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A Diffusion Approximation for the G/GI/n/m Queue

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  • Ward Whitt

    (Department of Industrial Engineering and Operations Research, Columbia University, New York, New York 10027-6699)

Abstract

We develop a diffusion approximation for the queue-length stochastic process in the G/GI/n/m queueing model (having a general arrival process, independent and identically distributed service times with a general distribution, n servers, and m extra waiting spaces). We use the steady-state distribution of that diffusion process to obtain approximations for steady-state performance measures of the queueing model, focusing especially upon the steady-state delay probability. The approximations are based on heavy-traffic limits in which n tends to infinity as the traffic intensity increases. Thus, the approximations are intended for large n .For the GI/M/n/ ∞ special case, Halfin and Whitt (1981) showed that scaled versions of the queue-length process converge to a diffusion process when the traffic intensity ρ n approaches 1 with (1 – ρ n )√ n → β for 0 β G/GI/n/m n models in which the number of waiting places depends on n and the service-time distribution is a mixture of an exponential distribution with probability p and a unit point mass at 0 with probability 1 – p . Finite waiting rooms are treated by incorporating the additional limit m n /√n → κ for 0 κ ≤ ∞. The approximation for the more general G/GI/n/m model developed here is consistent with those heavy-traffic limits. Heavy-traffic limits for the GI/PH/n/ ∞ model with phase-type service-time distributions established by Puhalskii and Reiman (2000) imply that our approximating process is not asymptotically correct for nonexponential phase-type service-time distributions, but nevertheless, the heuristic diffusion approximation developed here yields useful approximations for key performance measures such as the steady-state delay probability. The accuracy is confirmed by making comparisons with exact numerical results and simulations.

Suggested Citation

  • Ward Whitt, 2004. "A Diffusion Approximation for the G/GI/n/m Queue," Operations Research, INFORMS, vol. 52(6), pages 922-941, December.
  • Handle: RePEc:inm:oropre:v:52:y:2004:i:6:p:922-941
    DOI: 10.1287/opre.1040.0136
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    References listed on IDEAS

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    1. Toshikazu Kimura, 2002. "Diffusion Approximations for Queues with Markovian Bases," Annals of Operations Research, Springer, vol. 113(1), pages 27-40, July.
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    8. Mor Armony & Constantinos Maglaras, 2004. "On Customer Contact Centers with a Call-Back Option: Customer Decisions, Routing Rules, and System Design," Operations Research, INFORMS, vol. 52(2), pages 271-292, April.
    9. Ward Whitt, 1992. "Understanding the Efficiency of Multi-Server Service Systems," Management Science, INFORMS, vol. 38(5), pages 708-723, May.
    10. Ward Whitt, 1984. "Departures from a Queue with Many Busy Servers," Mathematics of Operations Research, INFORMS, vol. 9(4), pages 534-544, November.
    11. Sem Borst & Avi Mandelbaum & Martin I. Reiman, 2004. "Dimensioning Large Call Centers," Operations Research, INFORMS, vol. 52(1), pages 17-34, February.
    12. Otis B. Jennings & Avishai Mandelbaum & William A. Massey & Ward Whitt, 1996. "Server Staffing to Meet Time-Varying Demand," Management Science, INFORMS, vol. 42(10), pages 1383-1394, October.
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    Cited by:

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    4. Anatoly Nazarov & Alexander Moiseev & Svetlana Moiseeva, 2021. "Mathematical Model of Call Center in the Form of Multi-Server Queueing System," Mathematics, MDPI, vol. 9(22), pages 1-13, November.
    5. J. G. Dai & Tolga Tezcan, 2011. "State Space Collapse in Many-Server Diffusion Limits of Parallel Server Systems," Mathematics of Operations Research, INFORMS, vol. 36(2), pages 271-320, May.
    6. V. S. Koroliuk & V. V. Koroliuk & N. Limnios, 2009. "Queuing Systems with Semi-Markov Flow in Average and Diffusion Approximation Schemes," Methodology and Computing in Applied Probability, Springer, vol. 11(2), pages 201-209, June.
    7. J B Atkinson, 2009. "Two new heuristics for the GI/G/n/0 queueing loss system with examples based on the two-phase Coxian distribution," Journal of the Operational Research Society, Palgrave Macmillan;The OR Society, vol. 60(6), pages 818-830, June.
    8. Ward Whitt, 2005. "Heavy-Traffic Limits for the G / H 2 */ n / m Queue," Mathematics of Operations Research, INFORMS, vol. 30(1), pages 1-27, February.
    9. Raj, G. & Roy, D. & de Koster, R. & Bansal, V., 2024. "Stochastic modeling of integrated order fulfillment processes with delivery time promise: Order picking, batching, and last-mile delivery," European Journal of Operational Research, Elsevier, vol. 316(3), pages 1114-1128.
    10. Avishai Mandelbaum & Petar Momčilović, 2008. "Queues with Many Servers: The Virtual Waiting-Time Process in the QED Regime," Mathematics of Operations Research, INFORMS, vol. 33(3), pages 561-586, August.
    11. Yunan Liu & Ward Whitt & Yao Yu, 2016. "Approximations for heavily loaded G/GI/n + GI queues," Naval Research Logistics (NRL), John Wiley & Sons, vol. 63(3), pages 187-217, April.
    12. Tolga Tezcan, 2008. "Optimal Control of Distributed Parallel Server Systems Under the Halfin and Whitt Regime," Mathematics of Operations Research, INFORMS, vol. 33(1), pages 51-90, February.

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