Statistical bandwidth sharing: A study of congestion at flow level

S. B. Fredj; T. Bonald; A. Proutiere; G. Régnié; J. W. Roberts

doi:10.1145/964723.383068

Statistical bandwidth sharing: A study of congestion at flow level

S. B. Fredj, T. Bonald, A. Proutiere, G. Régnié, J. W. Roberts

Orange Labs

Research output: Contribution to journal › Conference article › peer-review

Abstract

In this paper we study the statistics of the realized throughput of elastic document transfers, accounting for the way network bandwidth is shared dynamically between the randomly varying number of concurrent flows. We first discuss the way TCP realizes statistical bandwidth sharing, illustrating essential properties by means of packet level simulations. Mathematical flow level models based on the theory of stochastic networks are then proposed to explain the observed behavior. A notable result is that first order performance (e.g., mean throughput) is insensitive with respect both to the flow size distribution and the flow arrival process, as long as "sessions" arrive according to a Poisson process. Perceived performance is shown to depend most significantly on whether demand at flow level is less than or greater than available capacity. The models provide a key to understanding the effectiveness of techniques for congestion management and service differentiation.

Original language	English
Pages (from-to)	111-122
Number of pages	12
Journal	Computer Communication Review
Volume	31
Issue number	4
DOIs	https://doi.org/10.1145/964723.383068
Publication status	Published - 27 Aug 2001
Externally published	Yes
Event	ACM SIGCOMM 2001- Applications, Technologies, Architectures, and Protocols for Computers Communications- - San Diego, CA, United States Duration: 27 Aug 2001 → 31 Aug 2001

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10.1145/964723.383068

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title = "Statistical bandwidth sharing: A study of congestion at flow level",

abstract = "In this paper we study the statistics of the realized throughput of elastic document transfers, accounting for the way network bandwidth is shared dynamically between the randomly varying number of concurrent flows. We first discuss the way TCP realizes statistical bandwidth sharing, illustrating essential properties by means of packet level simulations. Mathematical flow level models based on the theory of stochastic networks are then proposed to explain the observed behavior. A notable result is that first order performance (e.g., mean throughput) is insensitive with respect both to the flow size distribution and the flow arrival process, as long as {"}sessions{"} arrive according to a Poisson process. Perceived performance is shown to depend most significantly on whether demand at flow level is less than or greater than available capacity. The models provide a key to understanding the effectiveness of techniques for congestion management and service differentiation.",

author = "Fredj, \{S. B.\} and T. Bonald and A. Proutiere and G. R{\'e}gni{\'e} and Roberts, \{J. W.\}",

year = "2001",

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doi = "10.1145/964723.383068",

language = "English",

volume = "31",

pages = "111--122",

journal = "Computer Communication Review",

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note = "ACM SIGCOMM 2001- Applications, Technologies, Architectures, and Protocols for Computers Communications- ; Conference date: 27-08-2001 Through 31-08-2001",

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TY - JOUR

T1 - Statistical bandwidth sharing

T2 - ACM SIGCOMM 2001- Applications, Technologies, Architectures, and Protocols for Computers Communications-

AU - Fredj, S. B.

AU - Bonald, T.

AU - Proutiere, A.

AU - Régnié, G.

AU - Roberts, J. W.

PY - 2001/8/27

Y1 - 2001/8/27

N2 - In this paper we study the statistics of the realized throughput of elastic document transfers, accounting for the way network bandwidth is shared dynamically between the randomly varying number of concurrent flows. We first discuss the way TCP realizes statistical bandwidth sharing, illustrating essential properties by means of packet level simulations. Mathematical flow level models based on the theory of stochastic networks are then proposed to explain the observed behavior. A notable result is that first order performance (e.g., mean throughput) is insensitive with respect both to the flow size distribution and the flow arrival process, as long as "sessions" arrive according to a Poisson process. Perceived performance is shown to depend most significantly on whether demand at flow level is less than or greater than available capacity. The models provide a key to understanding the effectiveness of techniques for congestion management and service differentiation.

AB - In this paper we study the statistics of the realized throughput of elastic document transfers, accounting for the way network bandwidth is shared dynamically between the randomly varying number of concurrent flows. We first discuss the way TCP realizes statistical bandwidth sharing, illustrating essential properties by means of packet level simulations. Mathematical flow level models based on the theory of stochastic networks are then proposed to explain the observed behavior. A notable result is that first order performance (e.g., mean throughput) is insensitive with respect both to the flow size distribution and the flow arrival process, as long as "sessions" arrive according to a Poisson process. Perceived performance is shown to depend most significantly on whether demand at flow level is less than or greater than available capacity. The models provide a key to understanding the effectiveness of techniques for congestion management and service differentiation.

U2 - 10.1145/964723.383068

DO - 10.1145/964723.383068

M3 - Conference article

AN - SCOPUS:0034776787

SN - 0146-4833

VL - 31

SP - 111

EP - 122

JO - Computer Communication Review

JF - Computer Communication Review

IS - 4

Y2 - 27 August 2001 through 31 August 2001

ER -

Statistical bandwidth sharing: A study of congestion at flow level

Abstract

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