S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, UC Berkeley, Dec. 1996. UCB/CSD-96-928.  Home/Search   Document Details and Download   Summary   Related Articles   Check

....adaptive models are of less interest than client adaptive models because the former does not generalize well to multicast scenarios. Our current challenge in this area is to develop loss reactive adaptation mechanisms that achieve near optimal performance as optimal adaptation. McCanne s RLM [16] adaptation mechanism utilizes sustained packet loss as a signal to streams that their subscription level is too high for the bandwidth available along their route. We propose a similar scheme but where the stream s sensitivity to loss depends on the stream volume and the mean stream volume. ....

Steve McCanne, Scalable Compression and Transmission of Internet Multicast Video, Ph.D. thesis, University of California at Berkeley, 1996.

....in bandwidth, so that a fixed bit rate is transmitted to each client. In contrast, several previous works on multicast of audio and video, most notably Receiver driven Layered Multicast, exploited the properties of layered coding to efficiently transmit to clients at different bit rates [4, 5]. Low bandwidth clients would receive only a base layer, for example, while high bandwidth clients would receive both a base layer and an enhancement layer. In this paper we explore layered multiple description codes, which have the advantages of both layered codes and multiple description codes, ....

S. R. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, The University of California, Berkeley, CA, December 1996.

....lower bandwidths would receive less layers, depending on their actual bandwidth. Applications (or devices) known as transceivers would be in charge of data scaling. The RTP protocol already supports them and VAT can act as a transceiver. More about data (in this case video) scaling can be found in [55]. ....

S. McCanne, "Scalable Compression and Transmission of Internet Multicast Video," Ph.D. Thesis, University of California Berkeley, UCB/CSD-96-928, December

....the choice of parameters in layered wavelet video coding are presented in Section 7.3. The article concludes with an outlook in Section 8. 2 Related Work This article deals with layered wavelet video encoding and thus exploits findings of earlier works in the area of layered video algorithms. In [9] a number of typical approaches for layered video encoding are described which similar to our approach carry out scaling in the spatial domain. They can be split into two categories: layered DCT and pyramid coding. Layered DCT approaches transform the video signal into the frequency domain. ....

Steven McCanne. Scalable Compression and Transmission of Internet Multicast Video. Ph.D. Thesis, University of California, Berkeley, CA, USA, 1996.

....which started operations in 1992. The initial success of the MBone motivated further interest in the development of tools that make use of that infrastructure. Examples of audio and or video conferencing tools are INRIA s ivs, Schulzrinne s nevot [1] Xerox PARC s nv [2] UCB LBNL s vic and vat [3], and more. There were also tools that required a different type of multicast service: whereas audio and video data can tolerate some amount of packet loss without severely degrading the quality of the reproduced signal, applications which involve the transport of binary data (such as text) ....

....the video source is sliced into a number of multiresolution layers, each layer is transmitted over a separate multicast group, and different receivers adapt to bandwidth fluctuations by adjusting the number of layers to which they subscribe. This is the approach pioneered by McCanne in his thesis [3], and of much of the recent work in this area (e.g. 6] 7] 8] 9] Now, despite its many successes, layered multicast suffers from three basic deficiencies: Lack of fairness among different multicast sessions. Without some additional machinery (e.g. RED gateways [10] it is ....

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S. R. McCanne, Scalable Compression and Transmission of Internet Multicast Video, Ph.D. thesis, University of California, Berkeley, 1996.

....Intra H.261 takes advantage of the fact that lost block updates will typically be made quickly redundant by a new block transmitted due to continued change in that area. This is particularly true of the talking head in front of a large static background common in Internet seminars and conferences [McCanne96b]. 3.4.3 Whiteboard wb communicates between clients in the same session by multicasting commands in UDP packets. Each packet contains the source s identity, a timestamp, and one of 12 structured drawing commands. These range from RECTANGLE and LINE to Postscript wrappers that allow entire ....

....particularly inefficient on the Internet, which already has a multipeer connection mechanism in the form of multicast. A number of mechanisms have been developed to retain the benefits of multicast whilst catering for the differing needs of heterogeneous clients. Receiver driven Layered Multicast [McCanne96b] and Scalable Consensus based Bandwidth Adaptation [Amir98a] are end toend schemes that allow different clients to vary the amount of data they receive and to specify to data sources how they should share the available bandwidth. Other schemes like the UCL Transcoding Gateway use active services ....

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S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. Ph.D. thesis, University of California Berkeley, UCB/CSD-96-928, December 1996.

....and only a discrete set of bandwidths in another range. The situation becomes signi cantly di erent in this general case. The general case is relevant in the current day networking scenario. For example, every additional layer induces an exponential increase in the total bit rate in the codec of [12]. A study of fair allocation of utilities will capture this general scenario as well, and will unify the frameworks of [17] and [18] Recently, researchers have studied the parallel problem of utility maximization in unicast networks. Low et al. has developed a distributed algorithm for computing ....

