Unit 11: Queuing Theory




          11.  Traffic intensity in a system of steady state is given by  = l / .             Notes
          12.  For Poisson arrivals at the constant rate  l per unit, the time between successive arrivals
               (inter-arrival time) has the exponential distribution.

          11.6 Summary


              Queuing Theory is a collection of mathematical models of various queuing systems.
              It is used  extensively to analyze production and service  processes exhibiting  random
               variability in market demand (arrival times) and service time.
              Queues or waiting lines arise when the demand for a service facility exceeds the capacity
               of that facility, that is, the  customers do not get service immediately upon request but
               must wait, or the service facilities stand idle and wait for customers.
              The type of queuing system a business uses is an important factor in determining how
               efficient the business is run.

              As the size of the population increases the world over, the number of queues and their
               queue length also increase.

              In the business world, more customers mean more business transactions.
              Out of the many ways to attract customers, an efficient queuing system plays a significant
               role as it reduces a customer’s waiting time. The shorter waiting time makes customers
               happy, and in all probabilities, a happy customer will come back for business again.
              In a queuing system, the calling population is assumed to be infinite.
              This means that if a unit leaves the calling population and joins the waiting line or enters
               service, there will be no change in the arrival rate.
              The arrivals occur one at a time in a random order and once the customer joins the queuing
               system he will eventually receive the service.
              The arrival rate and services are modeled as variables that follow statistical distributions.
               If  the arrival  rate is greater than  the service rate, the  waiting line  will grow without
               bound.
              Waiting line models that assume that customers arrive according to a Poisson probability
               distribution, and service times are described by an exponential distribution.

              The Poisson distribution specifies the probability that a certain number of customers will
               arrive in a given time period.

              The exponential distribution describes the service times as the probability that a particular
               service time will be less than or equal to a given amount of time.
              A waiting line priority rule determines which customer is served next. A frequently used
               priority rule is first-come, first-served.
              Other rules include best customers first, high-test profit customer first, emergencies first,
               and so on.
              Although each priority rule has merit, it is important to use the priority rule that best
               supports the overall organization strategy.

              The priority rule used affects the performance of the waiting line system.






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