Dynamic Routing in Large-Scale Service Systems with Heterogeneous Servers
Queueing Systems: Theory and Applications
How many servers are best in a dual-priority M/PH/k system?
Performance Evaluation
Performance Evaluation
Queueing Systems: Theory and Applications
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In this paper we establish the weakest known sufficient conditions for the existence of stationary delay moments in FIFOGI/GI/s queues, fors = 2. These conditions involve not only the service time distribution, as in the classic Kiefer and Wolfowitz conditions, but also the interplay of the traffic intensity and the number of servers in the queue. We then prove the necessity of our conditions for a large class of service times having finite first, but infinite ath, moment for some finite a. Such service time distributions include many, but not all of, the class of heavy-tailed distributions: The Pareto and Cauchy are members; the Weibull is not.Our results are then applied to provide one answer to the classic question: When ares slow servers (operating at rate 1 /s) better than one fast server (operating at rate 1)? We consider this question with respect to the rate of decay of the tail of stationary customer delay. In a system characterized by service times that have finite mean but lack some higher moments, such as are often used to model telecommunications traffic, fors greater than a traffic-related constant, the answer isalways. Our results help to quantify the benefits of extra servers, while also pointing the way towards the derivation of bounds and asymptotics for the stationary delay distribution of multiserver queues having these types of service times. Such queues are attracting a great deal of academic research, motivated by their practical use modeling telecommunications systems.