leave a trace - A People Tracking System Meets Anomaly Detection

Video surveillance always had a negative connotation, among others because of the loss of privacy and because it may not automatically increase public safety. If it was able to detect atypical (i.e. dangerous) situations in real time, autonomously and anonymously, this could change. A prerequisite for this is a reliable automatic detection of possibly dangerous situations from video data. This is done classically by object extraction and tracking. From the derived trajectories, we then want to determine dangerous situations by detecting atypical trajectories. However, due to ethical considerations it is better to develop such a system on data without people being threatened or even harmed, plus with having them know that there is such a tracking system installed. Another important point is that these situations do not occur very often in real, public CCTV areas and may be captured properly even less. In the artistic project leave a trace the tracked objects, people in an atrium of a institutional building, become actor and thus part of the installation. Visualisation in real-time allows interaction by these actors, which in turn creates many atypical interaction situations on which we can develop our situation detection. The data set has evolved over three years and hence, is huge. In this article we describe the tracking system and several approaches for the detection of atypical trajectories

Design of power device sizing and integration for solar-powered aircraft application

The power device constitutes the PV cell, rechargeable battery, and maximum power point tracker. Solar aircraft lack proper power device sizing to provide adequate energy to sustain low and high altitude and long endurance flight. This paper conducts the power device sizing and integration for solar-powered aircraft applications (Unmanned Aerial Vehicle). The solar radiation model, the aerodynamic model, the energy and mass balance model, and the adopted aircraft configuration were used to determine the power device sizing, integration, and application. The input variables were aircraft mass 3 kg, wingspan 3.2 m, chord 0.3 m, aspect ratio 11.25, solar radiation 825 W/m2 , lift coefficient 0.913, total drag coefficient 0.047, day time 12 hour, night time 12 hours, respectively. The input variables were incorporated into the MS Excel program to determine the output variables. The output variables are; the power required 10.92 W, the total electrical power 19.47 W, the total electrical energy 465.5 Wh, the daily solar energy 578.33 Wh, the solar cell area 0.62 m, the number of PV cell 32, and the number of the Rechargeable battery 74 respectively. The power device was developed with the PV cell Maxeon Gen III for high efficiency, the rechargeable battery sulfur-lithium battery for high energy density, and the Maximum power point tracker neural network algorithm for smart and efficient response. The PD sizing was validated with three existing designs. The validation results show that 20% reduction of the required number of PV cells and RB and a 30% increase in flight durations

Cognitive visual tracking and camera control

Cognitive visual tracking is the process of observing and understanding the behaviour of a moving person. This paper presents an efficient solution to extract, in real-time, high-level information from an observed scene, and generate the most appropriate commands for a set of pan-tilt-zoom (PTZ) cameras in a surveillance scenario. Such a high-level feedback control loop, which is the main novelty of our work, will serve to reduce uncertainties in the observed scene and to maximize the amount of information extracted from it. It is implemented with a distributed camera system using SQL tables as virtual communication channels, and Situation Graph Trees for knowledge representation, inference and high-level camera control. A set of experiments in a surveillance scenario show the effectiveness of our approach and its potential for real applications of cognitive vision

AFFECT-PRESERVING VISUAL PRIVACY PROTECTION

The prevalence of wireless networks and the convenience of mobile cameras enable many new video applications other than security and entertainment. From behavioral diagnosis to wellness monitoring, cameras are increasing used for observations in various educational and medical settings. Videos collected for such applications are considered protected health information under privacy laws in many countries. Visual privacy protection techniques, such as blurring or object removal, can be used to mitigate privacy concern, but they also obliterate important visual cues of affect and social behaviors that are crucial for the target applications. In this dissertation, we propose to balance the privacy protection and the utility of the data by preserving the privacy-insensitive information, such as pose and expression, which is useful in many applications involving visual understanding. The Intellectual Merits of the dissertation include a novel framework for visual privacy protection by manipulating facial image and body shape of individuals, which: (1) is able to conceal the identity of individuals; (2) provide a way to preserve the utility of the data, such as expression and pose information; (3) balance the utility of the data and capacity of the privacy protection. The Broader Impacts of the dissertation focus on the significance of privacy protection on visual data, and the inadequacy of current privacy enhancing technologies in preserving affect and behavioral attributes of the visual content, which are highly useful for behavior observation in educational and medical settings. This work in this dissertation represents one of the first attempts in achieving both goals simultaneously

