AVS-M: from standards to applications
Journal of Computer Science and Technology - Special section on China AVS standard
Optimized H.264/AVC-based bit stream switching for mobile video streaming
EURASIP Journal on Applied Signal Processing
Alternate motion-compensated prediction for error resilient video coding
Journal of Visual Communication and Image Representation
The emerging MVC standard for 3D video services
EURASIP Journal on Applied Signal Processing - 3DTV: Capture, Transmission, and Display of 3D Video
Error resilient coding and error concealment in scalable video coding
IEEE Transactions on Circuits and Systems for Video Technology
Semantic adaptation of synchronized multimedia streams in a format-independent way
PCS'09 Proceedings of the 27th conference on Picture Coding Symposium
Multimedia Tools and Applications
Error resilient video coding using B pictures in H.264
IEEE Transactions on Circuits and Systems for Video Technology
A real-time content adaptation framework for exploiting ROI scalability in H.264/AVC
ACIVS'06 Proceedings of the 8th international conference on Advanced Concepts For Intelligent Vision Systems
Implementation strategies for efficient media fragment retrieval
Multimedia Tools and Applications
Robust P2P Multimedia Exchange within a VANET
Wireless Personal Communications: An International Journal
A URI-based approach for addressing fragments of media resources on the Web
Multimedia Tools and Applications
Protecting H.264/AVC data-partitioned video streams over broadband WiMAX
Advances in Multimedia
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Different types of prediction are applied in modern video coding. While predictive coding improves compression efficiency, the propagation of transmission errors becomes more likely. In addition, predictive coding brings difficulties to other aspects of video coding, including random access, parallel processing, and scalability. In order to combat the negative effects, video coding schemes introduce mechanisms such as slices and intracoding, to limit and break the prediction. This paper proposes the use of the isolated regions coding tool that jointly limits in-picture prediction and interprediction on a region-of-interest basis. The tool can be used to provide random access points from non-intrapictures and to respond to intrapicture update requests. Furthermore, it can be applied as an error-robust macroblock mode decision method and can be used in combination with unequal error protection. Finally, it enables mixing of scenes, which is useful in coding of masked scene transitions.