Keyframe-based monocular SLAM: design, survey, and future directions

Extensive research in the field of monocular SLAM for the past fifteen years has yielded workable systems that found their way into various applications in robotics and augmented reality. Although filter-based monocular SLAM systems were common at some time, the more efficient keyframe-based solutions are becoming the de facto methodology for building a monocular SLAM system. The objective of this paper is threefold: first, the paper serves as a guideline for people seeking to design their own monocular SLAM according to specific environmental constraints. Second, it presents a survey that covers the various keyframe-based monocular SLAM systems in the literature, detailing the components of their implementation, and critically assessing the specific strategies made in each proposed solution. Third, the paper provides insight into the direction of future research in this field, to address the major limitations still facing monocular SLAM; namely, in the issues of illumination changes, initialization, highly dynamic motion, poorly textured scenes, repetitive textures, map maintenance, and failure recovery

Biometric Systems

Because of the accelerating progress in biometrics research and the latest nation-state threats to security, this book's publication is not only timely but also much needed. This volume contains seventeen peer-reviewed chapters reporting the state of the art in biometrics research: security issues, signature verification, fingerprint identification, wrist vascular biometrics, ear detection, face detection and identification (including a new survey of face recognition), person re-identification, electrocardiogram (ECT) recognition, and several multi-modal systems. This book will be a valuable resource for graduate students, engineers, and researchers interested in understanding and investigating this important field of study

Change detection in combination with spatial models and its effectiveness on underwater scenarios

This thesis proposes a novel change detection approach for underwater scenarios and combines it with different especially developed spatial models, this allows accurate and spatially coherent detection of any moving objects with a static camera in arbitrary environments. To deal with the special problems of underwater imaging pre-segmentations based on the optical flow and other special adaptions were added to the change detection algorithm so that it can better handle typical underwater scenarios like a scene crowded by a whole fish swarm

Gaze-Based Human-Robot Interaction by the Brunswick Model

We present a new paradigm for human-robot interaction based on social signal processing, and in particular on the Brunswick model. Originally, the Brunswick model copes with face-to-face dyadic interaction, assuming that the interactants are communicating through a continuous exchange of non verbal social signals, in addition to the spoken messages. Social signals have to be interpreted, thanks to a proper recognition phase that considers visual and audio information. The Brunswick model allows to quantitatively evaluate the quality of the interaction using statistical tools which measure how effective is the recognition phase. In this paper we cast this theory when one of the interactants is a robot; in this case, the recognition phase performed by the robot and the human have to be revised w.r.t. the original model. The model is applied to Berrick, a recent open-source low-cost robotic head platform, where the gazing is the social signal to be considered

Raum-Zeit Interpolationstechniken

The photo-realistic modeling and animation of complex scenes in 3D requires a lot of work and skill of artists even with modern acquisition techniques. This is especially true if the rendering should additionally be performed in real-time. In this thesis we follow another direction in computer graphics to generate photo-realistic results based on recorded video sequences of one or multiple cameras. We propose several methods to handle scenes showing natural phenomena and also multi-view footage of general complex 3D scenes. In contrast to other approaches, we make use of relaxed geometric constraints and focus especially on image properties important to create perceptually plausible in-between images. The results are novel photo-realistic video sequences rendered in real-time allowing for interactive manipulation or to interactively explore novel view and time points.Das Modellieren und die Animation von 3D Szenen in fotorealistischer Qualität ist sehr arbeitsaufwändig, auch wenn moderne Verfahren benutzt werden. Wenn die Bilder in Echtzeit berechnet werden sollen ist diese Aufgabe um so schwieriger zu lösen. In dieser Dissertation verfolgen wir einen alternativen Ansatz der Computergrafik, um neue photorealistische Ergebnisse aus einer oder mehreren aufgenommenen Videosequenzen zu gewinnen. Es werden mehrere Methoden entwickelt die für natürlicher Phänomene und für generelle Szenen einsetzbar sind. Im Unterschied zu anderen Verfahren nutzen wir abgeschwächte geometrische Einschränkungen und berechnen eine genaue Lösung nur dort wo sie wichtig für die menschliche Wahrnehmung ist. Die Ergebnisse sind neue fotorealistische Videosequenzen, die in Echtzeit berechnet und interaktiv manipuliert, oder in denen neue Blick- und Zeitpunkte der Szenen frei erkundet werden können