H.264 Advance Video Coding (AVC)/ MPEG-4 Part 10 REFERENCES

H.264 Advance Video Coding (AVC)/ MPEG-4 Part 10 REFERENCES

1. 
   R. Schäfer, T. Wiegand and H. Schwarz, “The emerging H.264/AVC standard,” EBU Technical Review, pp. 1–12, Jan. 2003.
   
2. 
   JVT Draft ITU-T recommendation and final draft international standard of joint video specification (ITU-T Rec. H.264–ISO/IEC 14496-10 AVC), March 2003, JVT-G050 available on http://ip.hhi.de/imagecom_G1/assets/pdfs/JVT-G050.pdf.
   
3. 
   T. Wiegand et al, “Overview of the H.264/AVC video coding standard,” IEEE Trans. CSVT, Special Issue on H.264/AVC, vol. 13, pp. 560–576, July 2003. Draw the JPEG baseline decoder block diagram. [12 points]he proposed systematic solution and the fast algorithm can also be applied to
   
4. 
   H.S. Malvar et al, “Low-complexity transform and quantization in H.264/AVC,” IEEE Trans. CSVT, vol. 13, pp. 598–603, July 2003.
   
5. 
   T. Stockhammer, M.M. Hannuksela and T. Wiegand, “H.264/AVC in wireless environments,” IEEE Trans. CSVT, vol. 13, pp. 657–673, July 2003.
   
6. 
   S. Wenger, “H.264/AVC over IP,” IEEE Trans. CSVT, vol. 13, pp. 645–656, July 2003.
   
7. 
   A. Tamhankar and K.R. Rao, “An overview of H.264 / MPEG-4 part 10,” Proc. 4th EURASIP-IEEE Conf. focused on Video/Image Processing and Multimedia Communications, vol. 1, pp. 1–51, Zagreb, Croatia, July 2003.
   
8. 
   J. Ostermann et al, “Video coding with H.264/AVC: Tools, performance, and complexity”, IEEE Circuits and Systems Magazine, vol. 4, pp. 7–28, First Quarter 2004.
   
9. 
   M. Fieldler, “Implementation of basic H.264/AVC decoder,” Seminar Paper at Chemnitz University of Technology, June 2004.
   
10. 
    Y. Zhang et al, “Fast 4x4 intra-prediction mode selection for H.264”, in Proc. Int. Conf. Multimedia Expo, pp. 1151–1154, Taipei, Taiwan, Jun. 2004.
    
11. 
    G.J. Sullivan, P. Topiwala and A. Luthra, “The H.264/AVC advanced video coding standard: Overview and introduction to the fidelity range extensions,” SPIE Conf. on Applications of Digital Image Processing XXVII, vol. 5558, pp. 53–74, Aug. 2004.
    
12. 
    F. Fu et al, “Fast intra prediction algorithm in H.264/AVC”, Proc. 7th Int. Conf. Signal Process., pp. 1191–1194, Beijing, China, Sep. 2004.
    
13. 
    A. Puri, X. Chen and A. Luthra, “Video coding using the H.264/MPEG-4 AVC compression standard,” Signal Processing: Image Communication, vol. 19, pp. 793–849, Oct. 2004.
    
14. 
    F. Pan et al, “Fast intra mode decision algorithm for H.264/AVC video coding,” Proc. IEEE ICIP., pp. 781–784, Singapore, Oct. 2004.
    
15. 
    Proc. IEEE, Special Issue on Advances in Video Coding and Delivery, vol. 93, pp. 3–193, Jan. 2005. This has several overview papers.
    
16. 
    T. Sikora, “Trends and perspectives in image and video coding,” Proc. IEEE, vol. 93, pp. 6–17, Jan.2005.
    
17. 
    G.J. Sullivan and T. Wiegand, “Video compression – From concepts to H.264/AVC standard”, (Tutorial), Proc. IEEE, vol.93, pp. 18–31, Jan. 2005.
    
18. 
    D. Marpe and T. Wiegand, “H.264/MPEG4-AVC Fidelity Range Extensions: Tools, Profiles, Performance, and Application Areas”, IEEE ICIP, vol. 1, pp. I - 596, 11-14 Sept. 2005.
    
19. 
    Y-L. Lee and K-H. Han, “Complexity of the proposed lossless intra for 4:4:4”, (ISO/IEC JTC1/SC29/WG11 and ITU-T SG 16 Q.6) document JVT-Q035, 17-21 Oct. 2005.
    
