A large insurance company maintains a central computing system that contains a variety of information about customer accounts. Insurance agents in a six-state area use telephone lines to access the customer information database. Currently, the company's central computer system allows three users to access the central computer simultaneously. Agents who attempt to use the system when it is full are denied access; no waiting is allowed. Management realizes that with its expanding business, more requests will be made to the central information system. Being denied access to the system is inefficient as well as annoying for agents. Access requests follow a Poisson probability distribution, with a mean of 29 calls per hour. The service rate per line is 19 calls per hour. (a) What is the probability that 0, 1, 2, and 3 access lines will be in use? (Round your answers to four decimal places.) P(0) = P(1) = P(2) = P(3) = (b) What is the probability that an agent will be denied access to the system? (Round your answers to four decimal places.) Pk= (c) What is the average number of access lines in use? (Round your answers to two decimal places.) (d) In planning for the future, management wants to be able to handle λ = 40 calls per hour. In addition, the probability that an agent will be denied access to the system should be no greater than the value computed in part (b). How many access lines should this system have?
A large insurance company maintains a central computing system that contains a variety of information about customer accounts. Insurance agents in a six-state area use telephone lines to access the customer information database. Currently, the company's central computer system allows three users to access the central computer simultaneously. Agents who attempt to use the system when it is full are denied access; no waiting is allowed. Management realizes that with its expanding business, more requests will be made to the central information system. Being denied access to the system is inefficient as well as annoying for agents. Access requests follow a Poisson probability distribution, with a mean of 29 calls per hour. The service rate per line is 19 calls per hour. (a) What is the probability that 0, 1, 2, and 3 access lines will be in use? (Round your answers to four decimal places.) P(0) = P(1) = P(2) = P(3) = (b) What is the probability that an agent will be denied access to the system? (Round your answers to four decimal places.) Pk= (c) What is the average number of access lines in use? (Round your answers to two decimal places.) (d) In planning for the future, management wants to be able to handle λ = 40 calls per hour. In addition, the probability that an agent will be denied access to the system should be no greater than the value computed in part (b). How many access lines should this system have?
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 21P
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![A large insurance company maintains a central computing system that contains a variety of information about customer accounts. Insurance agents in a six-state area use telephone lines to access the
customer information database. Currently, the company's central computer system allows three users to access the central computer simultaneously. Agents who attempt to use the system when it is full are
denied access; no waiting is allowed.
Management realizes that with its expanding business, more requests will be made to the central information system. Being denied access to the system is inefficient as well as annoying for agents. Access
requests follow a Poisson probability distribution, with a mean of 29 calls per hour. The service rate per line is 19 calls per hour.
(a) What is the probability that 0, 1, 2, and 3 access lines will be in use? (Round your answers to four decimal places.)
P(0) =
P(1) =
P(2) =
P(3) =
(b) What is the probability that an agent will be denied access to the system? (Round your answers to four decimal places.)
(c) What is the average number of access lines in use? (Round your answers to two decimal places.)
(d) In planning for the future, management wants to be able to handle λ = 40 calls per hour. In addition, the probability that an agent will be denied access to the system should be no greater than the value
computed in part (b). How many access lines should this system have?](/v2/_next/image?url=https%3A%2F%2Fcontent.bartleby.com%2Fqna-images%2Fquestion%2F35f2bbd2-7586-429c-a9c8-27fea227e1fd%2Fde741477-ac14-4fc9-aaa0-92f375f5f5a1%2Fny06t2_processed.png&w=3840&q=75)
Transcribed Image Text:A large insurance company maintains a central computing system that contains a variety of information about customer accounts. Insurance agents in a six-state area use telephone lines to access the
customer information database. Currently, the company's central computer system allows three users to access the central computer simultaneously. Agents who attempt to use the system when it is full are
denied access; no waiting is allowed.
Management realizes that with its expanding business, more requests will be made to the central information system. Being denied access to the system is inefficient as well as annoying for agents. Access
requests follow a Poisson probability distribution, with a mean of 29 calls per hour. The service rate per line is 19 calls per hour.
(a) What is the probability that 0, 1, 2, and 3 access lines will be in use? (Round your answers to four decimal places.)
P(0) =
P(1) =
P(2) =
P(3) =
(b) What is the probability that an agent will be denied access to the system? (Round your answers to four decimal places.)
(c) What is the average number of access lines in use? (Round your answers to two decimal places.)
(d) In planning for the future, management wants to be able to handle λ = 40 calls per hour. In addition, the probability that an agent will be denied access to the system should be no greater than the value
computed in part (b). How many access lines should this system have?
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