An M/M/1 queueing system has that customers arrive to it at a rate of 5 per hour, i.e., its interarrival times between two consecutive arrivals follows an exponential distribution with parameter 5 per hour. This question will ask you to evaluate two options for designing the server in the system. Both options for the single server provide the same service for the customers in the queueing system but they cost different amounts to implement. In addition, the total costs of the queuing system are the implementation costs plus the customer costs. Currently, the customer costs are $100 per hour per customer in the queueing system. In comparing these options, it costs us $100 per hour per customer in the queueing system. (a) The first option for the server is one that has a service time that follows an exponential distribution with mean 10 minutes. Determine L, W, Lq, and Wq for this system. (b) The second option for the server is one that has a service time that follows an exponential distribution with mean 8 minutes. Determine L, W, Lq, and Wq for this system. (c) The first option will cost us $250 per hour to implement. The second option will cost us $600 per hour to implement. As mentioned earlier, the total costs of either option will be their implementation costs plus the customer costs. Using appropriate pieces of your results from (a) and (b), determine which option will have a lower total hourly cost to implement.
An M/M/1 queueing system has that customers arrive to it at a rate of 5 per hour, i.e., its interarrival times between two consecutive arrivals follows an exponential distribution with parameter 5 per hour. This question will ask you to evaluate two options for designing the server in the system. Both options for the single server provide the same service for the customers in the queueing system but they cost different amounts to implement. In addition, the total costs of the queuing system are the implementation costs plus the customer costs. Currently, the customer costs are $100 per hour per customer in the queueing system. In comparing these options, it costs us $100 per hour per customer in the queueing system. (a) The first option for the server is one that has a service time that follows an exponential distribution with mean 10 minutes. Determine L, W, Lq, and Wq for this system. (b) The second option for the server is one that has a service time that follows an exponential distribution with mean 8 minutes. Determine L, W, Lq, and Wq for this system. (c) The first option will cost us $250 per hour to implement. The second option will cost us $600 per hour to implement. As mentioned earlier, the total costs of either option will be their implementation costs plus the customer costs. Using appropriate pieces of your results from (a) and (b), determine which option will have a lower total hourly cost to implement.
Practical Management Science
6th Edition
ISBN:9781337406659
Author:WINSTON, Wayne L.
Publisher:WINSTON, Wayne L.
Chapter12: Queueing Models
Section12.5: Analytic Steady-state Queueing Models
Problem 9P
Related questions
Question
An M/M/1 queueing system has that customers arrive to it at a
rate of 5 per hour, i.e., its interarrival times between two consecutive arrivals follows an
exponential distribution with parameter 5 per hour. This question will ask you to evaluate
two options for designing the server in the system. Both options for the single server provide
the same service for the customers in the queueing system but they cost different amounts to
implement. In addition, the total costs of the queuing system are the implementation costs
plus the customer costs. Currently, the customer costs are $100 per hour per customer in the
queueing system.
In comparing these options, it costs us $100 per hour per customer in the queueing system.
(a) The first option for the server is one that has a service time that follows an
exponential distribution with mean 10 minutes. Determine L, W, Lq, and Wq for this
system.
(b) The second option for the server is one that has a service time that follows
an exponential distribution with mean 8 minutes. Determine L, W, Lq, and Wq for this
system.
(c) The first option will cost us $250 per hour to implement. The second option will cost us $600 per hour to implement. As mentioned earlier, the total costs of either
option will be their implementation costs plus the customer costs. Using appropriate pieces of your results from (a) and (b), determine which option will have a lower total hourly cost to implement.
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