Gait recognition based on shape and motion analysis of silhouette contours

This paper presents a three-phase gait recognition method that analyses the spatio-temporal shape and dynamic motion (STS-DM) characteristics of a human subject’s silhouettes to identify the subject in the presence of most of the challenging factors that affect existing gait recognition systems. In phase 1, phase-weighted magnitude spectra of the Fourier descriptor of the silhouette contours at ten phases of a gait period are used to analyse the spatio-temporal changes of the subject’s shape. A component-based Fourier descriptor based on anatomical studies of human body is used to achieve robustness against shape variations caused by all common types of small carrying conditions with folded hands, at the subject’s back and in upright position. In phase 2, a full-body shape and motion analysis is performed by fitting ellipses to contour segments of ten phases of a gait period and using a histogram matching with Bhattacharyya distance of parameters of the ellipses as dissimilarity scores. In phase 3, dynamic time warping is used to analyse the angular rotation pattern of the subject’s leading knee with a consideration of arm-swing over a gait period to achieve identification that is invariant to walking speed, limited clothing variations, hair style changes and shadows under feet. The match scores generated in the three phases are fused using weight-based score-level fusion for robust identification in the presence of missing and distorted frames, and occlusion in the scene. Experimental analyses on various publicly available data sets show that STS-DM outperforms several state-of-the-art gait recognition methods

