Overlapped Block Matching Research Articles

Computational Cost Reduction of Improved Super-Resolution Method Using Overlapped Block Matching

Computational Cost Reduction of Improved Super-Resolution Method Using Overlapped Block Matching

Performance Improvement of Super-Resolution by Dense Motion Estimation Using Overlapped Block Matching

Performance Improvement of Super-Resolution by Dense Motion Estimation Using Overlapped Block Matching

Parallel Numerics and Applications

Parallel Numerics and Applications

Overlapped block disparity compensation with adaptive windows for stereo image coding

We propose a modified overlapped block-matching (OBM) scheme for stereo image coding. OBM has been used in video coding but, to the best of our knowledge, it has not been applied to stereo image coding to date. In video coding, OBM has proven useful in reducing blocking artifacts (since multiple vectors can be used for each block), while also maintaining most of the advantages of fixed-size block matching. There are two main novelties in this work. First, we show that OBM techniques can be successfully applied to stereo image coding. Second, we take advantage of the smoothness properties typically found in disparity fields to further improve the performance of OBM in this particular application. Specifically, we note that practical OBM approaches use noniterative estimation techniques, which produce lower quality estimates than iterative methods. By introducing smoothness constraints into the noniterative DV computation, we improve the quality of the estimated disparity as compared to standard noniterative OBM approaches. In addition, we propose a disparity estimation/compensation approach using adaptive windows with variable shapes, which results in a reduction in complexity. We provide experimental results that show that our proposed hybrid OBM scheme achieves a PSNR gain (about 1.5-2 dB) as compared to a simple block-based scheme, with some slight PSNR gains (about 0.2-0.5 dB) in a reduced complexity, as compared to an approach based on standard OBM with half-pixel accuracy.

A hybrid video codec with block-based and mesh-based motion compensation modes

This article presents a complete video codec which supports both block-based and mesh-based motion compensation modes. While the mesh-based modes are suitable for spatially continuous representation of in-plane rotations, zooms, and other motions that can be represented by parametric mappings, the block-based modes (especially overlapped block matching) perform better around motion boundaries. Therefore, a hybrid codec with block-based and mesh-based modes, which nicely complement each other, yields the best results over a wide range of video at low bit rates. Experimental results with MPEG-4 test sequences are shown to demonstrate the performance of the proposed hybrid codec. © 1998 John Wiley & Sons, Inc. Int J Imaging Syst Technol, 9, 248–256, 1998

A hybrid video codec with block‐based and mesh‐based motion compensation modes

This article presents a complete video codec which supports both block-based and mesh-based motion compensation modes. While the mesh-based modes are suitable for spatially continuous representation of in-plane rotations, zooms, and other motions that can be represented by parametric mappings, the block-based modes (especially overlapped block matching) perform better around motion boundaries. Therefore, a hybrid codec with block-based and mesh-based modes, which nicely complement each other, yields the best results over a wide range of video at low bit rates. Experimental results with MPEG-4 test sequences are shown to demonstrate the performance of the proposed hybrid codec. © 1998 John Wiley & Sons, Inc. Int J Imaging Syst Technol, 9, 248–256, 1998

Wavelet vector quantisation scheme forimage sequence coding at 64 kbit/s

A new method for low bit rate video coding based on overlapped block matching and successive approximation wavelet vector quantisation is described. The main advantage of this scheme is that the most important data of the motion compensated interframe prediction error image are given priority coding, resulting in excellent coding performance. Simulation results show that at 64kbit/s, the proposed method outperforms the RM8 implementation of H.261 by 2-3 dB.

Low bit-rate video coding using wavelet vector quantisation

A method for low bit-rate video coding based on wavelet vector quantisation is proposed. Motion estimation/compensation using overlapped block matching (OBM) is employed to eliminate the blocking effects in the prediction error introduced by conventional block matching. It is shown that OBM significantly increases the efficiency of the wavelet transform coder. The motion-compensated interframe prediction error is decomposed using a wavelet transform and a method is employed for the efficient coding of the wavelet coefficients. In this technique, the coefficients are coded with a zero-tree multistage lattice vector quantiser. Simulation results are provided to evaluate the coding performance of the described coding scheme for low bit-rate video coding. It provides constant bit rate, obviating the need for buffer, with just small fluctuations in PSNR. Moreover, comparison with the RM8 implementation of the standard H261 video coder shows that the presented codec provides improvements in both peak signal-to-noise ratio and picture quality.