[24] ISO/IEC 14496-3 “Coding of audio-visual objects, Part 3: Audio”, final committee draft, May 1998. [25] ITU-T Rec. H.264 | ISO/IEC 14496-10 AVC, “Study of Final Committee Draft of Joint <strong>Video</strong> Specification”, February 2003. [26] P. Amon, G. Bäse, K. Illgner, and J. Pandel, “Efficient Coding of Synchronized H.26L Streams”, ITU-T <strong>Video</strong> Coding Experts Group (VCEG), document VCEG-N35, Santa Barbara, CA, USA, September 2001. [27] N. Kamaci, Y. Altunbask, “Performance comparison of the emerging H.264 video coding standard with the existing standards”, in IEEE Int. Conf. Multimedia and Expo, ICME’03, Baltimore, MD, July 2003. [28] S. Wenger, M.M. Hannuksela, T. Stockhammer, M. Westerlund, and D. Singer, “RTP payload Format for H.264 <strong>Video</strong>”, Internet Draft, IETF, June 2003, Expires December 2003. [29] Windows Media Home Page, available at: http://www.microsoft.com/windows/windowsmedia/ [30] Real <strong>Video</strong> Home Page, available at : http://www.realnetworks.com/solutions/leadership/realvideo.html [31] K. Shen and E. J. Delp, “Wavelet base rate scalable video compression”, IEEE Trans. Circuits Syst. <strong>Video</strong> Technol., vol. 9, pp. 109–121, 1999. [32] J. M. Shapiro, “Embedded image coding using zero tree of wavelet coefficients”, IEEE Trans. Signal Processing, vol. 41, pp. 3445–3462, 1993. [33] I. Sodagar, H.-J. Lee, P. Hatrack, and Y.-Q. Zhang, “Scalable wavelet coding for synthetic/natural hybrid images”, IEEE Trans. Circuits Syst. <strong>Video</strong> Technol., vol. 9, pp. 244– 254, 1999. [34] J.-Y. Tham, S. Ranganath, and A. A. Kassim, “Highly scalable wavelet based video codec for very low bit-rate environment”, IEEE Trans. Circuits Syst. <strong>Video</strong> Technol., vol. 16, pp. 12–27, 1998. [35] S. Wenger, “<strong>Video</strong> Redundancy Coding in H.263+”, Workshop on Audio-Visual Services for <strong>Packet</strong> <strong>Networks</strong>, September 1997. [36] V. Vaishampayan and S. John, “Interframe balanced-multiple description video compression”, IEEE Inter Conf. on Image Processing, Oct.1999. [37] A. Reibman, H. Jafarkhani, Y. Wang, M. Orchard, and R. Puri, “Multiple description coding for video using motion compensated prediction”, IEEE Inter. Conf. Image Processing , October 1999. [38] J. Apostolopoulos, “Error-resilient video compression via multiple state streams”, In Proc. International Workshop on Very Low Bitrate <strong>Video</strong>Coding (VLBV'99), October 1999. [39] J. Apostolopoulos and S. Wee, “Unbalanced Multiple Description <strong>Video</strong> Communication Using Path Diversity”, IEEE International Conference on Image Processing, October 2001. [40] W. Li, “<strong>Over</strong>view of Fine Granularity Scalability in MPEG-4 video standard,” IEEE Trans. Circuits and Systems for <strong>Video</strong> Technology, vol. 11, no. 3 , pp. 301-317, Mar. 2001. [41] F. Ling,W. Li, and H.-Q. Sun, “Bitplane coding of DCT coefficients for image and video compression”, in Proc. SPIE-VC<strong>IP</strong>’99, San Jose, CA, Jan. 25–27, 1999, pp. 500–508. [42] W. Li, “Bitplane coding of DCT coefficients for fine granularity scalability”, ISO/IEC JTC1/SC29/WG11, MPEG98/M3989, Oct. 1998. 160
[43] B. Schuster, “Fine granular scalability with wavelets coding”, ISO/IEC JTC1/SC29/WG11, MPEG98/M4021, Oct. 1998. [44] Y.-W. Chen, H. Radha, and R. A. Cohen, “Results of experiment of fine granular scalability with wavelet encoding of residuals,”, SO/IEC JTC1/SC29/WG11, MPEG98/M3988, Oct. 1998. [45] J. Liang, J. Yu, Y.Wang, M. Srinath, and M.-H. Zhou, “Fine granularity scalable video coding using combination of MPEG4 video objects and still texture objects,”, ISO/IEC JTC1/SC29/WG11, MPEG98/M4025, Oct. 1998. [46] S. C. S. Cheung and A. Zakhor, “Matching pursuit coding for fine granular video scalability”, ISO/IEC JTC1/SC29/WG11, MPEG98/M3991, Oct. 1998. [47] M. Benetiere and C. Dufour, “Matching pursuits residual coding for video fine granular scalability”, ISO/IEC JTC1/SC29/WG11, MPEG98/M4008, Oct. 1998. [48] J. Macnicol, M. Frater, and J. Arnold, “Results on fine granularity scalability”, Melbourne, Australia, ISO/IEC JTC1/SC29/WG11, MPEG99/m5122, Oct. 1999. [49] F. Wu, S. Li and Y.-Q. Zhang, “A framework for efficient progressive fine granularity scalable video coding,” IEEE Trans. Circuits and Systems for <strong>Video</strong> Technology, special issue on streaming video, Vol. 11, no 3, 332-344, 2001. [50] X. Sun, F. Wu, S. Li, W. Gao, and Y,-Q. Zhang, “Macroblock-based progressive fine granularity scalable video coding”, ICME2001, Tokyo, Aug. 22-25, 2001. [51] S. Li, F. Wu, and Y. Q. Zhang, “Study of a new approach to improve FGS video coding efficiency”, ISO/IEC JTC1/SC29/WG11, MPEG98/M5583, Dec. 1999. [52] J. Hartung, A. Jacquin, J. Pawlyk, and K. L. Shipley, “A real-time scalable software video codec for collaborative applications over packed networks,” in Proc ACM Multimedia’98, Bristol, U.K., Sept. 1998, pp. 419–426. [53] P. Amon, K. Illgner, and J. Pandel, “SNR Scalable Layered <strong>Video</strong> Coding”, International <strong>Packet</strong> <strong>Video</strong> Workshop 