Many-server diffusion limits for G/Ph/n+GI queues

Many-server diffusion limits for G/Ph/n+GI queues

J. G. Dai, Shuangchi He, and Tolga Tezcan

Source: Ann. Appl. Probab. Volume 20, Number 5 (2010), 1854-1890.

Abstract

This paper studies many-server limits for multi-server queues that have a phase-type service time distribution and allow for customer abandonment. The first set of limit theorems is for critically loaded G/Ph/n+GI queues, where the patience times are independent and identically distributed following a general distribution. The next limit theorem is for overloaded G/Ph/n+M queues, where the patience time distribution is restricted to be exponential. We prove that a pair of diffusion-scaled total-customer-count and server-allocation processes, properly centered, converges in distribution to a continuous Markov process as the number of servers n goes to infinity. In the overloaded case, the limit is a multi-dimensional diffusion process, and in the critically loaded case, the limit is a simple transformation of a diffusion process. When the queues are critically loaded, our diffusion limit generalizes the result by Puhalskii and Reiman (2000) for GI/Ph/n queues without customer abandonment. When the queues are overloaded, the diffusion limit provides a refinement to a fluid limit and it generalizes a result by Whitt (2004) for M/M/n/+M queues with an exponential service time distribution. The proof techniques employed in this paper are innovative. First, a perturbed system is shown to be equivalent to the original system. Next, two maps are employed in both fluid and diffusion scalings. These maps allow one to prove the limit theorems by applying the standard continuous-mapping theorem and the standard random-time-change theorem.

First Page: Show

Primary Subjects: 90B20, 68M20, 60J70

Keywords: Multi-server queues; customer abandonment; many-server heavy traffic; Halfin–Whitt regime; quality and efficiency-driven regime; efficiency-driven regime; phase-type distribution

Full-text: Access denied (no subscription detected)

We're sorry, but we are unable to provide you with the full text of this article because we are not able to identify you as a subscriber.

If you have a personal subscription to this journal, then please login. If you are already logged in, then you may need to update your profile to register your subscription. Read more about accessing full-text

Links and Identifiers

Permanent link to this document: http://projecteuclid.org/euclid.aoap/1282747403
Digital Object Identifier: doi:10.1214/09-AAP674
Zentralblatt MATH identifier: 05795073
Mathematical Reviews number (MathSciNet): MR2724423

back to Table of Contents

References

Billingsley, P. (1999). Convergence of Probability Measures, 2nd ed. Wiley, New York.

Mathematical Reviews (MathSciNet): MR1700749

Borovkov, A. A. (1967). On limit laws for service processes in multi-channel systems. Sibirsk. Mat. J. 8 746–763.

Mathematical Reviews (MathSciNet): MR222973

Dai, J. G. and He, S. (2010). Customer abandonment in many-server queues. Math. Oper. Res. 35 347–362.

Dai, J. G. and Tezcan, T. (2005). State space collapse in many-server diffusion limits of parallel server systems in many-server limits. Preprint. Available at http://www2.isye.gatech.edu/~dai/publications/ssc_mor100324.pdf.

Dai, J. G. and Tezcan, T. (2008). Optimal control of parallel server systems with many servers in heavy traffic. Queueing Syst. 59 95–134.

Mathematical Reviews (MathSciNet): MR2430811

Digital Object Identifier: doi:10.1007/s11134-008-9078-5

Ethier, S. N. and Kurtz, T. G. (1986). Markov Processes: Characterization and Convergence. Wiley, New York.

Mathematical Reviews (MathSciNet): MR838085

Gamarnik, D. and Momčilović, P. (2008). Steady-state analysis of a multiserver queue in the Halfin–Whitt regime. Adv. in Appl. Probab. 40 548–577.

Garnett, O., Mandelbaum, A. and Reiman, M. (2002). Designing a call center with impatient customers. Manufacturing and Service Operations Management 4 208–227.

Halfin, S. and Whitt, W. (1981). Heavy-traffic limits for queues with many exponential servers. Oper. Res. 29 567–588.

Mathematical Reviews (MathSciNet): MR629195

Digital Object Identifier: doi:10.1287/opre.29.3.567

JSTOR: links.jstor.org

Iglehart, D. L. and Whitt, W. (1970). Multiple channel queues in heavy traffic. I. Adv. in Appl. Probab. 2 150–177.

Mathematical Reviews (MathSciNet): MR266331

Zentralblatt MATH: 0218.60098

Digital Object Identifier: doi:10.2307/3518347

JSTOR: links.jstor.org

Jelenković, P., Mandelbaum, A. and Momčilović, P. (2004). Heavy traffic limits for queues with many deterministic servers. Queueing Syst. 47 53–69.

Mathematical Reviews (MathSciNet): MR2074672

Digital Object Identifier: doi:10.1023/B:QUES.0000032800.52494.51

Johnson, D. P. (1983). Diffusion approximations for optimal filtering of jump processes and for queueing networks. Ph.D. thesis, Univ. Wisconsin.

Kang, W. N. and Ramanan, K. (2010). Fluid limits of many-server queues with reneging. Ann. Appl. Probab. To appear.

Karlin, S. and Taylor, H. M. (1981). A Second Course in Stochastic Processes. Academic Press, New York.

Mathematical Reviews (MathSciNet): MR611513

Zentralblatt MATH: 0469.60001

Kaspi, H. and Ramanan, K. (2010). Law of large numbers limits for many server queues. Ann. Appl. Probab. To appear.

