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Chap. 20, page 1051 Queuing Theory Arrival process Service process Queue Discipline Method to join queue IE 417, Chap 20, Jan 99.

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Presentation on theme: "Chap. 20, page 1051 Queuing Theory Arrival process Service process Queue Discipline Method to join queue IE 417, Chap 20, Jan 99."— Presentation transcript:

1 Chap. 20, page 1051 Queuing Theory Arrival process Service process Queue Discipline Method to join queue IE 417, Chap 20, Jan 99

2 Each Distribution for Random Variable Has: Definition Parameters Density or Mass function Cumulative function Range of valid values Mean and Variance IE 417, Chap 20, Jan 99

3 Exponential Dist. Poisson Dist. IE 417, Chap 20, Jan 99

4 X1=1/4 X2=1/2 X3=1/4 X4=1/8 X5=1/8 X6=1/2 X7=1/4 X8=1/4 X9=1/8 X10=1/8 X11=3/8 X12=1/8 0 1:00 2:00 3:00 Y1=3 Y2=4 Y3=5 Relation between Exponential distribution ↔ Poisson distribution X i : Continuous random variable, time between arrivals, has Exponential distribution with mean = 1/4 Y i : Discrete random variable, number of arrivals per unit of time, has Poisson distribution with mean = 4. (rate=4) Y ~ Poisson (4) IME 301

5 Kendell-Lee Notation for Queuing System 1 / 2 / 3 / 4 / 5 / 6 Arrival / Service / Parallel / Queue / Max / Population Process Process Servers Discip- Cus- Size line tomer M, D, Er, G, GI IE 417, Chap 20, Jan 99

6 Queuing System j = State of the system, number of people in the system P ij (t) = Probability that j people are in the system at time t given that i people are in the system at time 0 Steady state probability of j people in the system IE 417, Chap 20, Jan 99

7 Laws of Birth-Death Process 1- : birth rate (arrival) in state j 2- : death rate (service ends) in state j 3- death and births are independent of each other, no more than 1 event in M/M/1 is considered a birth-death process Will not cover mathematical details of Section 20.3 IE 417, Chap 20, Jan 99

8 Notations used for QUEUING SYSTEM in steady state (AVERAGES) = Arrival rate approaching the system e = Arrival rate (effective) entering the system = Maximum (possible) service rate e = Practical (effective) service rate L = Number of customers present in the system Lq = Number of customers waiting in the line Ls = Number of customers in service W = Time a customer spends in the system Wq = Time a customer spends in the line Ws = Time a customer spends in service IE 417, Chap 20, May 99

9 Notations used for QUEUING SYSTEM in steady state = Traffic intensity = / = P(j) = Probability that j units are in the system = P(0) = Probability that there are no units (idle) in the system P w = P(j>S) = Probability that an arriving unit has to wait for service C = System capacity (limit) = Probability that a system is full (lost customer) = Probability that a particular server is idle IE 417, Chap 20, Mayl 99

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