SPIE Journal Paper | 1 January 2007
KEYWORDS: Reconstruction algorithms, Image processing, Image restoration, Feature extraction, 3D image processing, 3D image reconstruction, 3D displays, Visual system, Motion estimation, Image segmentation
In this paper, stereo image reconstruction using regularized adaptive disparity estimation is proposed. That is, by adaptively predicting the mutual correlation between stereo images pair using the proposed algorithm, the bandwidth of stereo input images pair can be compressed to the level of a conventional 2D image and a predicted image also can be effectively reconstructed using a reference image and disparity vectors. Especially, in the proposed algorithm, the first feature values are extracted from the input stereo images pair. Then, a matching window for stereo matching is adaptively selected depending on the magnitude of these feature values. That is, for the region having larger feature values, a smaller matching window is selected, while, for the opposite case, a larger matching window is selected by comparing predetermined threshold values. This approach is not only able to reduce a mismatching of disparity vectors, which occurs in the conventional dense disparity estimation with a small matching window, but is also able to reduce blocking effects that occur in the coarse disparity estimation with a large matching window. In addition, in this paper, a new regularized adaptive disparity estimation technique is proposed. That is, by regularizing the estimated disparity vector with the neighboring disparity vectors, problems of the conventional adaptive disparity estimation scheme might be solved, and the predicted stereo image can be more effectively reconstructed. From experiments using stereo sequences of “Man”, “Fichier”, “Manege”, and “Tunnel”, it is shown that the proposed algorithm improves the PSNRs of a reconstructed image to about 6.90 dB on average at ±30 search ranges as compared to those of conventional algorithms. Also, it is found that there is almost no difference between an original image and a reconstructed image through the proposed algorithm by comparison to that of conventional algorithms.