Service life of many real-life systems cannot be considered infinite, and thus the systems will be eventually stopped or will break down. Some of them may be re-launched after possible maintenance under likely new initial conditions. In such systems, which are often modelled by birth and death processes, the assumption of stationarity may be too strong and performance characteristics obtained under this assumption may not make much sense. In such circumstances, timedependent analysis is more meaningful. In this paper, transient analysis of one class of Markov processes defined on non-negative integers, specifically, inhomogeneous birth and death processes allowing special transitions from and to the origin, is carried out. Whenever the process is at the origin, transition can occur to any state, not necessarily a neighbouring one. Being in any other state, besides ordinary transitions to neighbouring states, a transition to the origin can occur. All possible transition intensities are assumed to be non-random functions of time and may depend (except for transition to the origin) on the process state. To the best of our knowledge, first ergodicity and perturbation bounds for this class of processes are obtained. Extensive numerical results are also provided.
@article{bwmeta1.element.bwnjournal-article-amcv25i4p787bwm, author = {Alexander Zeifman and Anna Korotysheva and Yacov Satin and Victor Korolev and Sergey Shorgin and Rostislav Razumchik}, title = {Ergodicity and perturbation bounds for inhomogeneous birth and death processes with additional transitions from and to the origin}, journal = {International Journal of Applied Mathematics and Computer Science}, volume = {25}, year = {2015}, pages = {787-802}, language = {en}, url = {http://dml.mathdoc.fr/item/bwmeta1.element.bwnjournal-article-amcv25i4p787bwm} }
Alexander Zeifman; Anna Korotysheva; Yacov Satin; Victor Korolev; Sergey Shorgin; Rostislav Razumchik. Ergodicity and perturbation bounds for inhomogeneous birth and death processes with additional transitions from and to the origin. International Journal of Applied Mathematics and Computer Science, Tome 25 (2015) pp. 787-802. http://gdmltest.u-ga.fr/item/bwmeta1.element.bwnjournal-article-amcv25i4p787bwm/
[000] Chen, A., Pollett, P., Li, J. and Zhang, H. (2010). Markovian bulk-arrival and bulk-service queues with state-dependent control, Queueing Systems 64(3): 267-304. | Zbl 1186.60094
[001] Chen, A. and Renshaw, E. (1997). The m|m|1 queue with mass exodus and mass arrives when empty, Journal of Applied Probability 34(1): 192-207. | Zbl 0876.60079
[002] Chen, A. and Renshaw, E. (2004). Markov bulk-arriving queues with state-dependent control at idle time, Advances in Applied Probability 36(2): 499-524. | Zbl 1046.60080
[003] Daleckij, J. and Krein, M. (1975). Stability of solutions of differential equations in Banach space, Bulletin of the American Mathematical Society 81(6): 1024-102.
[004] Gaidamaka, Y., Pechinkin, A., Razumchik, R., Samouylov, K. and Sopin, E. (2014). Analysis of an M/G/1/R queue with batch arrivals and two hysteretic overload control policies, International Journal of Applied Mathematics and Computer Science 24(3): 519-534, DOI: 10.2478/amcs-2014-0038. | Zbl 1322.60190
[005] Granovsky, B. and Zeifman, A. (2004). Nonstationary queues: Estimation of the rate of convergence, Queueing Systems 46(3-4): 363-388. | Zbl 1056.90030
[006] Li, J. and Chen, A. (2013). The decay parameter and invariant measures for Markovian bulk-arrival queues with control at idle time, Methodology and Computing in Applied Probability 15(2): 467-484. | Zbl 1270.60102
[007] Parthasarathy, P. and Kumar, B.K. (1991). Density-dependent birth and death processes with state-dependent immigration, Mathematical and Computer Modelling 15(1): 11-16. | Zbl 0721.92019
[008] Van Doorn, E., Zeifman, A. and Panfilova, T. (2010). Bounds and asymptotics for the rate of convergence of birth-death processes, Theory of Probability and Its Applications 54(1): 97-113. | Zbl 1204.60083
[009] Zeifman, A. (1995). Upper and lower bounds on the rate of convergence for nonhomogeneous birth and death processes, Stochastic Processes and Their Applications 59(1): 157-173. | Zbl 0846.60084
[010] Zeifman, A., Bening, V. and Sokolov, I. (2008). ContinuousTime Markov Chains and Models, Elex-KM, Moscow.
[011] Zeifman, A. and Korolev, V. (2014). On perturbation bounds for continuous-time Markov chains, Statistics & Probability Letters 88(1): 66-72. | Zbl 1296.60205
[012] Zeifman, A. and Korotysheva, A. (2012). Perturbation bounds for Mt /Mt /N queue with catastrophes, Stochastic Models 28(1): 49-62. | Zbl 1243.60076
[013] Zeifman, A., Korotysheva, A., Satin, Y. and Shorgin, S. (2010). On stability for nonstationary queueing systems with catastrophes, Informatics and Its Applications 4(3): 9-15.
[014] Zeifman, A., Leorato, S., Orsingher, E., Satin, Y. and Shilova, G. (2006). Some universal limits for nonhomogeneous birth and death processes, Queueing Systems 52(2): 139-151. | Zbl 1119.60071
[015] Zeifman, A., Satin, Y., Korolev, V. and Shorgin, S. (2014). On truncations for weakly ergodic inhomogeneous birth and death processes, International Journal of Applied Mathematics and Computer Science 24(3): 503-518, DOI: 10.2478/amcs-2014-0037. | Zbl 1322.60184