2002, Pittsburgh, PA, USA, April 2002. [54] K. Illgner, P. Amon, J. Pandel, and M. Wagner, “Scalable <strong>Video</strong> Coding and Resilient Transmission over <strong>IP</strong>”, 2002 Tyrrhenian International Workshop on Digital Communications (IWDC 2002), Capri, Italy, September 2002. [55] S.E. Han and B. Girod, “Robust and Efficient Scalable <strong>Video</strong> Coding with Leaky Prediction”, In International Conference on Image Processing (IC<strong>IP</strong> 2002), Rochester, NY, USA, September 2002. [56] Y. He, R. Yan, F. Wu, and S. Li, “H.26L-based Fine Granularity Scalable <strong>Video</strong> Coding”, ITU- T <strong>Video</strong> Coding Experts Group (VCEG), document VCEG-O60, Pattaya, Thailand, Decembe 2001. [57] R. Yan, F. Wu, S. Li, and Y.Q. Zhang, “Macroblock-based Progressive Fine Granularity Spatial Scalability (mb-PFGSS)”, ISO/IEC JTC1/SC29/WG11, MPEG2001/M7112, March 2001. [58] S. McCanne and V. Jacobson, “Receiver-driven layered multicast”, in Proc. ACM SIGCOMM’96, Stanford, CA, pp. 117–130, Aug. 1996. [59] P. Amon, and J. Pandel “Evaluation of <strong>Adaptive</strong> and Reliable <strong>Video</strong> Transmission Technologies”, <strong>Packet</strong> <strong>Video</strong>’03, France, April 2003. [60] X. Sun, S. Li, F. Wu, G. Shen, and W. Gao, “Efficient and flexible drift-free video bitstream switching at predictive frames”, ICME 2002. 161
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Résumé Nous constatons aujourd’
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3 Related Work ....................
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5.5.1.2 Simulation Results.........
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List of Figures Figure 1-1: Structu
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Figure 5-15: End-to-end packet tran
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Acknowledgments The first person I
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[11] Toufik Ahmed, Guillaume Burida
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d’accès. Les interactions de QoS
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Métrique MAX_DELAY PREF_MAX_DELAY
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1.1.2 Proposition dun Protocole d'E
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des paquets RTP. Reste toujours le
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Nous pouvons distinguer trois possi
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1.1.2.5.2 Multiplexage des Flux El
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l’horloge est par défaut égale
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La valeur R TCP représente le déb
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Pour ces raisons, nous nous intére
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Telles que illustrés par la Figure
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3. DMIF2SIP vérifie si son propre
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utilisée optionnellement pour loca
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Chapter 2 2 Introduction 2.1 Motiva
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conditions. Based on end-to-end fee
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Chapter 3 3 Related Work Nowadays,
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• multicasting: it takes the stre
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expensive, fixed delivery and recep
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3.1.6 Static vs. Dynamic Channels T
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environment because they require a
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H.261 is called video codec for aud
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VideoScene (VS) VideoObject (VO) Vi
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Temporal scalability involves parti
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multitude of streams. It can switch
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3.2.2.1 End-to-End Retransmission R
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correctly received block. The missi
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two H.323 endpoints or between an e
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Chapter 4 4 Adaptive Packet Video T
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the same value. This timing informa
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0.3 0.25 our proposal classical app
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lost packet at the receiver. Conseq
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marking scheme. The server must be
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The video server adds audio-visual
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Marker (TR3CM) [131] to mark the ba
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VO1 VO2 AVO Scenario Audio BL EL1 E
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Throughput (Kbits) 3000 2500 2000 1
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