As compressed videos are transmitted in the communication networks, video packet loss inevitably occurs. This problem can be solved by error concealment method. We used the motion vector of the… Click to show full abstract
As compressed videos are transmitted in the communication networks, video packet loss inevitably occurs. This problem can be solved by error concealment method. We used the motion vector of the available neighboring blocks to estimate the lost motion vector for the lost block. These estimates propagate to predict all other missing motion vectors. We further improved the work by using the idea of the motion vector disparities between neighboring available blocks to modify the motion vector weightings. Furthermore, the differences between the compensated pixels and the decoded pixels in the neighboring blocks are computed for another weighting for improvement. These two novelties are combined as a final indicator to prediction weightings. By comparison against the state-of-the-art method, the four proposed algorithms increase the average peak signal-to-noise ratio (PSNR) by up to 1.86, 1.93, 1.94, and 2.04 dB on average, showing the gradual improvement of our design systems. For other video quality measurements, the average gains of the proposed work against the state-of-the-art work can be up to 0.0575 in structural similarity index metric (SSIM), −0.0278 in video quality metric (VQM) (the lower the better), −0.0008 in motion-based video integrity evaluation (MOVIE) (the lower the better), and 2.77 in subjective evaluation. The proposed work performs slightly worse than a pixel-based state-of-the-art method in PSNR and SSIM but performs better in VQM and MOVIE (both correlate better with human perception) and subjective experiments, with much lower computational complexity.
               
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