Sufficient stability conditions for multi-class constant retrial rate systems

Avrachenkov, Konstantin; Morozov, Evsey; Steyaert, Bart

doi:10.1007/s11134-015-9463-9

Cited by 32 publications

(29 citation statements)

References 29 publications

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“…Altman and Yechiali 18 study a closed polling model in which all customers finished service at a queue would proceed to another (possibly the same) queue but not leave. Several one‐server queue models with retrial are present 19–21 . However, this paper did not consider a polling setting.…”

Section: Related Workmentioning

confidence: 99%

“…Several one-server queue models with retrial are present. [19][20][21] However, this paper did not consider a polling setting. Sidi and Levy 22 consider a system in which (external) customers arrive at a queue according to a Poisson process and in which a customer, after having received service at a queue, either leaves the system or moves to another queue (with some given probability).…”

Section: Related Workmentioning

confidence: 99%

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Performance analysis of polling‐based MAC protocol with retrial for Internet of Things

Guan

Xiong

et al. 2019

Concurrency and Computation

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Summary We consider and analyze a single‐server multiqueue polling model with inner arrivals. Customers arriving at the queue before polling instant could receive service in the current polling round; furthermore, each one could be retried (turns into an inner arrival) a given number of times with a specified probability. Such polling model can be used to study the performance of certain scheduling data transmission in the Internet of Things (IoT) and the relationship between data retransmission and delay. We obtain the closed‐form expression for the generating function of the amount of customers, which are presented at polling instants. Then, it is used to derive the precise closed‐form formula of mean queue length and mean waiting time in symmetric system.

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Section: Related Workmentioning

confidence: 99%

Section: Related Workmentioning

confidence: 99%

Performance analysis of polling‐based MAC protocol with retrial for Internet of Things

Guan

Xiong

et al. 2019

Concurrency and Computation

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“…We note that a probabilistic interpretation can be given for the parameter p(1): it denotes the joint probability that the system contains exactly one customer and the next customer to enter service has the opposite type as the customer in service. It now remains for us to determine the two remaining unknowns p(0) and p (1). A first relation between p(0) and p(1) can be obtained from the normalization condition of the system-content distribution, i.e., the condition U (1) = 1.…”

Section: Steady-state Analysis Of the System Contentmentioning

confidence: 99%

“…Classical multi-class queueing models deal with situations where multiple types (or classes) of customers compete for the use of the same resources; see, e.g., [11,2,19,16,27,25,1,3] for some recent examples in various application areas. Usually, the resources to be shared are the facilities that are able to deliver the requested services to the customers, or, in queueing language, the "servers" of the queueing system.…”

Section: Introduction and Mathematical Modelmentioning

confidence: 99%

Performance analysis of a discrete-time two-class global-FCFS queue with two servers and geometric service times

Bruneel

Mlange

Walraevens

et al. 2017

Performance Evaluation

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In this paper, we analyze a discrete-time queueing model with two types (classes) of customers and two servers, one for each customer class. Although each server can only process one type of customers, all customers are accommodated in one single queue and served in their order of arrival, irrespective of their types. The numbers of customers arriving in the system from time slot to time slot are independent, but the types of consecutive customers are not necessarily independent. Specifically, we assume that a first-order Markovian correlation ("interclass correlation") exists between the types of subsequent customers in the arrival stream. The fact that multiple customers of the same type may arrive back-to-back and customers have to be served in their order of arrival, causes occasional under-utilization of the service capacity of the system, because some customers may not be able to reach their server owing to the presence of customers of the opposite type in front of them.In this paper, we assume that the service times of both types of customers are independent, geometrically distributed random variables. The paper extends earlier work where all the service times were assumed to be of fixed length, either equal to 1 slot each, or equal to multiple slots. The fact that, in the present paper, service times are of variable length, entails that customers being served simultaneously can overtake each other, thus disturbing the original arrival order. This phenomenon did not occur in previous studies with fixed-length service times, and represents the main new element of the paper. It also complicates the analysis of the system considerably. Nevertheless, we are able to derive explicit expressions for the probability generating functions and the mean values of the main performance measures of the system, in terms of the original system parameters and one root of a non-linear equation. Our results reveal the impact of the interclass correlation and the variable nature of the service times on the achievable throughput, the (mean) number of customers in the system, the (mean) customer sojourn times, the (mean) unfinished work in the system, and related quantities.

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“…Expected waiting time expressions are given for two-and multi-class M/G/1 queues with batch arrivals and exponential retrials in [34] and [25], respectively. Avrachenkov et al [7] considered an M/G/c queue with waiting lines and constant retrial policy in which only one customer in the orbit can attempt to get service. Shin and Moon [47] showed that the stationary distribution of a multiclass M/M/c queue with exponential retrials converges to that of a classical multiclass M/M/c queue with discriminatory random order service policy as retrial rates tend to ∞, and they presented approximation formulae for some performance measures.…”

Section: Introductionmentioning

confidence: 99%

Steady-state analysis of a multiclass MAP/PH/cqueue with acyclic PH retrials

Dayar

Orhan

2016

J. Appl. Probab.

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A multiclass c-server retrial queueing system in which customers arrive according to a class-dependent Markovian arrival process (MAP) is considered. Service and retrial times follow class-dependent phase-type (PH) distributions with the further assumption that PH distributions of retrial times are acyclic. A necessary and sufficient condition for ergodicity is obtained from criteria based on drifts. The infinite state space of the model is truncated with an appropriately chosen Lyapunov function. The truncated model is described as a multidimensional Markov chain, and a Kronecker representation of its generator matrix is numerically analyzed.

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Sufficient stability conditions for multi-class constant retrial rate systems

Cited by 32 publications

References 29 publications

Performance analysis of polling‐based MAC protocol with retrial for Internet of Things

Performance analysis of polling‐based MAC protocol with retrial for Internet of Things

Performance analysis of a discrete-time two-class global-FCFS queue with two servers and geometric service times

Steady-state analysis of a multiclass MAP/PH/cqueue with acyclic PH retrials

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