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Multi-camera Human Tracking on Realtime 3D Immersive Surveillance SystemHsieh, Meng-da 23 June 2010 (has links)
Conventional surveillance systems present video to a user from more than one camera on a single display. Such a display allows the user to observe different part of the scene, or to observe the same part of the scene from different viewpoints. Each video is usually labeled by a fixed textual annotation displayed under the video segment to identify the image. With the growing number of surveillance cameras set up and the expanse of surveillance area, the conventional split-screen display approach cannot provide intuitive correspondence between the images acquired and the areas under surveillance. Such a system has a number of inherent flaws¡GLower relativity of split videos¡BThe difficulty of tracking new activities¡BLow resolution of surveillance videos¡BThe difficulty of total surveillance¡FIn order to improve the above defects, the ¡§Immersive Surveillance for Total Situational Awareness¡¨ use computer graphic technique to construct 3D model of buildings on the 2D satellite-images, the users can construct the floor platform by defining the information of each floor or building and the position of each camera. This information is combined to construct 3D surveillance scene, and the images acquired by surveillance cameras are pasted into the constructed 3D model to provide intuitively visual presentation. The users could also walk through the scene by a fixed-frequency , self-defined business model to perform a virtual surveillance.
Multi-camera Human Tracking on Realtime 3D Immersive Surveillance System based on the ¡§Immersive Surveillance for Total Situational Awareness,¡¨ 1. Salient object detection¡GThe System converts videos to corresponding image sequences and analyze the videos provided by each camera. In order to filter out the foreground pixels, the background model of each image is calculated by pixel-stability-based background update algorithm. 2. Nighttime image fusion¡GUse the fuzzy enhancement method to enhance the dark area in nighttime image, and also maintain the saturation information. Then apply the Salient object detection Algorithm to extract salient objects of the dark area. The system divides fusion results into 3 parts: wall, ceiling, and floor, then pastes them as materials into corresponding parts of 3D scene. 3. Multi-camera human tracking¡GApply connected component labeling to filter out small area and save each block¡¦s infomation. Use RGB-weight percentage information in each block and 5-state status (Enter¡BLeave¡BMatch¡BOcclusion¡BFraction) to draw out the trajectory of each person in every camera¡¦s field of view on the 3D surveillance scene. Finally, fuse every camera together to complete the multi-camera realtime people tracking. Above all, we can track every human in our 3D immersive surveillance system without watching out each of thousand of camera views.
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Performance Evaluation of Object Proposal Generators for Salient Object DetectionJanuary 2019 (has links)
abstract: The detection and segmentation of objects appearing in a natural scene, often referred to as Object Detection, has gained a lot of interest in the computer vision field. Although most existing object detectors aim to detect all the objects in a given scene, it is important to evaluate whether these methods are capable of detecting the salient objects in the scene when constraining the number of proposals that can be generated due to constraints on timing or computations during execution. Salient objects are objects that tend to be more fixated by human subjects. The detection of salient objects is important in applications such as image collection browsing, image display on small devices, and perceptual compression.
This thesis proposes a novel evaluation framework that analyses the performance of popular existing object proposal generators in detecting the most salient objects. This work also shows that, by incorporating saliency constraints, the number of generated object proposals and thus the computational cost can be decreased significantly for a target true positive detection rate (TPR).
As part of the proposed framework, salient ground-truth masks are generated from the given original ground-truth masks for a given dataset. Given an object detection dataset, this work constructs salient object location ground-truth data, referred to here as salient ground-truth data for short, that only denotes the locations of salient objects. This is obtained by first computing a saliency map for the input image and then using it to assign a saliency score to each object in the image. Objects whose saliency scores are sufficiently high are referred to as salient objects. The detection rates are analyzed for existing object proposal generators with respect to the original ground-truth masks and the generated salient ground-truth masks.
As part of this work, a salient object detection database with salient ground-truth masks was constructed from the PASCAL VOC 2007 dataset. Not only does this dataset aid in analyzing the performance of existing object detectors for salient object detection, but it also helps in the development of new object detection methods and evaluating their performance in terms of successful detection of salient objects. / Dissertation/Thesis / Masters Thesis Electrical Engineering 2019
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Cluster-Based Salient Object Detection Using K-Means Merging and Keypoint Separation with Rectangular CentersBuck, Robert 01 May 2016 (has links)
The explosion of internet traffic, advent of social media sites such as Facebook and Twitter, and increased availability of digital cameras has saturated life with images and videos. Never before has it been so important to sift quickly through large amounts of digital information. Salient Object Detection (SOD) is a computer vision topic that finds methods to locate important objects in pictures. SOD has proven to be helpful in numerous applications such as image forgery detection and traffic sign recognition. In this thesis, I outline a novel SOD technique to automatically isolate important objects from the background in images.