20. 
    D. Kumar, P. Shastry and A. Basu, “Overview of the H.264 / AVC,” 8th Texas Instruments Developer Conference India, 30 Nov. – 1 Dec. 2005, Bangalore, India.
    
21. 
    Proc. IEEE, Special Issue on Global Digital Television: Technology and Emerging Services, vol.94, Jan. 2006.
    
22. 
    G. Raja and M. Mirza, “In-loop de-blocking filter for H.264/AVC Video,” Proc. the 2nd IEEE-EURASIP Int. Symp. Commun., Control and Signal Processing 2006, ISCCSP, Marrakech, Morocco, March 2006.
    
23. 
    S.-K. Kwon, A. Tamhankar and K.R. Rao, “Overview of H.264/MPEG-4 Part 10,” J. Vis. Commun. Image Representation (JVCIR), vol. 17, pp. 186–216, April 2006. Special Issue on “Emerging H.264/AVC Video Coding Standard”.
    
24. 
    S. Kumar et al, “Error resiliency schemes in H.264/AVC standard,” J. Visual Commun. Image Representation. (JVCIR), Special Issue on H.264/AVC, vol. 17, pp. 425–450, April 2006.
    
25. 
    D. Marpe, T. Wiegand and G. J. Sullivan, “The H.264/MPEG-4 AVC standard and its applications,” IEEE Communications Magazine, vol. 44, pp. 134143, Aug. 2006.
    
26. 
    S. Naito and A. Koike, “Efficient coding scheme for super high definition video based on extending H.264 high profile,” in Proc. SPIE Visual Commun. Image Process., vol. 6077, pp. 607727-1-607727-8, Jan. 2006.
    
27. 
    J. Kim et al, “Complexity reduction algorithm for intra mode selection in H.264/AVC video coding” J. Blanc-Talon et al. (Eds.): pp. 454–465, ACIVS 2006, LNCS 4179, Springer, 2006.
    
28. 
    S. Ma and C.C. J. Kuo, “High-definition video coding with super macroblocks,” in Proc. SPIE VCIP, vol. 6508, pp. 650816-1-650816-12, Jan. 2007.
    
29. 
    T. Wiegand and G.J. Sullivan, “The H.264/AVC video coding standard,” IEEE SP Magazine, vol. 24, pp. 148–153, March 2007. (Info on H.264/AVC resources)
    
30. 
    H.264/AVC JM 18.0 reference software: http://iphome.hhi.de/suehring/tml/download/
    
31. 
    “H.264 video compression standard,” White paper, Axis communications.
    
32. 
    W. Lee et al, “High speed intra prediction scheme for H.264/AVC,” IEEE Trans. Consumer Electronics, vol. 53, no. 4, pp. 1577–1582, Nov. 2007.
    
33. 
    Y.Q. Shi and H. Sun, “Image and video compression for multimedia engineering,” Boca Raton: CRC Press, II Edition (Chapter on H.264), 2008.
    
34. 
    B. Furht and S.A. Ahson, “Handbook of mobile broadcasting, DVB-H, DMB, ISDB-T and MEDIAFLO,” Boca Raton, FL: CRC Press, 2008. (H.264 related chapters)
    
35. 
    M. Jafari and S. Kasaei, “Fast intra- and inter-prediction mode decision in H.264 advanced video coding,” International Journal of Computer Science and Network Security, vol. 8, pp. 130–140, May 2008.
    
36. 
    A.M. Tourapis (January 2009), “H.264/14496-10 AVC reference software manual” [Online]. Available: http://iphome.hhi.de/suehring/tml/JM%20Reference%20Software%20Manual%20%28JVT-AE010%29.pdf
    
37. 
    P. Carrillo, H. Kalva, and T. Pin, “Low complexity H.264 video encoding,” SPIE, vol. 7443, paper # 74430A, Aug. 2009.
    
38. 
    B.M.K. Aswathappa and K.R. Rao, “Rate-distortion optimization using structural information in H.264 strictly intra-frame encoder,” IEEE Southeastern Symp. on System Theory (SSST), Tyler, TX, March 2010.
    
39. 
    D. Han et al, “Low complexity H.264 encoder using machine learning”, IEEE SPA 2010, pp. 40–43, Poznan, Poland, Sept. 2010.
    
