Title :
Scalable Video Coding Extension for HEVC
Author :
Jianle Chen ; Rapaka, K. ; Xiang Li ; Seregin, Vadim ; Liwei Guo ; Karczewicz, Marta ; Auwera, G.V.D. ; Sole, Joel ; Xianglin Wang ; Chengjie Tu ; Ying Chen ; Joshi, Rajan
Author_Institution :
Qualcomm Technol. Inc., San Diego, CA, USA
Abstract :
This paper describes a scalable video codec that was submitted as a response to the joint call for proposals issued by ISO/IEC MPEG and ITU-T VCEG on HEVC scalable extension. The proposed codec uses a multi-loop decoding structure. Several inter-layer texture prediction methods are employed to remove the inter-layer redundancy. Inter-layer prediction is also used when coding enhancement layer syntax elements such as motion parameter and intra prediction mode, to further reduce bit overhead. Additionally, alternative transforms as well as adaptive coefficients scanning are used to code the prediction residues more efficiently. Experimental results are presented to demonstrate the effectiveness of the proposed scheme. When compared to HEVC single-layer coding, the additional rate overhead for the proposed scalable extension is 1.2% to 6.4% to achieve two layers of SNR and spatial scalability.
Keywords :
IEC standards; ISO standards; decoding; image enhancement; image motion analysis; image scanners; image texture; media streaming; prediction theory; video codecs; video coding; HEVC scalable extension; ISO-IEC MPEG; ITU-T VCEG; SNR; coding enhancement layer syntax element; interlayer redundancy; interlayer texture prediction method; intraprediction mode; motion parameter; multiloop decoding structure; scalable video coding extension; spatial scalability; video codec; Adaptive filters; Codecs; Decoding; Encoding; Scalability; Signal to noise ratio; Syntactics; HEVC; Scalable Video Coding;
Conference_Titel :
Data Compression Conference (DCC), 2013
Conference_Location :
Snowbird, UT
Print_ISBN :
978-1-4673-6037-1
DOI :
10.1109/DCC.2013.27