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Visual saliency computation for image analysisZhang, Jianming 08 December 2016 (has links)
Visual saliency computation is about detecting and understanding salient regions and elements in a visual scene. Algorithms for visual saliency computation can give clues to where people will look in images, what objects are visually prominent in a scene, etc. Such algorithms could be useful in a wide range of applications in computer vision and graphics. In this thesis, we study the following visual saliency computation problems. 1) Eye Fixation Prediction. Eye fixation prediction aims to predict where people look in a visual scene. For this problem, we propose a Boolean Map Saliency (BMS) model which leverages the global surroundedness cue using a Boolean map representation. We draw a theoretic connection between BMS and the Minimum Barrier Distance (MBD) transform to provide insight into our algorithm. Experiment results show that BMS compares favorably with state-of-the-art methods on seven benchmark datasets. 2) Salient Region Detection. Salient region detection entails computing a saliency map that highlights the regions of dominant objects in a scene. We propose a salient region detection method based on the Minimum Barrier Distance (MBD) transform. We present a fast approximate MBD transform algorithm with an error bound analysis. Powered by this fast MBD transform algorithm, our method can run at about 80 FPS and achieve state-of-the-art performance on four benchmark datasets. 3) Salient Object Detection. Salient object detection targets at localizing each salient object instance in an image. We propose a method using a Convolutional Neural Network (CNN) model for proposal generation and a novel subset optimization formulation for bounding box filtering. In experiments, our subset optimization formulation consistently outperforms heuristic bounding box filtering baselines, such as Non-maximum Suppression, and our method substantially outperforms previous methods on three challenging datasets. 4) Salient Object Subitizing. We propose a new visual saliency computation task, called Salient Object Subitizing, which is to predict the existence and the number of salient objects in an image using holistic cues. To this end, we present an image dataset of about 14K everyday images which are annotated using an online crowdsourcing marketplace. We show that an end-to-end trained CNN subitizing model can achieve promising performance without requiring any localization process. A method is proposed to further improve the training of the CNN subitizing model by leveraging synthetic images. 5) Top-down Saliency Detection. Unlike the aforementioned tasks, top-down saliency detection entails generating task-specific saliency maps. We propose a weakly supervised top-down saliency detection approach by modeling the top-down attention of a CNN image classifier. We propose Excitation Backprop and the concept of contrastive attention to generate highly discriminative top-down saliency maps. Our top-down saliency detection method achieves superior performance in weakly supervised localization tasks on challenging datasets. The usefulness of our method is further validated in the text-to-region association task, where our method provides state-of-the-art performance using only weakly labeled web images for training.
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The research of background removal applied to fashion data : The necessity analysis of background removal for fashion data / Forskningen av bakgrundsborttagning tillämpas på modedata : Nödvändighetsanalysen av bakgrundsborttagning för modedataLiang, Junhui January 2022 (has links)
Fashion understanding is a hot topic in computer vision, with many applications having a great business value in the market. It remains a difficult challenge for computer vision due to the immense diversity of garments and a wide range of scenes and backgrounds. In this work, we try to remove the background of fashion images to boost data quality and ultimately increase model performance. Thanks to the fashion image consisting of evident persons in full garments visible, we can utilize Salient Object Detection (SOD) to achieve the background removal of fashion data to our expectations. The fashion image with removing the background is claimed as the “rembg” image, contrasting with the original one in the fashion dataset. We conduct comparative experiments between these two types of images on multiple aspects of model training, including model architectures, model initialization, compatibility with other training tricks and data augmentations, and target task types. Our experiments suggested that background removal can significantly work for fashion data in simple and shallow networks that are not susceptible to overfitting. It can improve model accuracy by up to 5% in the classification of FashionStyle14 when training models from scratch. However, background removal does not perform well in the deep network due to its incompatibility with other regularization techniques like batch normalization, pre-trained initialization, and data augmentations introducing randomness. The loss of background pixels invalidates many existing training tricks in the model training, adding the risk of overfitting for deep models. / Modeförståelse är ett hett ämne inom datorseende, med många applikationer som har ett stort affärsvärde på marknaden. Det är fortfarande en svår utmaning för datorseende