Coding unit complexity-based predictions of coding unit depth and prediction unit mode for efficient HEVC-to-SHVC transcoding with quality scalability

•Novel unit prediction method for efficient HEVC-to-SHVC transcoding is proposed.•Two proposed techniques are early termination and adaptive confidence interval.•We are among the first to propose a fast HEVC-to-SHVC transcoding framework.•Proposed method reduces encoding time of SHVC by 74.14% almos...

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Bibliographic Details
Published in:Journal of visual communication and image representation 2018-08, Vol.55, p.342-351
Main Authors: Yeh, Chia-Hung, Tseng, Wen-Yu, Kang, Li-Wei, Lee, Cheng-Wei, Muchtar, Kahlil, Chen, Mei-Juan
Format: Article
Language:English
Subjects:
Coding unit complexity
Early termination
HEVC (high efficiency video coding)
Scalable video coding
SHVC (scalability extension of HEVC)
Video transcoding
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Summary:•Novel unit prediction method for efficient HEVC-to-SHVC transcoding is proposed.•Two proposed techniques are early termination and adaptive confidence interval.•We are among the first to propose a fast HEVC-to-SHVC transcoding framework.•Proposed method reduces encoding time of SHVC by 74.14% almost without quality loss. To support good video quality of experiences in heterogeneous environments, transcoding an existed HEVC (high efficiency video coding) video bitstream to a SHVC (scalability extension of HEVC) bitstream with quality scalability is highly required. A straightforward way is to first fully decode the input HEVC bitstream and then fully re-encode it with the SHVC encoder, which requires a tremendous computational complexity. To solve the problem, in this paper, a coding unit complexity (CUC)-based prediction method for predictions of CU (coding unit) depth and PU (prediction unit) mode for efficient HEVC-to-SHVC transcoding with quality scalability is proposed to significantly reduce the transcoding complexity. The proposed method contains two prediction techniques, including (i) early termination and (ii) adaptive confidence interval, and predicts the CU depth and PU mode relying on the decoded information from the input HEVC bitstream. Experimental results have shown that the proposed method significantly outperforms the traditional HEVC-to-SHVC method by 74.14% on average in reductions of encoding time for SHVC enhancement layer.
ISSN:1047-3203
1095-9076
DOI:10.1016/j.jvcir.2018.06.008