischen Abbildungssystems resultierende Informationsverlust während der Bildaufnahme. Bildrauschen, Unschärfe und andere Messunsicherheiten können dazu führen, dass Analysealgorithmen möglicherweise mehrere oder keine Lösung für Bildverarbeitungsaufgaben finden. Im Rahmen der vorliegenden Arbeit entwickeln wir einen verteilten, parallelen Algorithmus für die Segmentierung von speicherintensiven Fluoreszenzmikroskopie-Bildern. Diese Methode basiert auf dem vielseitigen "Discrete Region Competition" Algorithmus (Cardinale et al., 2012), der sich bereits in anderen Anwendungen als nützlich für die Segmentierung von Mikroskopie-Bildern erwiesen hat. Das hier präsentierte Verfahren unterteilt das Eingangsbild in kleinere Unterbilder, welche auf die Speicher mehrerer Computer verteilt werden. Die Koordinierung des globalen Segmentierungsproblems wird durch die Benutzung von Netzwerkkommunikation erreicht. Dies erlaubt die Segmentierung von sehr großen Bildern, wobei wir die Anwendung des Algorithmus auf Bildern mit bis zu 10^10 Pixeln demonstrieren. Zusätzlich wird die Segmentierungsgeschwindigkeit erhöht und damit vergleichbar mit der Aufnahmerate des Mikroskops. Dies ist eine Grundvoraussetzung für die intelligenten Mikroskope der Zukunft, und es erlaubt die Online-Betrachtung der aufgenommenen Daten, sowie interaktive Experimente. Wir bestimmen die Unsicherheit des Segmentierungsalgorithmus bei der Anwendung auf Bilder, deren Größe den Speicher eines einzelnen Computers übersteigen. Dazu entwickeln wir einen verteilten, parallelen Algorithmus für effizientes Markov-chain Monte Carlo "Discrete Region Sampling" (Cardinale, 2013). Dieser Algorithmus quantifiziert die Segmentierungsunsicherheit statistisch erwartungstreu. Dazu wird die A-posteriori-Wahrscheinlichkeitsdichte über den hochdimensionalen Raum der Segmentierungen in der Umgebung der zuvor gefundenen Segmentierung approximiert. info:eu-repo/classification/ddc/004 ddc:004
587	Morfologické operace ve zpracování obrazu / Morphological Operations in Image Processing Kolouchová, Michaela January 2008 (has links) Mathematical morphology stems from set theory and it makes use of properties of point sets. The first point set is an origin image and the second one (usually smaller) is a structuring element. Morphological image transformations are image to image transformations based on a few elementary set operators. Fundamental morphologic operations are dilation, erosion and hit or miss. Next operations described in this work are opening and closing. Originally morphological operators were used for binary images only, later they were generalized for grey tone and color ones. This work describes the basic morphological image processing methods including their practical usage in image filtering and segmentation.
588	The Stixel World Pfeiffer, David 31 August 2012 (has links) Die Stixel-Welt ist eine neuartige und vielseitig einsetzbare Zwischenrepräsentation zur effizienten Beschreibung dreidimensionaler Szenen. Heutige stereobasierte Sehsysteme ermöglichen die Bestimmung einer Tiefenmessung für nahezu jeden Bildpunkt in Echtzeit. Das erlaubt zum einen die Anwendung neuer leistungsfähiger Algorithmen, doch gleichzeitig steigt die zu verarbeitende Datenmenge und der dadurch notwendig werdende Aufwand massiv an. Gerade im Hinblick auf die limitierte Rechenleistung jener Systeme, wie sie in der videobasierten Fahrerassistenz zum Einsatz kommen, ist dies eine große Herausforderung. Um dieses Problem zu lösen, bietet die Stixel-Welt eine generische Abstraktion der Rohdaten des Sensors. Jeder Stixel repräsentiert individuell einen Teil eines Objektes im Raum und segmentiert so die Umgebung in Freiraum und Objekte. Die Arbeit stellt die notwendigen Verfahren vor, um die Stixel-Welt mittels dynamischer Programmierung in einem einzigen globalen Optimierungsschritt in Echtzeit zu extrahieren. Dieser Prozess wird durch eine Vielzahl unterschiedlicher Annahmen über unsere von Menschenhand geschaffene Umgebung gestützt. Darauf aufbauend wird ein Kalmanfilter-basiertes Verfahren zur präzisen Bewegungsschätzung anderer Objekte vorgestellt. Die Arbeit stellt umfangreiche Bewertungen der zu erwartenden Leistungsfähigkeit aller vorgestellten Verfahren an. Dafür kommen sowohl vergleichende Ansätze als auch diverse Referenzsensoren, wie beispielsweise LIDAR, RADAR oder hochpräzise Inertialmesssysteme, zur Anwendung. Die Stixel-Welt ist eine extrem kompakte Abstraktion der dreidimensionalen Umgebung und bietet gleichzeitig einfachsten Zugriff auf alle essentiellen Informationen der Szene. Infolge dieser Arbeit war es möglich, die Effizienz vieler auf der Stixel-Welt aufbauender Algorithmen deutlich zu verbessern. / The Stixel World is a novel and versatile medium-level representation to efficiently bridge the gap between pixel-based processing and high-level vision. Modern stereo matching schemes allow to obtain a depth measurement for almost every pixel of an image in real-time, thus allowing the application of new and powerful algorithms. However, it also results in a large amount of measurement data that has to be processed and evaluated. With respect to vision-based driver assistance, these algorithms are executed on highly integrated low-power processing units that leave no room for algorithms with an intense calculation effort. At the same time, the growing number of independently executed vision tasks asks for new concepts to manage the resulting system complexity. These challenges are tackled by introducing a pre-processing step to extract all required information in advance. Each Stixel approximates a part of an object along with its distance and height. The Stixel World is computed in a single unified optimization scheme. Strong use is made of physically motivated a priori knowledge about our man-made three-dimensional environment. Relying on dynamic programming guarantees to extract the globally optimal segmentation for the entire scenario. Kalman filtering techniques are used to precisely estimate the motion state of all tracked objects. Particular emphasis is put on a thorough performance evaluation. Different comparative strategies are followed which include LIDAR, RADAR, and IMU reference sensors, manually created ground truth data, and real-world tests. Altogether, the Stixel World is ideally suited to serve as the basic building block for today''s increasingly complex vision systems. It is an extremely compact abstraction of the actual world giving access to the most essential information about the current scenario. Thanks to this thesis, the efficiency of subsequently executed vision algorithms and applications has improved significantly. Bildsegmentierung Freiraum Optischer Fluss Die Stixel-Welt Stixel Stereo vision Dichtes Stereo Zwischenrepräsentation Szenenrepräsentation Maximum a posteriori Schätzproblem Globale Optimierung Dynamische Programmierung Hindernisse Objektrepräsentation Bewegungsschätzung Objektverfolgung Bewegungzustandschätzung Kalmanfilter Auswertung LIDAR RADAR KLT-Tracker Robustheit Sensormodell evaluation Kalman filter Image segmentation The Stixel World Stixels Stereo vision Dense stereo Medium-level representation Scene representation Maximum a posteriori estimation Global optimization Dynamic programming Obstacles Freespace Object representation Motion estimation Object tracking LIDAR RADAR Optical flow KLT-tracker Robustness Sensor model 004 Informatik 28 Informatik, Datenverarbeitung ST 330 ddc:004

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