på grund av den enorma mångfalden av plagg och ett brett utbud av scener och bakgrunder. I det här arbetet försöker vi ta bort bakgrunden från modebilder för att öka datakvaliteten och i slutändan öka modellens prestanda. Tack vare modebilden som består av synliga personer i helt synliga plagg, kan vi använda framträdande objektivdetektion för att uppnå bakgrundsborttagning av modedata enligt våra förväntningar. Modebilden med att ta bort bakgrunden hävdas vara “rembg”-bilden, i kontrast till den ursprungliga i modedatasetet. Vi genomför jämförande experiment mellan dessa två typer av bilder på flera aspekter av modellträning, inklusive modellarkitekturer, modellinitiering , kompatibilitet med andra träningsknep och dataökningar och måluppgiftstyper. Våra experiment antydde att bakgrundsborttagning avsevärt kan fungera för modedata i enkla och ytliga nätverk som inte är mottagliga för överanpassning. Det kan förbättra modellens noggrannhet med upp till 5 % i klassificeringen av FashionStyle14 när man tränar modeller från grunden. Bakgrundsborttagning fungerar dock inte bra i det djupa nätverket på grund av dess inkompatibilitet med andra regulariseringstekniker som batchnormalisering, förtränad initialisering och dataförstärkningar som introducerar slumpmässighet. Förlusten av bakgrundspixlar ogiltigförklarar många befintliga träningsknep i modellträningen, lägg till risken för övermontering för djupa modeller.
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Salient object detection and segmentation in videos / Détection d'objets saillants et segmentation dans des vidéosWang, Qiong 09 May 2019 (has links)
Cette thèse est centrée sur le problème de la détection d'objets saillants et de leur segmentation dans une vidéo en vue de détecter les objets les plus attractifs ou d'affecter des identités cohérentes d'objets à chaque pixel d'une séquence vidéo. Concernant la détection d'objets saillants dans vidéo, outre une revue des techniques existantes, une nouvelle approche et l'extension d'un modèle sont proposées; de plus une approche est proposée pour la segmentation d'instances d'objets vidéo. Pour la détection d'objets saillants dans une vidéo, nous proposons : (1) une approche traditionnelle pour détecter l'objet saillant dans sa totalité à l'aide de la notion de "bordures virtuelles". Un filtre guidé est appliqué sur la sortie temporelle pour intégrer les informations de bord spatial en vue d'une meilleure détection des bords de l'objet saillants. Une carte globale de saillance spatio-temporelle est obtenue en combinant la carte de saillance spatiale et la carte de saillance temporelle en fonction de l'entropie. (2) Une revue des développements récents des méthodes basées sur l'apprentissage profond est réalisée. Elle inclut les classifications des méthodes de l'état de l'art et de leurs architectures, ainsi qu'une étude expérimentale comparative de leurs performances. (3) Une extension d'un modèle de l'approche traditionnelle proposée en intégrant un procédé de détection d'objet saillant d'image basé sur l'apprentissage profond a permis d'améliorer encore les performances. Pour la segmentation des instances d'objets dans une vidéo, nous proposons une approche d'apprentissage profond dans laquelle le calcul de la confiance de déformation détermine d'abord la confiance de la carte masquée, puis une sélection sémantique est optimisée pour améliorer la carte déformée, où l'objet est réidentifié à l'aide de l'étiquettes sémantique de l'objet cible. Les approches proposées ont été évaluées sur des jeux de données complexes et de grande taille disponibles publiquement et les résultats expérimentaux montrent que les approches proposées sont plus performantes que les méthodes de l'état de l'art. / This thesis focuses on the problem of video salient object detection and video object instance segmentation which aim to detect the most attracting objects or assign consistent object IDs to each pixel in a video sequence. One approach, one overview and one extended model are proposed for video salient object detection, and one approach is proposed for video object instance segmentation. For video salient object detection, we propose: (1) one traditional approach to detect the whole salient object via the adjunction of virtual borders. A guided filter is applied on the temporal output to integrate the spatial edge information for a better detection of the salient object edges. A global spatio-temporal saliency map is obtained by combining the spatial saliency map and the temporal saliency map together according to the entropy. (2) An overview of recent developments for deep-learning based methods is provided. It includes the classifications of the state-of-the-art methods and their frameworks, and the experimental comparison of the performances of the state-of-the-art methods. (3) One extended model further improves the performance of the proposed traditional approach by integrating a deep-learning based image salient object detection method For video object instance segmentation, we propose a deep-learning approach in which the warping confidence computation firstly judges the confidence of the mask warped map, then a semantic selection is introduced to optimize the warped map, where the object is re-identified using the semantics labels of the target object. The proposed approaches have been assessed on the published large-scale and challenging datasets. The experimental results show that the proposed approaches outperform the state-of-the-art methods.