40. 
    T. Sathe, “Complexity reduction of H.264/AVC motion estimation using OpenMP,” M.S. Thesis, EE Dept., University of Texas at Arlington, Arlington, Texas, May 2011. http://www.uta.edu/faculty/krrao/dip click on courses and then click on EE5359 Scroll down and go to Thesis/Project Title and click on T.Sathe
    
41. 
    D. Han, A. Kulkarni and K.R. Rao, “Fast inter-prediction mode decision algorithm for H.264 video encoder,” IEEE ECTICON 2012, Cha Am, Thailand, May 2012.
    
42. 
    H.264/MPEG-4 AVC: http://en.wikipedia.org/wiki/H.264
    
43. 
    S. Subbarayappa, “Implementation and analysis of directional discrete cosine transform in H.264 for baseline profile,” M.S. Thesis, EE Dept., UTA, May 2012.
    
44. 
    I.E. Richardson, “H.264 / MPEG-4 Part 10 White Paper,” www.vcodex.com
    
45. 
    I.E. Richardson, “Overview: What is H.264?” 2011. www.vcodex.com
    
46. 
    I.E. Richardson, “A Technical Introduction to H.264/AVC,” 2011. [Online]. Available: http://www.vcodex.com/files/H.264_technical_introduction.pdf
    
47. 
    I.E. Richardson, “White Paper: H.264 / AVC intra prediction,” 2011. www.vcodex.com
    
48. 
    I.E. Richardson, “White Paper: H.264 / AVC inter prediction,” 2011. www.vcodex.com
    
49. 
    I.E. Richardson, “White Paper: 44 transform and quantization in H.264/AVC,” Nov. 2010. www.vcodex.com
    
50. 
    I.E. Richardson, “White Paper: H.264 / AVC loop filter,” 2011. www.vcodex.com
    
51. 
    Joint Video Team (JVT), ITU-T website, http://www.itu.int/ITU-T/studygroups/com16/jvt/
    
52. 
    “RGB Spectrum’s H.264 codecs hit the mark in the latest U.S. missile test program,” May 2012. www.rgb.com. See [B18].
    
53. 
    ISO website: http://www.iso.org/iso/home.htm
    
54. 
    IEC website: http://www.iec.ch/
    
55. 
    ITU-T website: http://www.itu.int/ITU-T/index.html
    
56. 
    C.-L. Su, T.-M. Chen and C.-Y. Huang,” Cluster-Based Motion Estimation Algorithm with Low Memory and Bandwidth Requirements for H.264/AVC Scalable Extension”, IEEE Trans. CSVT, vol.24, pp. 1016-1024, June 2014.
    

JM 16.0

H.264/mpeg-4 AVC reference software joint Model 18.4 available at

H57 FFmpeg Developers (2013): Libavcodec H.264 Decoder [Online]. Available: http://ffmpeg.org, accessed Aug 1, 2014.

H58 X264: A free H.264 Encoder [Online] Available: http://www.videolan.org/developers/x.264.html, accessed Aug.1, 2014.

H59 D. S. Eagle, “Beyond the Full HD (UHD & 8K),” Sunday 12 April 2015, 3:30 PM to 4:45 PM, NAB Show, Las Vegas, NV, April 2015.

Sony’s XAVC format employs MPEG-4 AVC/H.264 level 5.2, the highest picture resolution and frame rate video compression codec based on industry standards. XAVC enables a very wide range of operational possibilities for content production, notably: from Proxy to 4K pixel resolutions, intra frame and long GOP schemes, and 1080 50P/60P infrastructure capability.

Built with the principles of workflow efficiency, evolution and optimized image quality at its heart, Sony’s XAVC can support the following content formats: 

• 
  4K (4096 x 2160 and 3840 x 2160), HD and proxy resolution 
  
• 
  MPEG-4 AVC/H.264 video compression 
  
• 
  12, 10 and 8 bit color depth 
  
• 
  Up to 60fps 
  
• 
  MXF wrapping format can be used 
  
• 
  4:4:4, 4:2:2, 4:2:0 color sampling 
  

Website : http://www.sony.co.uk/pro/article/broadcast-products-sonys-new-xavc-recording-format-accelerates

H60 I. E. G. Richardson, “The H.264 Advanced Video Compression Standard,” II Edition, Wiley, 2010.

H61 T. Wiegand et al, “Introduction to the Special Issue on Scalable Video Coding—Standardization and Beyond,” IEEE Trans. CSVT, vol. 17, pp. 1099 – 1269, Sept. 2007.

H62 K. Muller et al,” Multi – view video coding based on H.264/AVC using hierarchical B-frames,” in Proc. PCS 2006, Picture Coding Symp., Beijing, China, April 2006.