Video Registration for Multimodal Surveillance Systems

RÉSUMÉ Au cours de la dernière décennie, la conception et le déploiement de systèmes de surveillance par caméras thermiques et visibles pour l'analyse des activités humaines a retenu l'attention de la communauté de la vision par ordinateur. Les applications de l'imagerie thermique-visible pour l'analyse des activités humaines couvrent différents domaines, notamment la médecine, la sécurité à bord d'un véhicule et la sécurité des personnes. La motivation derrière un tel système est l'amélioration de la qualité des données dans le but ultime d'améliorer la performance du système de surveillance. Une difficulté fondamentale associée à un système d'imagerie thermique-visible est la mise en registre précise de caractéristiques et d'informations correspondantes à partir d'images avec des différences significatives dans les propriétés des signaux. Dans un cas, on capte des informations de couleur (lumière réfléchie) et dans l'autre cas, on capte la signature thermique (énergie émise). Ce problème est appelé mise en registre d'images et de séquences vidéo. La vidéosurveillance est l'un des domaines d'application le plus étendu de l'imagerie multi-spectrale. La vidéosurveillance automatique dans un environnement réel, que ce soit à l'intérieur ou à l'extérieur, est difficile en raison d'un nombre élevé de facteurs environnementaux tels que les variations d'éclairage, le vent, le brouillard, et les ombres. L'utilisation conjointe de différentes modalités permet d'augmenter la fiabilité des données d'entrée, et de révéler certaines informations sur la scène qui ne sont pas perceptibles par un système d'imagerie unimodal. Les premiers systèmes multimodaux de vidéosurveillance ont été conçus principalement pour des applications militaires. Mais de nos jours, en raison de la réduction du prix des caméras thermiques, ce sujet de recherche s'étend à des applications civiles ayant une variété d'objectifs. Les approches pour la mise en registre d'images pour un système multimodal de vidéosurveillance automatique sont divisées en deux catégories fondées sur la dimension de la scène: les approches qui sont appropriées pour des grandes scènes où les objets sont lointains, et les approches qui conviennent à de petites scènes où les objets sont près des caméras. Dans la littérature, ce sujet de recherche n'est pas bien documenté, en particulier pour le cas de petites scènes avec objets proches. Notre recherche est axée sur la conception de nouvelles solutions de mise en registre pour les deux catégories de scènes dans lesquels il y a plusieurs humains. Les solutions proposées sont incluses dans les quatre articles qui composent cette thèse. Nos méthodes de mise en registre sont des prétraitements pour d'autres tâches d'analyse vidéo telles que le suivi, la localisation de l'humain, l'analyse de comportements, et la catégorisation d'objets. Pour les scènes avec des objets lointains, nous proposons un système itératif qui fait de façon simultanée la mise en registre thermique-visible, la fusion des données et le suivi des personnes. Notre méthode de mise en registre est basée sur une mise en correspondance de trajectoires (en utilisant RANSAC) à partir desquelles on estime une matrice de transformation affine pour transformer globalement des objets d'avant-plan d'une image sur l'autre image. Notre système proposé de vidéosurveillance multimodale est basé sur un nouveau mécanisme de rétroaction entre la mise en registre et le module de suivi, ce qui augmente les performances des deux modules de manière itérative au fil du temps. Nos méthodes sont conçues pour des applications en ligne et aucune calibration des caméras ou de configurations particulières ne sont requises. Pour les petites scènes avec des objets proches, nous introduisons le descripteur Local Self-Similarity (LSS), comme une mesure de similarité viable pour mettre en correspondance les régions du corps humain dans des images thermiques et visibles. Nous avons également démontré théoriquement et quantitativement que LSS, comme mesure de similarité thermique-visible, est plus robuste aux différences entre les textures des régions correspondantes que l'information mutuelle (IM), qui est la mesure de similarité classique pour les applications multimodales. D'autres descripteurs viables, y compris Histogram Of Gradient (HOG), Scale Invariant Feature Transform (SIFT), et Binary Robust Independent Elementary Feature (BRIEF) sont également surclassés par LSS. En outre, nous proposons une approche de mise en registre utilisant LSS et un mécanisme de votes pour obtenir une carte de disparité stéréo dense pour chaque région d'avant-plan dans l'image. La carte de disparité qui en résulte peut alors être utilisée pour aligner l'image de référence sur la seconde image. Nous démontrons que notre méthode surpasse les méthodes dans l'état de l'art, notamment les méthodes basées sur l'information mutuelle. Nos expériences ont été réalisées en utilisant des scénarios réalistes de surveillance d'humains dans une scène de petite taille. En raison des lacunes des approches locales de correspondance stéréo pour l'estimation de disparités précises dans des régions de discontinuité de profondeur, nous proposons une méthode de correspondance stéréo basée sur une approche d'optimisation globale. Nous introduisons un modèle stéréo approprié pour la mise en registre d'images thermique-visible en utilisant une méthode de minimisation de l'énergie en conjonction avec la méthode Belief Propagation (BP) comme méthode pour optimiser l'affectation des disparités par une fonction d'énergie. Dans cette méthode, nous avons intégré les informations de couleur et de mouvement comme contraintes douces pour améliorer la précision d'affectation des disparités dans les cas de discontinuités de profondeur. Bien que les approches de correspondance globale soient plus gourmandes au niveau des ressources de calculs par rapport aux approches de correspondance locale basée sur la stratégie Winner Take All (WTA), l'algorithme efficace BP et la programmation parallèle (OpenMP) en C++ que nous avons utilisés dans notre implémentation, permettent d'accélérer le temps de traitement de manière significative et de rendre nos méthodes viables pour les applications de vidéosurveillance. Nos méthodes sont programmées en C++ et utilisent la bibliothèque OpenCV. Nos méthodes sont conçues pour être facilement intégrées comme prétraitement pour toute application d'analyse vidéo. En d'autres termes, les données d'entrée de nos méthodes pourraient être un flux vidéo en ligne, et pour une analyse plus approfondie, un nouveau module pourrait être ajouté en aval à notre schéma algorithmique. Cette analyse plus approfondie pourrait être le suivi d'objets, la localisation d'êtres humains, et l'analyse de trajectoires pour les applications de surveillance multimodales de grandes scène. Aussi, Il pourrait être l'analyse de comportements, la catégorisation d'objets, et le suivi pour les applications sur des scènes de tailles réduites.