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Segmentation and structuring of video documents for indexing applicationsTapu, Ruxandra Georgina 07 December 2012 (has links) (PDF)
Recent advances in telecommunications, collaborated with the development of image and video processing and acquisition devices has lead to a spectacular growth of the amount of the visual content data stored, transmitted and exchanged over Internet. Within this context, elaborating efficient tools to access, browse and retrieve video content has become a crucial challenge. In Chapter 2 we introduce and validate a novel shot boundary detection algorithm able to identify abrupt and gradual transitions. The technique is based on an enhanced graph partition model, combined with a multi-resolution analysis and a non-linear filtering operation. The global computational complexity is reduced by implementing a two-pass approach strategy. In Chapter 3 the video abstraction problem is considered. In our case, we have developed a keyframe representation system that extracts a variable number of images from each detected shot, depending on the visual content variation. The Chapter 4 deals with the issue of high level semantic segmentation into scenes. Here, a novel scene/DVD chapter detection method is introduced and validated. Spatio-temporal coherent shots are clustered into the same scene based on a set of temporal constraints, adaptive thresholds and neutralized shots. Chapter 5 considers the issue of object detection and segmentation. Here we introduce a novel spatio-temporal visual saliency system based on: region contrast, interest points correspondence, geometric transforms, motion classes' estimation and regions temporal consistency. The proposed technique is extended on 3D videos by representing the stereoscopic perception as a 2D video and its associated depth
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Estimation de cartes d'énergie du bruit apériodique de la marche humaine avec une caméra de profondeur pour la détection de pathologies et modèles légers de détection d'objets saillants basés sur l'opposition de couleursNdayikengurukiye, Didier 06 1900 (has links)
Cette thèse a pour objectif l’étude de trois problèmes : l’estimation de cartes de saillance de l’énergie du bruit apériodique de la marche humaine par la perception de profondeur pour la détection de pathologies, les modèles de détection d’objets saillants en général et les modèles légers en particulier par l’opposition de couleurs.
Comme première contribution, nous proposons un système basé sur une caméra de profondeur et un tapis roulant, qui analyse les parties du corps du patient ayant un mouvement irrégulier, en termes de périodicité, pendant la marche. Nous supposons que la marche d'un sujet sain présente n'importe où dans son corps, pendant les cycles de marche, un signal de profondeur avec un motif périodique sans bruit. La présence de bruit et son importance peuvent être utilisées pour signaler la présence et l'étendue de pathologies chez le sujet. Notre système estime, à partir de chaque séquence vidéo, une carte couleur de saillance montrant les zones de fortes irrégularités de marche, en termes de périodicité, appelées énergie de bruit apériodique, de chaque sujet. Notre système permet aussi de détecter automatiquement les cartes des individus sains et ceux malades.
Nous présentons ensuite deux approches pour la détection d’objets saillants. Bien qu’ayant fait l’objet de plusieurs travaux de recherche, la détection d'objets saillants reste un défi. La plupart des modèles traitent la couleur et la texture séparément et les considèrent donc implicitement comme des caractéristiques indépendantes, à tort.
Comme deuxième contribution, nous proposons une nouvelle stratégie, à travers un modèle simple, presque sans paramètres internes, générant une carte de saillance robuste pour une image naturelle. Cette stratégie consiste à intégrer la couleur dans les motifs de texture pour caractériser une micro-texture colorée, ceci grâce au motif ternaire local (LTP) (descripteur de texture simple mais puissant) appliqué aux paires de couleurs. La dissemblance entre chaque paire de micro-textures colorées est calculée en tenant compte de la non-linéarité des micro-textures colorées et en préservant leurs distances, donnant une carte de saillance intermédiaire pour chaque espace de couleur. La carte de saillance finale est leur combinaison pour avoir des cartes robustes.
Le développement des réseaux de neurones profonds a récemment permis des performances élevées. Cependant, il reste un défi de développer des modèles de même performance pour des appareils avec des ressources limitées.