H63. T. Wiegand et al, “Joint draft 5: scalable video coding,” Joint Video Team of ISO/IEC MPEG and ITU-T VCEG, Doc. JVT-R201, Bangkok, Jan. 2006.

H64. G. J. Sullivan, “ The H.264 / MPEG4-AVC video coding standard and its deployment status,” in proc. SPIE conf. visual communications and image processing (VCIP), Beijing, China, July 2005.

H65. T. Wiegand et al, “Rate- constrained coder control and comparison of video coding standards,” IEEE Trans. CSVT, vol.13, pp. 688 – 703, July 2003.

H66. C. Fenimore et al, “ Subjective testing methodology in MPEG video verification,” in Proc. SPIE Applications of Digital Image Processing, vol. 5558, pp. 503 -511, Denver, CO, Aug. 2004.

H67. MPEG industry forum resources [online] Available: http://www.mpegif.org/reswources.php

H68. H. Schwarz, D. Marpe and T. Wiegand, “ Overview of the scalable H.264/ AVC extension,” in Proc. IEEE Int. Conf. Image Processing, Atlanta, GA, pp. 161-164, Oct. 2006.

H69.C.-H. Kuo, L.-L. Shih and S.-C. Shih, “Rate control via adjustment of Lagrange multiplier for video coding”, IEEE Trans. CSVT, (EARLY ACCESS)

H70. A.K. Au-Yeung, S. Zhu and B. Zeng, ‘Partial video encryption using multiple 8x8 transforms in H.264 and MPEG-4,’ Proceedings of ICASSP 2011, pp.2436-2439, Prague, Czech Republic., May 2011.

H71. A.K. Au-Yeung, S. Zhu and B. Zeng, ‘Design of new unitary transforms for perceptual video encryption,’ IEEE Trans. CSVT, vol.21, pp.1341- 1345, Sept. 2011.

H72. B. Zeng et al, ‘Perceptual encryption of H.264 videos: embedding sign-flips into the integer-based transforms,’ IEEE Trans. Information Forensics and Security, vol.9, no.2, pp.309-320, Feb. 2014.

H73. S.J. Li et al, “On the design of perceptual MPEG-video encryption algorithms,” IEEE Trans. CSVT, vol.17, pp. 214-223, Feb.2007.

H74. B.Y. Lei, K.T. Lo and J. Feng, ‘Encryption Techniques for H.264 Video,” The Handbook of MPEG Applications: Standards in Practice, pp.151-174, Edited by M.C. Angelides and H. Agius, Wiley, Feb.2011.

H75. Overview of H.264/AVC: http://www.csee.wvu.edu/~xinl/courses/ee569/H264_tutorial.pdf

Access to HM Software Manual: http://iphome.hhi.de/marpe/download/Performance_HEVC_VP9_X264_PCS_2013_preprint.pdf

H76. M.P. Krishnan, “Implementation and performance analysis of 2D order 16 integer transform in H.264 and AVS - China for HD video coding” M.S. Thesis, EE Dept., UT-Arlington, TX, Dec. 2010.

H77. B. Dey and M.K. Kundu, “Enhanced microblock features for dynamic background modeling in H.264/AVC video encoded at low bitrate”, IEEE Trans. CSVT (EARLY ACCESS).

H78 K. Minemura; K. Wong; R. Phan; K. Tanaka, "A Novel Sketch Attack for H.264/AVC Format-Compliant Encrypted Video," in IEEE Trans. CSVT, (Early access). Conclusions are repeated here.

Conclusions: In this work, we proposed a novel sketch attack for H.264/AVC format-compliant encrypted video. Specifically, the macroblock bitstream size was exploited to sketch the outline of the original video frame directly from the encrypted video. In addition, the Canny edge map was considered as the ideal outline image and an edge similar score was modified for performance evaluation purposes. Experimental results suggest that the proposed sketch attack can extract visual information directly from the format-compliant encrypted video. Although the proposed and conventional methods can sketch the outline from the encrypted INTRA-frame, only the proposed MBS sketch attack method can sketch the outline from the encrypted INTER-frame, which outnumbers INTRA-frame, by far, in compressed video. Moreover, the proposed MBS sketch attack is verified to be more robust against compression when compared to the conventional sketch attacks. In view of this proposed sketch attack framework, we suggest that this framework should be considered for format compliant video encryption security analysis. In addition to determining the encryption modules in use by analyzing the encrypted video, we would like to extend this sketch attack framework to handle different video standards such as High Efficiency Video Coding (HEVC), Audio Video Standard (AVS) and Google VP9 as our future work