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Large deviations and overflow probabilities for the general single-server queue, with applications

Published online by Cambridge University Press:  24 October 2008

N. G. Duffield  and
Neil O'connell
N. G. Duffield
Affiliation:
School of Mathematical Sciences, Dublin City University, Dublin 9, Ireland. e-mail: [email protected]
Neil O'connell
Affiliation:
Dublin Institute for Advanced Studies, 10 Burlington Road, Dublin 4, Ireland. e-mail: [email protected]
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Abstract

We consider queueing systems where the workload process is assumed to have an associated large deviation principle with arbitrary scaling: there exist increasing scaling functions (at, vt, tR+) and a rate function I such that if (Wt, tR+) denotes the workload process, then

on the continuity set of I. In the case that at = vt = t it has been argued heuristically, and recently proved in a fairly general context (for discrete time models) by Glynn and Whitt[8], that the queue-length distribution (that is, the distribution of supremum of the workload process Q = supt≥0Wt) decays exponentially:

and the decay rate δ is directly related to the rate function I. We establish conditions for a more general result to hold, where the scaling functions are not necessarily linear in t: we find that the queue-length distribution has an exponential tail only if limt→∞at/vt is finite and strictly positive; otherwise, provided our conditions are satisfied, the tail probabilities decay like

Type
Research Article
Information
Mathematical Proceedings of the Cambridge Philosophical Society , Volume 118 , Issue 2 , September 1995 , pp. 363 - 374
Copyright
Copyright © Cambridge Philosophical Society 1995

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References

REFERENCES

[1]Milton, Abramowitz and Stegun, Irene A. (eds.) Handbook of mathematical functions (Dover, 1965).Google Scholar
[2]David, Aldous. Probability approximations via the Poisson clumping heuristic (Springer-Verlag, 1989).Google Scholar
[3]Borovkov, A. A.. Asymptotic methods in queueing theory. (Wiley, 1984).Google Scholar
[4]Cheng-Shang, Chang. Stability, queue length and delay of deterministic and stochastic queueing networks. IEEE Trans. on Automatic Control 39 (1994), 913931.Google Scholar
[5]Kulkarni, V. and Rolski, T.. Fluid model driven by an Ornstein-Uhlenbeck process (preprint).Google Scholar
[6]Amir, Dembo and Ofer, Zeitoüni. Large deviation techniques and applications (Jones and Bartlett, 1993).Google Scholar
[7]Duffield, N. G.. Exponential bounds for queues with Markovian arrivals. Queueing Systems 17 (1994), 413430CrossRefGoogle Scholar
[8]Glynn, Peter W. and Ward, Whitt. Logarithmic asymptotics for steady-state tail probabilities in a single-server queue. J. Appl. Prob. 31A (1994), 131159CrossRefGoogle Scholar
[9]Kesidis, G., Walrand, J. and Chang, C. S.. Effective bandwidths for multiclass Markov fluids and other ATM Sources. IEEE/ACH Trans. Networking 1 (1993), 424428.CrossRefGoogle Scholar
[10]Leland, Will E., Taqqu, Murad S., Walter, Willinger and Wilson, Daniel V.. On the self-similar nature of Ethernet traffic. ACM SIOCOMM Computer Communications Review 23 (1993), 183193.CrossRefGoogle Scholar
[11]Lewis, J. T. and Pfister, C. E.. Thermodynamic probability theory: some aspects of large deviations. Theor. Prob. Appl, (to appear).Google Scholar
[12]Torgny, Lindvall. Lectures on the coupling method (Wiley, 1992).Google Scholar
[13]Mandelbrot, Benoit B. and Van Ness, John W.. Fractional Brownian motions, fractional noises and applications. SIAM Review 10 (1968), 422437.Google Scholar
[14]Marcus, M. B. and Shepp, L. A.. Sample behaviour of Gaussian processes. Proceedings of the Sixth Berkeley Symposium (1972).Google Scholar
[15]Ilkka, Norros. Studies on a model for connectionless traffic, based on fractional Brownian motion. Conference on Applied Probability in Engineering, Computer and communication sciences INRIA/ORSA/TIMS/SMAI, Paris 1993.Google Scholar
[16]Ilkka, Norros. A storage model with self-similar input. Queueing Systems 16 (1994), 387396.Google Scholar
[17]Norros, I., Roberts, J. W., Simonain, A. and Virtamo, J.. The superposition of variable bitrate sources in ATM multiplexers. IEEE J. Selected Areas in Commun. 9 (1991), 378387.CrossRefGoogle Scholar
[18]Jim, Pitman and Marc, Yor. A decomposition of Bessel bridges. Z. Wahr. verw. Gebeit 59 (1982), 425457.Google Scholar