Comme troisième contribution, nous proposons une nouvelle approche pour un modèle léger de réseau neuronal profond de détection d'objets saillants, inspiré par les processus de double opposition du cortex visuel primaire, qui lient inextricablement la couleur et la forme dans la perception humaine des couleurs. Notre modèle proposé, CoSOV1net, est entraîné à partir de zéro, sans utiliser de ``backbones'' de classification d'images ou d'autres tâches. Les expériences sur les ensembles de données les plus utilisés et les plus complexes pour la détection d'objets saillants montrent que CoSOV1Net atteint des performances compétitives avec des modèles de l’état-de-l’art, tout en étant un modèle léger de détection d'objets saillants et pouvant être adapté aux environnements mobiles et aux appareils à ressources limitées. / The purpose of this thesis is to study three problems: the estimation of saliency maps of the aperiodic noise energy of human gait using depth perception for pathology detection, and to study models for salient objects detection in general and lightweight models in particular by color opposition.
As our first contribution, we propose a system based on a depth camera and a treadmill, which analyzes the parts of the patient's body with irregular movement, in terms of periodicity, during walking. We assume that a healthy subject gait presents anywhere in his (her) body, during gait cycles, a depth signal with a periodic pattern without noise. The presence of noise and its importance can be used to point out presence and extent of the subject’s pathologies. Our system estimates, from each video sequence, a saliency map showing the areas of strong gait irregularities, in terms of periodicity, called aperiodic noise energy, of each subject. Our system also makes it possible to automatically detect the saliency map of healthy and sick subjects.
We then present two approaches for salient objects detection. Although having been the subject of many research works, salient objects detection remains a challenge. Most models treat color and texture separately and therefore implicitly consider them as independent feature, erroneously.
As a second contribution, we propose a new strategy through a simple model, almost without internal parameters, generating a robust saliency map for a natural image. This strategy consists in integrating color in texture patterns to characterize a colored micro-texture thanks to the local ternary pattern (LTP) (simple but powerful texture descriptor) applied to the color pairs. The dissimilarity between each colored micro-textures pair is computed considering non-linearity from colored micro-textures and preserving their distances. This gives an intermediate saliency map for each color space. The final saliency map is their combination to have robust saliency map.
The development of deep neural networks has recently enabled high performance. However, it remains a challenge to develop models of the same performance for devices with limited resources.
As a third contribution, we propose a new approach for a lightweight salient objects detection deep neural network model, inspired by the double opponent process in the primary visual cortex, which inextricably links color and shape in human color perception. Our proposed model, namely CoSOV1net, is trained from scratch, without using any image classification backbones or other tasks. Experiments on the most used and challenging datasets for salient objects detection show that CoSOV1Net achieves competitive performance with state-of-the-art models, yet it is a lightweight detection model and it is a salient objects detection that can be adapted to mobile environments and resource-constrained devices.
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Visual Flow Analysis and Saliency PredictionSrinivas, Kruthiventi S S January 2016 (has links) (PDF)
Nowadays, we have millions of cameras in public places such as traffic junctions, railway stations etc., and capturing video data round the clock. This humongous data has resulted in an increased need for automation of visual surveillance. Analysis of crowd and traffic flows is an important step towards achieving this goal. In this work, we present our algorithms for identifying and segmenting dominant ows in surveillance scenarios. In the second part, we present our work aiming at predicting the visual saliency. The ability of humans to discriminate and selectively pay attention to few regions in the scene over the others is a key attentional mechanism. Here, we present our algorithms for predicting human eye fixations and segmenting salient objects in the scene.
(i) Flow Analysis in Surveillance Videos: We propose algorithms for segmenting flows of static and dynamic nature in surveillance videos in an unsupervised manner. In static flows scenarios, we assume the motion patterns to be consistent over the entire duration of video and analyze them in the compressed domain using H.264 motion vectors. Our approach is based on modeling the motion vector field as a Conditional Random Field (CRF) and obtaining oriented motion segments which are merged to obtain the final flow segments. This approach in compressed domain is shown to be both accurate and computationally efficient. In the case of dynamic flow videos (e.g. flows at a traffic junction), we propose a method for segmenting the individual object flows over long durations. This long-term flow segmentation is achieved in the framework of CRF using local color and motion features. We propose a Dynamic Time Warping (DTW) based distance measure between flow segments for clustering them and generate representative dominant ow models. Using these dominant flow models, we perform path prediction for the vehicles entering the camera's field-of-view and detect anomalous motions.
