Motion segmentation initialization strategies for bi-directional inter-frame prediction

Experimental results and the latest standards have proved that segmentation based video coding systems can outperform the traditional block-based video coding systems. However, this approach requires the simultaneous estimation of both the shape and motion of moving objects in a video scene. In most of the cases neither the shape nor the motion are known initially. Another critical aspect of this tightly-coupled relationship is that inaccurate motion estimation may cause poor segmentation and erroneous segmentation may negatively impact motion estimation. While some of the existing approaches require user intervention and some use clues such as depth, colour or occlusion to separate the foreground from the background, we propose to use motion reliability information for this purpose. This is because the ingredients necessary for the calculation of motion reliability are the by-product of block-based motion estimation and compensation between the reference frames. Therefore, they require very little or no increase in the computational overhead. In this paper, we explore several motion segmentation initialization strategies based on motion reliability. The performances of these initialization approaches are investigated, in terms of the PSNR, for the predicted inter-frames.

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