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Multi-Sever based Distributed Coding based on HEVC/H.265 for Studio Quality Video Editing

  • Kim, Jongho (Realistic AV research group, Electronics and Telecommunications Research Institute) ;
  • Lim, Sung-Chang (Realistic AV research group, Electronics and Telecommunications Research Institute) ;
  • Jeong, Se-Yoon (Realistic AV research group, Electronics and Telecommunications Research Institute) ;
  • Kim, Hui-Yong (Realistic AV research group, Electronics and Telecommunications Research Institute)
  • Received : 2018.08.20
  • Accepted : 2018.09.13
  • Published : 2018.09.30

Abstract

High Efficiency Video Coding range extensions (HEVC RExt) is a kind of extension model of HEVC. HEVC RExt was specially designed for dealing the high quality images. HEVC RExt is very essential for studio editing which handle the very high quality and various type of images. There are some problems to dealing these massive data in studio editing. One of the most important procedure is re-encoding and decoding procedure during the editing. Various codecs are widely used for studio data editing. But most of the codecs have common problems to dealing the massive data in studio editing. First, the re-encoding and decoding processes are frequently occurred during the studio data editing and it brings enormous time-consuming and video quality loss. This paper, we suggest new video coding structure for the efficient studio video editing. The coding structure which is called "ultra-low delay (ULD)". It has the very simple and low-delayed referencing structure. To simplify the referencing structure, we can minimize the number of the frames which need decoding and re-encoding process. It also prevents the quality degradation caused by the frequent re-encoding. Various fast coding algorithms are also proposed for efficient editing such as tool-level optimization, multi-serve based distributed coding and SIMD (Single instruction, multiple data) based parallel processing. It can reduce the enormous computational complexity during the editing procedure. The proposed method shows 9500 times faster coding speed with negligible loss of quality. The proposed method also shows better coding gain compare to "intra only" structure. We can confirm that the proposed method can solve the existing problems of the studio video editing efficiently.

Keywords

References

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