(ii) Visual Saliency Prediction using Deep Convolutional Neural Networks: We propose a deep fully convolutional neural network (CNN) - DeepFix, for accurately predicting eye fixations in the form of saliency maps. Unlike classical works which characterize the saliency map using various hand-crafted features, our model automatically learns features in a hierarchical fashion and predicts saliency map in an end-to-end manner. DeepFix is designed to capture visual semantics at multiple scales while taking global context into account. Generally, fully convolutional nets are spatially invariant which prevents them from modeling location dependent patterns (e.g. centre-bias). Our network overcomes this limitation by incorporating a novel Location Biased Convolutional layer. We experimentally show that our network outperforms other recent approaches by a significant margin.
In general, human eye fixations correlate with locations of salient objects in the scene. However, only a handful of approaches have attempted to simultaneously address these related aspects of eye fixations and object saliency. In our work, we also propose a deep convolutional network capable of simultaneously predicting eye fixations and segmenting salient objects in a unified framework. We design the initial network layers, shared between both the tasks, such that they capture the global contextual aspects of saliency, while the deeper layers of the network address task specific aspects. Our network shows a significant improvement over the current state-of-the-art for both eye fixation prediction and salient object segmentation across a number of challenging datasets.
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Segmentation and structuring of video documents for indexing applications / Segmentation et structuration de documents video pour l'indexationTapu, Ruxandra Georgina 07 December 2012 (has links)
Les progrès récents en matière de télécommunications, collaboré avec le développement des dispositifs d'acquisition d’images et de vidéos a conduit à une croissance spectaculaire de la quantité des données vidéo stockées, transmises et échangées sur l’Internet. Dans ce contexte, l'élaboration d'outils efficaces pour accéder aux éléments d’information présents dans le contenu vidéo est devenue un enjeu crucial. Dans le Chapitre 2 nous introduisons un nouvel algorithme pour la détection de changement de plans vidéo. La technique est basée sur la partition des graphes combinée avec une analyse multi-résolution et d'une opération de filtrage non-linéaire. La complexité globale de calcul est réduite par l’application d'une stratégie deux passes. Dans le Chapitre 3 le problème d’abstraction automatique est considéré. Dans notre cas, nous avons adopté un système de représentation image-clés qui extrait un nombre variable d'images de chaque plan vidéo détecté, en fonction de la variation du contenu visuel. Le Chapitre 4 traite la segmentation de haut niveau sémantique. En exploitant l'observation que les plans vidéo appartenant à la même scène ont les mêmes caractéristiques visuelles, nous introduisons un nouvel algorithme de regroupement avec contraintes temporelles, qui utilise le seuillage adaptatif et les plans vidéo neutralisés. Dans le Chapitre 5 nous abordons le thème de détection d’objets vidéo saillants. Dans ce contexte, nous avons introduit une nouvelle approche pour modéliser l'attention spatio-temporelle utilisant : la correspondance entre les points d'intérêt, les transformations géométriques et l’estimation des classes de mouvement / Recent advances in telecommunications, collaborated with the development of image and video processing and acquisition devices has lead to a spectacular growth of the amount of the visual content data stored, transmitted and exchanged over Internet. Within this context, elaborating efficient tools to access, browse and retrieve video content has become a crucial challenge. In Chapter 2 we introduce and validate a novel shot boundary detection algorithm able to identify abrupt and gradual transitions. The technique is based on an enhanced graph partition model, combined with a multi-resolution analysis and a non-linear filtering operation. The global computational complexity is reduced by implementing a two-pass approach strategy. In Chapter 3 the video abstraction problem is considered. In our case, we have developed a keyframe representation system that extracts a variable number of images from each detected shot, depending on the visual content variation. The Chapter 4 deals with the issue of high level semantic segmentation into scenes. Here, a novel scene/DVD chapter detection method is introduced and validated. Spatio-temporal coherent shots are clustered into the same scene based on a set of temporal constraints, adaptive thresholds and neutralized shots. Chapter 5 considers the issue of object detection and segmentation. Here we introduce a novel spatio-temporal visual saliency system based on: region contrast, interest points correspondence, geometric transforms, motion classes’ estimation and regions temporal consistency. The proposed technique is extended on 3D videos by representing the stereoscopic perception as a 2D video and its associated depth
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