---------ABSTRACT Recently, the design and deployment of thermal-visible surveillance systems for human analysis attracted a lot of attention in the computer vision community. Thermal-visible imagery applications for human analysis span different domains including medical, in-vehicle safety system, and surveillance. The motivation of applying such a system is improving the quality of data with the ultimate goal of improving the performance of targeted surveillance system. A fundamental issue associated with a thermal-visible imaging system is the accurate registration of corresponding features and information from images with high differences in imaging characteristics, where one reflects the color information (reflected energy) and another one reflects thermal signature (emitted energy). This problem is named Image/video registration. Video surveillance is one of the most extensive application domains of multispectral imaging. Automatic video surveillance in a realistic environment, either indoor or outdoor, is difficult due to the unlimited number of environmental factors such as illumination variations, wind, fog, and shadows. In a multimodal surveillance system, the joint use of different modalities increases the reliability of input data and reveals some information of the scene that might be missed using a unimodal imaging system. The early multimodal video surveillance systems were designed mainly for military applications. But nowadays, because of the reduction in the price of thermal cameras, this subject of research is extending to civilian applications and has attracted more interests for a variety of the human monitoring objectives. Image registration approaches for an automatic multimodal video surveillance system are divided into two general approaches based on the range of captured scene: the approaches that are appropriate for long-range scenes, and the approaches that are suitable for close-range scenes. In the literature, this subject of research is not well documented, especially for close-range surveillance application domains. Our research is focused on novel image registration solutions for both close-range and long-range scenes featuring multiple humans. The proposed solutions are presented in the four articles included in this thesis. Our registration methods are applicable for further video analysis such as tracking, human localization, behavioral pattern analysis, and object categorization. For far-range video surveillance, we propose an iterative system that consists of simultaneous thermal-visible video registration, sensor fusion, and people tracking. Our video registration is based on a RANSAC object trajectory matching, which estimates an affine transformation matrix to globally transform foreground objects of one image on another one. Our proposed multimodal surveillance system is based on a novel feedback scheme between registration and tracking modules that augments the performance of both modules iteratively over time. Our methods are designed for online applications and no camera calibration or special setup is required. For close-range video surveillance applications, we introduce Local Self-Similarity (LSS) as a viable similarity measure for matching corresponding human body regions of thermal and visible images. We also demonstrate theoretically and quantitatively that LSS, as a thermal-visible similarity measure, is more robust to differences between corresponding regions' textures than the Mutual Information (MI), which is the classic multimodal similarity measure. Other viable local image descriptors including Histogram Of Gradient (HOG), Scale Invariant Feature Transform (SIFT), and Binary Robust Independent Elementary Feature (BRIEF) are also outperformed by LSS. Moreover, we propose a LSS-based dense local stereo correspondence algorithm based on a voting approach, which estimates a dense disparity map for each foreground region in the image. The resulting disparity map can then be used to align the reference image on the second image. We demonstrate that our proposed LSS-based local registration method outperforms similar state-of-the-art MI-based local registration methods in the literature. Our experiments were carried out using realistic human monitoring scenarios in a close-range scene. Due to the shortcomings of local stereo correspondence approaches for estimating accurate disparities in depth discontinuity regions, we propose a novel stereo correspondence method based on a global optimization approach. We introduce a stereo model appropriate for thermal-visible image registration using an energy minimization framework and Belief Propagation (BP) as a method to optimize the disparity assignment via an energy function. In this method, we integrated color and motion visual cues as a soft constraint into an energy function to improve disparity assignment accuracy in depth discontinuities. Although global correspondence approaches are computationally more expensive compared to Winner Take All (WTA) local correspondence approaches, the efficient BP algorithm and parallel processing programming (openMP) in C++ that we used in our implementation, speed up the processing time significantly and make our methods viable for video surveillance applications. Our methods are implemented in C++ using OpenCV library and object-oriented programming. Our methods are designed to be integrated easily for further video analysis. In other words, the input data of our methods could come from two synchronized online video streams. For further analysis a new module could be added in our frame-by-frame algorithmic diagram. Further analysis might be object tracking, human localization, and trajectory pattern analysis for multimodal long-range monitoring applications, and behavior pattern analysis, object categorization, and tracking for close-range applications

Multiple human tracking in RGB-depth data: A survey

© The Institution of Engineering and Technology. Multiple human tracking (MHT) is a fundamental task in many computer vision applications. Appearance-based approaches, primarily formulated on RGB data, are constrained and affected by problems arising from occlusions and/or illumination variations. In recent years, the arrival of cheap RGB-depth devices has led to many new approaches to MHT, and many of these integrate colour and depth cues to improve each and every stage of the process. In this survey, the authors present the common processing pipeline of these methods and review their methodology based (a) on how they implement this pipeline and (b) on what role depth plays within each stage of it. They identify and introduce existing, publicly available, benchmark datasets and software resources that fuse colour and depth data for MHT. Finally, they present a brief comparative evaluation of the performance of those works that have applied their methods to these datasets