• Title/Summary/Keyword: CAVLC(Context-based Adaptive Variable Length Code)

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VLSI Design of H.264/AVC CAVLC encoder for HDTV Application (실시간 HD급 영상 처리를 위한 H.264/AVC CAVLC 부호화기의 하드웨어 구조 설계)

  • Woo, Jang-Uk;Lee, Won-Jae;Kim, Jae-Seok
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.44 no.7 s.361
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    • pp.45-53
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    • 2007
  • In this paper, we propose an efficient hardware architecture for H.264/AVC CAVLC (Context-based Adaptive Variable Length Coding) encoding. Previous CAVLC architectures search all of the coefficients to find statistic characteristics in a block. However, it is unnecessary information that zero coefficients following the last position of a non-zero coefficient when CAVLC encodes residual coefficients. In order to reduce this unnecessary operation, we propose two techniques, which detect the first and last position of non-zero coefficients and arrange non-zero coefficients sequentially. By adopting these two techniques, the required processing time was reduced about 23% compared with previous architecture. It was designed in a hardware description language and total logic gate count is 16.3k using 0.18um standard cell library Simulation results show that our design is capable of real-time processing for $1920{\times}1088\;30fps$ videos at 81MHz.

A design of Context-Based Adaptive Variable Length Coder For H.264 (H.264용 Context-Based Adaptive Variable Length Coder(CAVLC) 설계)

  • Lee, Hong-Sic;Suh, Ki-Bum
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • v.9 no.2
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    • pp.237-240
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    • 2005
  • This paper propose an novel CAVLC architcture for H.264 and designed the CAVLC module which can be used in AMBA based design. This designed module can be operated in 420 cycle for one-macroblock and support both long-start code method using Annex B.1 and RTP. To verify the CAVLC architecture, we developed the reference C from JM8.5 and verified the our developed hardware using test vector generated by reference C. The designed circuit can be operated in 54MHz clock system, and has 14096 gate counts using Hynix 0.35 um TLM process.

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Implementation of CAVLC Encoder for the Image Compression in H.264/AVC (H.264/AVC용 영상압축을 위한 CAVLC 인코더 구현)

  • Jung Duck Young;Choi Dug Young;Jo Chang-Seok;Sonh Seung Il
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.9 no.7
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    • pp.1485-1490
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    • 2005
  • Variable length code is an integral component of many international standards on image and video compression currently. Context-based Adaptive Variable Length Coding(CAVLC) is adopted by the emerging JVT(also called H.264, and AVC in MPEG-4). In this paper, we design an architecture for CAVLC encoder, including a coeff_token encoder, level encoder, total_zeros encoder and run_before encoder. The designed CAVLC encoder can encode one syntax element in one clock cycle. As a result of implementation by Vertex-1000e of Xilinx, its operation frequency is 68MHz. Therefore, it is very suitable for video applications that require high throughput.

Design of CAVLC Encoder for the Compressed Image in H.264/AVC (H.264/AVC에 적용 가능한 압축영상용 CAVLC 인코더 설계)

  • Jung, Duck-Young;Choi, Dug-Young;Sonh, Seung-Il
    • Proceedings of the Korean Institute of Information and Commucation Sciences Conference
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    • v.9 no.2
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    • pp.299-302
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    • 2005
  • 요즘 시대는 영상 기술과 IT 발전으로 다양한 멀티미디어 서비스를 제공하기 위해 고품질의 비디오와 높은 데이터 압축을 요구하게 되었고, 이를 위해 MPEG-4 AVC/H.264에서는 기존의 MPEG-4에서 채택한 VLC 기술과 유사한 Context-based Adaptive Variable Length Code(CAVLC)기술을 채택하여 이를 가능하게 하였다. 특히 CAVLC 기술은 HDTV처럼 큰 영상 뿐 아니라 카메라폰이나 DMB등과 같은 영상에서 고품질의 영상을 보다 효율적으로 제공 한다. 본 논문은 최근의 이미지와 비디오 압축에 대한 요구에 따라 H.264/AVC와 MPEG4-PART 1-에서 표준으로 채택한 CAVLC의 부호화 과정을 연구하여 Visual C++언어를 이용한 최적화된 시뮬레이션과 CAVLC의 성능평가를 통한 최적화를 실시하였고, 최적화된 예측 정보를 바탕으로 CAVLC를 VHDL언어를 이용하여 하드웨어로 구현하였다.

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Design of CAVLC Decoder for H.264/AVC (H.264/AVC용 CAVLC 디코더의 설계)

  • Jung, Duck-Young;Sonh, Seung-Il
    • Journal of the Korea Institute of Information and Communication Engineering
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    • v.11 no.6
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    • pp.1104-1114
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    • 2007
  • Digital video compression technique has played an important role that enables efficient transmission and storage of multimedia data where bandwidth and storage space are limited. The new video coding standard, H.264/AVC, developed by Joint Video Team(JVT) significantly outperforms previous standards in compression performance. Especially, variable length code(VLC) plays a crucial pun in video and image compression applications. H.264/AVC standard adopted Context-based Adaptive Variable Length Coding(CAVLC) as the entropy coding method. CAVLC of H.264/AVC requires a large number of the memory accesses. This is a serious problem for applications such as DMB and video phone service because of the considerable amount of power that is consumed in accessing the memory. In order to overcome this problem in this paper, we propose a variable length technique that implements memory-free coeff_token, level, and run_before decoding based on arithmetic operations and using only 70% of the required memory at total_zero variable length decoding.

Hardware Implementation of DCT and CAVLC for H.264/AVC based on Co-design (병행설계를 이용한 H.264/AVC의 DCT 및 CAVLC 하드웨어 구현)

  • Wang, Duck-Sang;Seo, Seok-Yong;Ko, Hyung-Hwa
    • Journal of Advanced Navigation Technology
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    • v.17 no.1
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    • pp.69-79
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    • 2013
  • In this paper, DCT(Discrete Cosine Transform) and CAVLC(Context Adaptive Variable Length Coding) are co-designed as hardware IP with software operation of the other modules in H.264/AVC codec. In order to increase the operation speed, a new method using SHIFT table is proposed. As a result, enhancement of about 16(%) in the operation speed is obtained. Designed Hardware IPs are downloaded into Virtex-4 FX60 FPGA in the ML-410 development board and H.264/AVC encoding is performed with Microblaze CPU implemented in FPGA. Software modules are developed from JM13.2 to make C code. In order to verify the designed Hardware IPs, Modelsim program is used for functional simulation. As a result that all Hardware IPs and software modules are downloaded into the FPGA, improvement of processing speed about multiples of 16 in case of DCT hardware IP and multiples of 10 in case of CAVLC compared with software-only processing. Although this paper deals with co-design of H/W and S/W for H.264, it can be utilized for the other embedded system design.