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A Globally Gated Polling System with a Dormant Server

Published online by Cambridge University Press:  27 July 2009

S. C. Borst
S. C. Borst
Affiliation:
CWI, P.O. Box 94079, 1090 GB Amsterdam, The Netherlands
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Abstract

We study a globally gated polling system with a dormant server, which makes a halt at its home base when there are no customers present in the system. We derive an explicit expression for the cycle time distribution as well as for the waiting-time distribution at each of the queues. As a justification of the dormant server policy, we show the waiting time at each of the queues to be smaller (in the increasing-convex-ordering sense) than in the ordinary nondormant server case.

Type
Research Article
Information
Probability in the Engineering and Informational Sciences , Volume 9 , Issue 2 , April 1995 , pp. 239 - 254
Copyright
Copyright © Cambridge University Press 1995

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References

1.Sarkar, D. & Zangwill, W.I. (1991). Variance effects in cyclic production systems. Management Science 37: 444453.CrossRefGoogle Scholar
2.Altman, E., Konstantopoulos, P., & Liu, Z. (1992). Stability, monotonicity and invariant quantities in general polling systems. Queueing Systems 11 (Special Issue on Polling Models): 3557.CrossRefGoogle Scholar
3.Blanc, J.P.C. & Van der Mei, R.D. (1994). The power-series algorithm applied to polling systems with a dormant server. In Labetoulle, J. & Roberts, J.W. (eds.), The fundamental role of teletraffic in the evolution of telecommunications networks, Proceedings of ITC 14. Amsterdam: North-Holland, pp. 865874.Google Scholar
4.Borst, S.C. (1993). A polling system with a dormant server. Report BS-R9313. CWI, Amsterdam.Google Scholar
5.Borst, S.C. (1994). A pseudo-conservation law for a polling system with a dormant server. In Labetoulle, J. & Roberts, J.W. (eds.), The fundamental role of teletraffic in the evolution of telecommunications networks, Proceedings of ITC 14. Amsterdam: North-Holland, pp. 729742.Google Scholar
6.Boxma, O.J., Levy, H., & Yechiali, U. (1992). Cyclic reservation schemes for efficient operation of multiple-queue single-server systems. Annals of Operations Research 35: 187208.CrossRefGoogle Scholar
7.Boxma, O.J., Weststrate, J.A., & Yechiali, U. (1993). A globally gated polling system with server interruptions, and applications to the repairman problem. Probability in the Engineering and Informational Sciences 7: 187208.CrossRefGoogle Scholar
8.Cohen, J.W. (1982). The single server queue, 2nd ed.Amsterdam: North-Holland.Google Scholar
9.Eisenberg, M. (1971). Two queues with changeover times. Operations Research 19: 386401.CrossRefGoogle Scholar
10.Eisenberg, M. (1972). Queues with periodic service and changeover times. Operations Research 20: 440451.CrossRefGoogle Scholar
11.Eisenberg, M. (1994). The polling system with a stopping server. Queueing Systems 18: 387431.CrossRefGoogle Scholar
12.Gersht, A.M. & Marbukh, V.V. (1975). Queueing systems with readjustment. Engineering Cybernetics 13: 5565.Google Scholar
13.Srinivasan, M.M. & Gupta, D. (1993). When should a roving server be patient? Report, University of Tennessee, Knoxville.Google Scholar
14.Keilson, J. & Servi, L.D. (1990). The distributional form of Little's law and the Fuhrmann-Cooper decomposition. Operations Research Letters 9: 239247.CrossRefGoogle Scholar
15.Levy, H. & Sidi, M. (1990). Polling systems: Applications, modelling and optimization. IEEE Transactions on Communications 38: 17501760.CrossRefGoogle Scholar
16.Levy, H., Sidi, M., & Boxma, O.J. (1990). Dominance relations in polling systems. Queueing Systems 6: 155171.CrossRefGoogle Scholar
17.Liu, Z., Nain, P., & Towsley, D. (1992). On optimal polling policies. Queueing Systems 11 (Special Issue on Polling Models): 5983.CrossRefGoogle Scholar
18.Resing, J.A.C. (1993). Polling systems and multitype branching processes. Queueing Systems 13: 409426.CrossRefGoogle Scholar
19.Takagi, H. (1986). Analysis of polling systems. Cambridge, MA: The MIT Press.Google Scholar
20.Takagi, H. (1990). Queueing analysis of polling models: An update. In Takagi, H. (ed.), Stochastic analysis of computer and communication systems. Amsterdam: North-Holland, pp. 267318.Google Scholar
21.Takagi, H. (1991). Queueing analysis. Vol. 1. Amsterdam: North-Holland.Google Scholar
22.Takine, T. & Hasegawa, T. (1992). On the M/C/1 queue with multiple vacations and gated service discipline. Journal of the Operations Research Society of Japan 35: 217235.CrossRefGoogle Scholar