Kiefer, J. and Wolfowitz, J. (1955). On the theory of queues with many servers. Trans. Amer. Math. Soc. 78 1–18.

Mathematical Reviews (MathSciNet): MR66587

Zentralblatt MATH: 0064.13303

Latouche, G. and Ramaswami, V. (1999). Introduction to Matrix Analytic Methods in Stochastic Modeling. SIAM, Philadelphia, PA.

Mathematical Reviews (MathSciNet): MR1674122

Zentralblatt MATH: 0922.60001

Mandelbaum, A., Massey, W. A. and Reiman, M. I. (1998). Strong approximations for Markovian service networks. Queueing Syst. 30 149–201.

Mathematical Reviews (MathSciNet): MR1663767

Digital Object Identifier: doi:10.1023/A:1019112920622

Mandelbaum, A. and Momčilović, P. (2009). Queues with many servers and impatient customers. Preprint. Available at http://iew3.technion.ac.il/serveng/References/MM0309.pdf.

Mandelbaum, A. and Pats, G. (1998). State-dependent stochastic networks. I. Approximations and applications with continuous diffusion limits. Ann. Appl. Probab. 8 569–646.

Mathematical Reviews (MathSciNet): MR1624965

Digital Object Identifier: doi:10.1214/aoap/1028903539

Project Euclid: euclid.aoap/1028903539

Pang, G., Talreja, R. and Whitt, W. (2007). Martingale proofs of many-server heavy-traffic limits for Markovian queues. Probab. Surv. 4 193–267.

Mathematical Reviews (MathSciNet): MR2368951

Zentralblatt MATH: 1189.60067

Digital Object Identifier: doi:10.1214/06-PS091

Project Euclid: euclid.ps/1200511983

Puhalskii, A. A. and Reed, J. E. (2010). On many-server queues in heavy traffic. Ann. Appl. Probab. 20 129–195.

Mathematical Reviews (MathSciNet): MR2582645

Zentralblatt MATH: 05678701

Digital Object Identifier: doi:10.1214/09-AAP604

Project Euclid: euclid.aoap/1262962320

Puhalskii, A. A. and Reiman, M. I. (2000). The multiclass GI/PH/N queue in the Halfin–Whitt regime. Adv. in Appl. Probab. 32 564–595.

Mathematical Reviews (MathSciNet): MR1778580

Zentralblatt MATH: 0962.60089

Digital Object Identifier: doi:10.1239/aap/1013540179

Project Euclid: euclid.aap/1013540179

Reed, J. (2009). The G/GI/N queue in the Halfin–Whitt regime. Ann. Appl. Probab. 19 2211–2269.

Mathematical Reviews (MathSciNet): MR2588244

Zentralblatt MATH: 1181.60137

Digital Object Identifier: doi:10.1214/09-AAP609

Project Euclid: euclid.aoap/1259158771

Reiman, M. I. (1984). Open queueing networks in heavy traffic. Math. Oper. Res. 9 441–458.

Mathematical Reviews (MathSciNet): MR757317

Zentralblatt MATH: 0549.90043

Digital Object Identifier: doi:10.1287/moor.9.3.441

JSTOR: links.jstor.org

Rogers, L. C. G. and Williams, D. (2000). Diffusions, Markov Processes, and Martingales. Cambridge Mathematical Library 2. Cambridge Univ. Press, Cambridge.

Stone, C. (1963). Limit theorems for random walks, birth and death processes, and diffusion processes. Illinois J. Math. 7 638–660.

Mathematical Reviews (MathSciNet): MR158440

Zentralblatt MATH: 0118.13202

Project Euclid: euclid.ijm/1255645101

Tezcan, T. (2006). State space collapse in many server diffusion limits of parallel server systems and applications. Ph.D. thesis, School of Industrial and Systems Engineering, Georgia Institute of Technology.

Tezcan, T. and Dai, J. G. (2010). Dynamic control of N-systems with many servers: Asymptotic optimality of a static priority policy in heavy traffic. Oper. Res. 58 94–110.

Whitt, W. (2002). Stochastic-Process Limits. Springer, New York.

Mathematical Reviews (MathSciNet): MR1876437

Zentralblatt MATH: 0993.60001

Whitt, W. (2004). Efficiency-driven heavy-traffic approximations for many-server queues with abandonments. Manag. Sci. 50 1449–1461.

Whitt, W. (2005). Heavy-traffic limits for the G/H₂*/n/m queue. Math. Oper. Res. 30 1–27.

Mathematical Reviews (MathSciNet): MR2125135

Zentralblatt MATH: 1082.90019

Digital Object Identifier: doi:10.1287/moor.1040.0119

Whitt, W. (2006). Fluid models for multiserver queues with abandonments. Oper. Res. 54 37–54.

Mathematical Reviews (MathSciNet): MR2201245

Zentralblatt MATH: 1167.90462

Digital Object Identifier: doi:10.1287/opre.1050.0227

Whitt, W. (2007). Proofs of the martingale FCLT. Probab. Surv. 4 268–302.

Mathematical Reviews (MathSciNet): MR2368952

Zentralblatt MATH: 1189.60070

Digital Object Identifier: doi:10.1214/07-PS122

Project Euclid: euclid.ps/1198788218

Zhang, J. (2009). Limited processor sharing queues and multi-server queues. Ph.D. thesis, School of Industrial and Systems Engineering, Georgia Institute of Technology.

previous :: next