NUMERICAL ANALYSIS OF SHORTEST QUEUE PROBLEM FOR TIME-SCALE QUEUEING SYSTEM WITH A SMALL PARAMETER

In this paper we apply numerical methods for analysis of the timescale queueing systems (TSQS) evolution dynamics under the the assumption that the number of single-services tends to infinity. We suppose that TSQS implements a service discipline so that for each incoming request is provided a random selection a server from random selected m-set servers that has the s-th shortest queue size. The evolution dynamics TSQS can be describe using the function that can be found by solving a system of differential equations infinite degree. We formulate the singularly perturbed Cauchy problem for this system of differential equations with a small parameter. We use the truncation procedure for this singularly perturbed Cauchy problem and formulate the finite order system of differential equations. We apply a high-order non-uniform grid scheme for numerical solving of the truncated Cauchy problem. We use different sets of small parameters for time-scaling processes analysis for TSQS. The grid scheme demonstrates good convergence of solutions of the singularly perturbed Cauchy problem when a small parameter tend to zero. The results of the numerical simulation show that this TSQS can hold with a high incoming flow of requests.

Язык
Английский
Страницы
105-110
Статус
Опубликовано
Год
2023
Организации
  • 1 Peoples' Friendship University of Russia
Ключевые слова
shortest queue problem; countable Markov chains; time-scale network analysis; singular perturbed infinite systems of differential equations; stability analysis for infinite systems of differential equations with a small parameter; numerical analysis of the Cauchy problem; layer-adapted piecewise uniform Shishkin-type meshes
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