Rate-adaptive codes for distributed source coding
Signal Processing - Special section: Distributed source coding
Studying the GOP size impact on the performance of a feedback channel-based Wyner-Ziv video codec
PSIVT'07 Proceedings of the 2nd Pacific Rim conference on Advances in image and video technology
Recent results in the Shannon theory
IEEE Transactions on Information Theory
The rate-distortion function for source coding with side information at the decoder
IEEE Transactions on Information Theory
Duality between source coding and channel coding and its extension to the side information case
IEEE Transactions on Information Theory
Correlation Noise Modeling for Efficient Pixel and Transform Domain Wyner–Ziv Video Coding
IEEE Transactions on Circuits and Systems for Video Technology
Analysis for Video Coding: Moving It from the Encoder to the Decoder
ICIAR '08 Proceedings of the 5th international conference on Image Analysis and Recognition
Side-information generation for temporally and spatially scalable Wyner-Ziv codecs
Journal on Image and Video Processing - Special issue on distributed video coding
Dynamic quality control for transform domain Wyner-Ziv video coding
Journal on Image and Video Processing - Special issue on distributed video coding
Refining side information for improved transform domain Wyner-Ziv video coding
IEEE Transactions on Circuits and Systems for Video Technology
Complexity efficient stopping criterion for LDPC based distributed video coding
Proceedings of the 5th International ICST Mobile Multimedia Communications Conference
Variable and constant bitrate in a DVC to H.264/AVC transcoder
Image Communication
Low-complexity video coding via power-rate-distortion optimization
Journal of Visual Communication and Image Representation
Forward wyner-ziv fast video decoding using multicore processors
MMM'12 Proceedings of the 18th international conference on Advances in Multimedia Modeling
Proceedings of the 20th ACM international conference on Multimedia
Multi-view codec with low-complexity encoding for Distributed Video Coding
Multimedia Tools and Applications
Probabilistic motion-compensated prediction in distributed video coding
Multimedia Tools and Applications
Toward fast Wyner-Ziv video decoding on multicore processors
Multimedia Tools and Applications
Maximum likelihood motion compensation for distributed video coding
Integrated Computer-Aided Engineering
Hi-index | 0.00 |
Wyner-Ziv (WZ) video coding-a particular case of distributed video coding (DVC)-is a new video coding paradigm based on two major Information Theory results: the Slepian-Wolf and Wyner-Ziv theorems. In recent years, some practical WZ video coding solutions have been proposed with promising results. One of the most popular WZ video coding architectures in the literature uses turbo codes based Slepian-Wolf coding and a feedback channel to perform rate control at the decoder. This WZ video coding architecture has been first proposed by researchers at Stanford University and has been after adopted and improved by many research groups around the world. However, while there are many papers published with changes and improvements to this architecture, the precise and detailed evaluation of its performance, targeting its deep understanding for future advances, has not been made. Available performance results are mostly partial, under unclear and incompatible conditions, using vaguely defined and also sometimes architecturally unrealistic codec solutions. This paper targets the provision of a detailed, clear, and complete performance evaluation of an advanced transform domain WZ video codec derived from the Stanford turbo coding and feedback channel based architecture. Although the WZ video codec proposed for this evaluation is among the best available, the main purpose and novelty of this paper is the solid and comprehensive performance evaluation made which will provide a strong, and very much needed, performance reference for researchers in this WZ video coding field, as well as a solid way to steer future WZ video coding research.