Exemplar-based Video Inpainting without Ghost Shadow Artifacts by Maintaining Temporal Continuity

[[abstract]]Image inpainting or image completion is the technique that automatically restores/completes removed areas in an image. When dealing with a similar problem in video, not only should a robust tracking algorithm be used, but the temporal continuity among video frames also needs to be taken into account, especially when the video has camera motions such as zooming and tilting. In this paper, we extend an exemplar-based image inpainting algorithm by incorporating an improved patch matching strategy for video inpainting. In our proposed algorithm, different motion segments with different temporal continuity call for different candidate patches, which are used to inpaint holes after a selected video object is tracked and removed. The proposed new video inpainting algorithm produces very few "ghost shadows," which were produced by most image inpainting algorithms directly applied on video. Our experiments use different types of videos, including cartoon, video from games, and video from digital camera with different camera motions. Our demonstration at http://member.mine.tku.edu.tw/www/T_CSVT/web/shows the promising results

Novel Video Completion Approaches and Their Applications

Video completion refers to automatically restoring damaged or removed objects in a video sequence, with applications ranging from sophisticated video removal of undesired static or dynamic objects to correction of missing or corrupted video frames in old movies and synthesis of new video frames to add, modify, or generate a new visual story. The video completion problem can be solved using texture synthesis and/or data interpolation to fill-in the holes of the sequence inward. This thesis makes a distinction between still image completion and video completion. The latter requires visually pleasing consistency by taking into account the temporal information. Based on their applied concepts, video completion techniques are categorized as inpainting and texture synthesis. We present a bandlet transform-based technique for each of these categories of video completion techniques. The proposed inpainting-based technique is a 3D volume regularization scheme that takes advantage of bandlet bases for exploiting the anisotropic regularities to reconstruct a damaged video. The proposed exemplar-based approach, on the other hand, performs video completion using a precise patch fusion in the bandlet domain instead of patch replacement. The video completion task is extended to two important applications in video restoration. First, we develop an automatic video text detection and removal that benefits from the proposed inpainting scheme and a novel video text detector. Second, we propose a novel video super-resolution technique that employs the inpainting algorithm spatially in conjunction with an effective structure tensor, generated using bandlet geometry. The experimental results show a good performance of the proposed video inpainting method and demonstrate the effectiveness of bandlets in video completion tasks. The proposed video text detector and the video super resolution scheme also show a high performance in comparison with existing methods

Advanced editing methods for image and video sequences

In the context of image and video editing, this thesis proposes methods for modifying the semantic content of a recorded scene. Two different editing problems are approached: First, the removal of ghosting artifacts from high dynamic range (HDR) images recovered from exposure sequences, and second, the removal of objects from video sequences recorded with and without camera motion. These editings need to be performed in a way that the result looks plausible to humans, but without having to recover detailed models about the content of the scene, e.g. its geometry, reflectance, or illumination. The proposed editing methods add new key ingredients, such as camera noise models and global optimization frameworks, that help achieving results that surpass the capabilities of state-of-the-art methods. Using these ingredients, each proposed method defines local visual properties that approximate well the specific editing requirements of each task. These properties are then encoded into a energy function that, when globally minimized, produces the required editing results. The optimization of such energy functions corresponds to Bayesian inference problems that are solved efficiently using graph cuts. The proposed methods are demonstrated to outperform other state-ofthe-art methods. Furthermore, they are demonstrated to work well on complex real-world scenarios that have not been previously addressed in the literature, i.e., highly cluttered scenes for HDR deghosting, and highly dynamic scenes and unconstraint camera motion for object removal from videos.Diese Arbeit schlägt Methoden zur Änderung des semantischen Inhalts einer aufgenommenen Szene im Kontext der Bild-und Videobearbeitung vor. Zwei unterschiedliche Bearbeitungsmethoden werden angesprochen: Erstens, das Entfernen von Ghosting Artifacts (Geist-ähnliche Artefakte) aus High Dynamic Range (HDR) Bildern welche von Belichtungsreihen erstellt wurden und zweitens, das Entfernen von Objekten aus Videosequenzen mit und ohne Kamerabewegung. Das Bearbeiten muss in einer Weise durchgeführt werden, dass das Ergebnis für den Menschen plausibel aussieht, aber ohne das detaillierte Modelle des Szeneninhalts rekonstruiert werden müssen, z.B. die Geometrie, das Reflexionsverhalten, oder Beleuchtungseigenschaften. Die vorgeschlagenen Bearbeitungsmethoden beinhalten neuartige Elemente, etwa Kameralärm-Modelle und globale Optimierungs-Systeme, mit deren Hilfe es möglich ist die Eigenschaften der modernsten existierenden Methoden zu übertreffen. Mit Hilfe dieser Elemente definieren die vorgeschlagenen Methoden lokale visuelle Eigenschaften welche die beschriebenen Bearbeitungsmethoden gut annähern. Diese Eigenschaften werden dann als Energiefunktion codiert, welche, nach globalem minimieren, die gewünschten Bearbeitung liefert. Die Optimierung solcher Energiefunktionen entspricht dem Bayes’schen Inferenz Modell welches effizient mittels Graph-Cut Algorithmen gelöst werden kann. Es wird gezeigt, dass die vorgeschlagenen Methoden den heutigen Stand der Technik übertreffen. Darüber hinaus sind sie nachweislich gut auf komplexe natürliche Szenarien anwendbar, welche in der existierenden Literatur bisher noch nicht angegangen wurden, d.h. sehr unübersichtliche Szenen für HDR Deghosting und sehr dynamische Szenen und unbeschränkte Kamerabewegungen für das Entfernen von Objekten aus Videosequenzen