Sensitivity analysis of a single server finite-source retrial queueing system with two-way communication and catastrophic breakdown using simulation

IF 0.3 Q4 MATHEMATICS
J. Sztrik, Á. Tóth
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Abstract

. In this paper, a finite-source retrial queueing system with two-way communication is investigated with the help of a simulation program of own. If a randomly arriving request from the finite-source finds the single server idle its service starts immediately, otherwise it joins an orbit from where it generates retrial/repeated calls after a random time. To increase the utilization of the server when it becomes idle after a random time an outgoing request is called for service from an infinity source. Upon its arrival if the server is busy, it goes to a buffer and when the server becomes idle again its service starts immediately. requests arriving from the finite-source and orbit are referred to as primary or incoming ones while requests called from the infinite source are referred to as secondary or outgoing requests, respectively. The service times of the primary and secondary requests are supposed to be random variables having different distributions. However, randomly catastrophic failures may happen to all the requests in the system, that is from the orbit, the service unit, and the buffer. In this case, the primary requests return to the finite-source, and the secondary ones are lost. The operation of the system is restored after a random time. Until the restoration is finished no arrivals and service take place in the system. All the above-mentioned times are supposed to be independent random variables. The novelty of this paper is to perform a sensitivity analysis of the failure and restoration/repair times on the main characteristics to illustrate the effect of different distributions having the same average and variance value. Our
基于仿真的单服务器有限源双向通信重审排队系统的灵敏度分析
. 本文利用自己编写的仿真程序,研究了一种具有双向通信的有限源重试排队系统。如果来自有限源的随机到达的请求发现单个服务器空闲,则其服务立即启动,否则它将加入一个轨道,在随机时间后生成重试/重复调用。当服务器在随机时间后空闲时,从无限源调用传出请求以获取服务,从而提高服务器的利用率。当它到达服务器时,如果服务器很忙,它将进入缓冲区,当服务器再次空闲时,它的服务立即启动。从有限源和轨道到达的请求分别称为主请求或传入请求,而从无限源调用的请求分别称为辅助请求或传出请求。主请求和辅助请求的服务时间应该是具有不同分布的随机变量。但是,系统中的所有请求,即来自轨道、服务单元和缓冲区的请求,都可能发生随机的灾难性故障。在这种情况下,主要请求返回到有限源,而次要请求丢失。系统在一段随机时间后恢复运行。在恢复完成之前,系统中不会发生任何到达和服务。上述时间都是独立的随机变量。本文的新颖之处在于对故障和恢复/修理时间对主要特征的敏感性分析,以说明具有相同平均值和方差值的不同分布的影响。我们的
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CiteScore
0.90
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0.00%
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0
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