S. McCanne, Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, Univ. of California, Berkeley, December 1996:

....as quality adaptation and can be performed in a number of ways. One option, called simulcast, encodes the bitstream at various target bitrates and switches between the previously encoded layers as the available bandwidth changes. An alternative quality adaptation scheme uses hierarchical encoding [12, 13, 25], where the video stream is encoded at a base layer and one or more enhancement layers, which can be combined to render the stream at higher quality. As the available bandwidth varies, the number of enhancement layers is adjusted by the server. Rate oscillations degrade the quality of received ....

S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, Univ. of California at Berkeley, 1996.

....Each 8 8 block of each image is transformed into the frequency domain, and the bits of the DCT coefficients are distributed over several layers. This corresponds to applying different quantisation factors ranging from coarse to fine for the coefficients. In the layered frequencies approach [3] each 8 8 block of each image of the video is transformed into the frequency domain using DCT. After quantisation, the coefficients are stored in different layers, e.g. the first layer contains the first three coefficients, the second layer the next three coefficients and so on. The core idea ....

Steven McCanne, Scalable Compression and Transmission of Internet Multicast Video, Ph.D. thesis, University of California, Berkeley, CA, USA, 1996.

....of most encoders can not be changed over a wide range. In an alternative approach, the server keeps several versions of each stream with different qualities. As available bandwidth changes, the server plays back streams of higher or lower quality as appropriate. With hierarchical encoding[9] [10], 11] 12] the server maintains a layered encoded version of each stream. As more bandwidth becomes available, more layers of the encoding are delivered. If the average bandwidth decreases, the server may then drop some of the layers being transmitted. Layered approaches usually have the ....

S. McCanne, "Scalable compression and transmission of internet multicast video," Ph.D. thesis, University of California Berkeley, UCB/CSD-96-928, December 1996.

....error degree) Target Rate Packet Scheduling Buffer Buffer Video (UDP) Feedback (TCP) 4 dynamics rather than processed feedbacks. Additionally, the same concept can be easily extended to multicast or multi user environments because the sender needs not handle feedbacks from all receivers [23][24] 25] SFRAM will calculate the next available bandwidth (ABW) which keeps network utilization high while limiting the overload and improving inter protocol fairness. ABW is translated at the sender into the target rate for the video encoder and used for packet scheduling to meet the ABW ....

S. McCanne, Scalable compression and transmission of internet multicast video. Ph.D. thesis, University of California Berkeley, 1996.

....would be malicious users mounting denial of service attacks by blasting unresponsive traffic into the network. Second, some applications use congestion control algorithms that, while responsive, are not TCP friendly. An example of such an algorithm is Receiver driven Layered Multicast (RLM) [69]. 1 Third, some users will cheat and use a non TCP congestion control algorithm to get more bandwidth. An example of this would be using a modified form of TCP with, for instance, a larger initial window and window opening constants. Starting with Nagle [74] many researchers observed that ....

....in Section 4.4 showed RLM receiving less than its fair share, when we change the simulation scenario so that the TCP flow starts after all the RLM flows, it then receives less than half of its fair share. This hysteresis in the RLM versus TCP behavior was first pointed out to us by Steve McCanne [69]. 46 a) Reference Stateful Network b) SCORE Network FQ FQ FQ FQ FQ FQ FQ FQ CSFQ CSFQ CSFQ CSFQ CSFQ CSFQ CSFQ CSFQ Figure 4.1: a) A reference stateful network that provides fair bandwidth allocation; each node implements the Fair Queueing algorithm. b) A SCORE network that ....

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S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, University of California at Berkeley, Computer Science Division, December 1996. Technical Report UCB/CSD-96-928.

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S. R. McCanne, "Scalable compression and transmission of Internet multicast video," Ph.D. dissertation, Univ. California, Berkeley, Dec. 1996.

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S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, UC Berkeley, Dec. 1996. UCB/CSD-96-928.

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S. McCanne, Scalable compression and transmission of internet muerne st video, Ph.D. Thesis, University of California at Berkeley, 1996.

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S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, University of California Berkeley, 1996.

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S. R. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, University of California, Berkeley, 1996.

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S. R. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, The University of California, Berkeley, CA, December 1996.

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S. R. McCanne, "Scalable Compression and Transmission of Internet Multicast Video," Proceedings of ACM SIGCOMM, 1990.

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S. McCanne, Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, University of California, Berkeley, 1996.

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S. McCanne, "Scalable compression and transmission of internet multicast video," Ph.D. dissertation, University of California at Berkeley, 1996.

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S. McCanne. Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, University of California at Berkeley, Computer Science Division, December 1996. Technical Report UCB/CSD-96-928.

No context found.

S. R. McCanne, "Scalable compression and transmission of internet multicast video," Tech. Rep. Ph.D. Thesis, UCB/CSD-96-928, University of California, Berkeley, 1996.

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S. McCanne, Scalable Compression and Transmission of Internet Multicast Video. PhD thesis, University of California, Berkeley, CA, USA, 1996.

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McCanne, S., Scalable Compression and Transmission of Internet Multicast Video, Ph.D. thesis, University of California Berkeley, UCB/CSD-96-928, December 1996.

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