Asymptotic behavior of a critical fluid model for a processor sharing queue via relative entropy

Puha, Amber L.; Williams, Ruth

doi:10.1214/15-ssy198

Cited by 4 publications

(48 citation statements)

References 9 publications

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“…The following lemma can be proved in the same manner as lemma 7.12 of Puha and Williams (2016), so we omit the proof.…”

Section: Proofs Of Theorem 1 and Corollary 1 61 Smooth Approximatiomentioning

confidence: 99%

“…This provides a rigorous formulation of a partial differential equation assumed to hold by Paganini et al (2012). A similar smoothing technique was also used by Puha and Williams (2016) in the study of the asymptotic behavior of critical fluid model solutions for a single class processor sharing queue. Our method is a little different from that of Puha and Williams (2016) in that we smooth the entire fluid model solution and not just the initial condition.…”

Section: Introductionmentioning

confidence: 99%

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Stability of a Subcritical Fluid Model for Fair Bandwidth Sharing with General File Size Distributions

Williams

2020

Stochastic Systems

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This work concerns the asymptotic behavior of solutions to a (strictly) subcritical fluid model for a data communication network, where file sizes are generally distributed and the network operates under a fair bandwidth-sharing policy. Here we consider fair bandwidth-sharing policies that are a slight generalization of the [Formula: see text]-fair policies introduced by Mo and Walrand [Mo J, Walrand J (2000) Fair end-to-end window-based congestion control. IEEE/ACM Trans. Networks 8(5):556–567.] Since the year 2000, it has been a standing problem to prove stability of the data communications network model of Massoulié and Roberts [Massoulié L, Roberts J (2000) Bandwidth sharing and admission control for elastic traffic. Telecommunication Systems 15(1):185–201.], with general file sizes and operating under fair bandwidth sharing policies, when the offered load is less than capacity (subcritical conditions). A crucial step in an approach to this problem is to prove stability of subcritical fluid model solutions. In 2012, Paganini et al. [Paganini F, Tang A, Ferragut A, Andrew LLH (2012) Network stability under alpha fair bandwidth allocation with general file size distribution. IEEE Trans. Automatic Control 57(3):579–591.] introduced a Lyapunov function for this purpose and gave an argument, assuming that fluid model solutions are sufficiently smooth in time and space that they are strong solutions of a partial differential equation and assuming that no fluid level on any route touches zero before all route levels reach zero. The aim of the current paper is to prove stability of the subcritical fluid model without these strong assumptions. Starting with a slight generalization of the Lyapunov function proposed by Paganini et al., assuming that each component of the initial state of a measure-valued fluid model solution, as well as the file size distributions, have no atoms and have finite first moments, we prove absolute continuity in time of the composition of the Lyapunov function with any subcritical fluid model solution and describe the associated density. We use this to prove that the Lyapunov function composed with such a subcritical fluid model solution converges to zero as time goes to infinity. This implies that each component of the measure-valued fluid model solution converges vaguely on [Formula: see text] to the zero measure as time goes to infinity. Under the further assumption that the file size distributions have finite pth moments for some p > 1 and that each component of the initial state of the fluid model solution has finite pth moment, it is proved that the fluid model solution reaches the measure with all components equal to the zero measure in finite time and that the time to reach this zero state has a uniform bound for all fluid model solutions having a uniform bound on the initial total mass and the pth moment of each component of the initial state. In contrast to the analysis of Paganini et al., we do not need their strong smoothness assumptions on fluid model solutions and we rigorously treat the realistic, but singular situation, where the fluid level on some routes becomes zero, whereas other route levels remain positive.

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“…The following lemma can be proved in the same manner as lemma 7.12 of Puha and Williams (2016), so we omit the proof.…”

Section: Proofs Of Theorem 1 and Corollary 1 61 Smooth Approximatiomentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Stability of a Subcritical Fluid Model for Fair Bandwidth Sharing with General File Size Distributions

Williams

2020

Stochastic Systems

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“…Traditional processor sharing with general distributional assumptions, as studied here, is not HL and a different notion of relative entropy is needed to carry out our analysis. In [14], Puha and Williams formulated such a notion of relative entropy in order to study the asymptotic behavior of critical fluid model solutions for single class processor sharing queues operating under general distributional assumptions. In the earlier work [13], also on single class processor sharing queues, Puha and Williams used renewal theoretic arguments to obtain rates of convergence results under higher moment assumptions than those required in [14].…”

Section: Introductionmentioning

confidence: 99%

“…In [14], Puha and Williams formulated such a notion of relative entropy in order to study the asymptotic behavior of critical fluid model solutions for single class processor sharing queues operating under general distributional assumptions. In the earlier work [13], also on single class processor sharing queues, Puha and Williams used renewal theoretic arguments to obtain rates of convergence results under higher moment assumptions than those required in [14]. The renewal theoretic techniques in [13] seem rather specific to a single class and rates of convergence are stronger than what is typically required in state space collapse arguments.…”

Section: Introductionmentioning

confidence: 99%

“…The renewal theoretic techniques in [13] seem rather specific to a single class and rates of convergence are stronger than what is typically required in state space collapse arguments. Therefore, an important motivation for the work in [14] was to devise a methodology that might not require higher moment assumptions and might more naturally extend to the network setting. The results in this current paper further develop the methodology of [14] in this direction.…”

Section: Introductionmentioning

confidence: 99%

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Asymptotic behavior of a critical fluid model for a multiclass processor sharing queue via relative entropy

2019

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This work concerns the asymptotic behavior of critical fluid model solutions for a multiclass processor sharing queue under general distributional assumptions. Such critical fluid model solutions are measure valued functions of time. We prove that critical fluid model solutions converge to the set of invariant states as time goes to infinity, uniformly for all initial conditions lying in certain relatively compact sets. This generalizes an earlier single class result of Puha and Williams to the more complex multiclass setting. In particular, several new challenges are overcome, including formulation of a suitable relative entropy functional and identifying a convenient form of the time derivative of the relative entropy applied to trajectories of critical fluid model solutions.

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Asymptotic behavior of a critical fluid model for bandwidth sharing with general file size distributions

Williams

2022

Ann. Appl. Probab.

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Asymptotic behavior of a critical fluid model for a processor sharing queue via relative entropy

Cited by 4 publications

References 9 publications

Stability of a Subcritical Fluid Model for Fair Bandwidth Sharing with General File Size Distributions

Stability of a Subcritical Fluid Model for Fair Bandwidth Sharing with General File Size Distributions

Asymptotic behavior of a critical fluid model for a multiclass processor sharing queue via relative entropy

Asymptotic behavior of a critical fluid model for bandwidth sharing with general file size distributions

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