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ANALYSIS OF THE NETWORK WITH MULTIPLE CLASSES OF POSITIVE AND NEGATIVE CUSTOMERS AT A TRANSIENT REGIME

Published online by Cambridge University Press:  10 April 2018

Mikhail Matalytski*
Affiliation:
Institute of Mathematics, Czestochowa University of Technology, Czestochowa, Poland E-mail: [email protected]

Abstract

This paper is devoted to the investigation of the G-network with multiple classes of positive and negative customers. The purpose of the investigation is to analyze such a network at a transient regime, to find the state probabilities of the network that depend on time. In the first part, a description of the functioning of G-networks with positive and negative customers is provided, when a negative customer when arriving to the system destroys a positive customer of its class. Streams of positive and negative customers arriving at each of the network systems are independent. Services of positive customers of all types occur in accordance with a random selection of them for service. For nonstationary probabilities of network states, a system of Kolmogorov's difference-differential equations (DDE) has been derived. A method for their finding is proposed. It is based on the use of a modified method of successive approximations, combined with the method of series. It is proved that successive approximations converge with time to a stationary probability distribution, the form of which is indicated in this paper, and the sequence of approximations converges to the unique solution of the DDE system. Any successive approximation is representable in the form of a convergent power series with an infinite radius of convergence, the coefficients of which satisfy recurrence relations, which is convenient for computer calculations. A model example illustrating the determination of the time-dependent probabilities of network states using this technique has been calculated. The obtained results can be applied in modeling the behavior of computer viruses and attacks in information and telecommunication systems and networks, for example, as a model of the impact of some file viruses on server resources. variable.

Type
Research Article
Copyright
Copyright © Cambridge University Press 2018 

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References

1.Gelenbe, E. (1991). Product form queueing networks with negative and positive customers. Journal of Applied Probability, 28: 656663.Google Scholar
2.Gelenbe, E. & Schassberger, R. (1992). Stability of G-networks. Probability in the Engineering and Informational Sciences, 6(1): 271276.Google Scholar
3.Gelenbe, E. (1994). G-networks: a unifying model for neural and queueing networks. Annals of Operations Research, 48: 433461.Google Scholar
4.Fourneau, J.N., Gelenbe, E. & Suros, R. (1996). G-networks with multiple classes of negative and positive customers. Theoretical Computer Science, 155: 141156.Google Scholar
5.Gelenbe, E., Labed, A. (1998). G-networks with multiple classes of signals and positive customers. European Journal of Operations Research, 108(2): 293305.Google Scholar
6.Matalytski, M. (2017). Finding non-stationary state probabilities of G-network with signal and customers batch removal. Probability the Engineering and Informational Sciences, 31(4): 396412.Google Scholar
7.Gelenbe, E. (1993). G-Networks with signals and batch removal. Probability in the Engineering and Informational Sciences, 7: 335342.Google Scholar
8.Gelenbe, E. (1993). G-networks with instantaneous customer movement. Journal of Applied Probability, 30(3): 742748.Google Scholar
9.Gelenbe, E. (2007). Steady-state solution of probabilistic gene regulatory networks. Physical Review, 76: 031903.Google Scholar