EMIS 7370

1. PROJECT PRESENTATION “QUEUEING THEORY” EMIS 7370 Yavuz SAHIN

2. QUEUEING THEORY • Nobody likes waiting • But, reducing waiting times needs investment • Queueing theory analyzes this situation • It is applicable to • communication networks • Computer systems • Supermarkets • hospitals

3. Server 1 Server 2 Server 3 Queue (waiting line) Server n

4. SOME COMMON DISCIPLINES • FIFO: (First in, First out) • LIFO: (Last in, First out) • Random Service: the customers in the queue are served in random order • Round Robin: every customer gets a time slice. If her service is not completed, she will re-enter the queue • Priority Disciplines: every customer has a (static or dynamic) priority

5. Kendall Notation • used for a short characterization of queueing systems • A/B/m/N-S • A : the distribution of the inter arrival time • B : the distribution of the service times • m : the number of servers • N : the maximum size of the waiting line in the finite case • S : the service discipline used

6. M (Markov) : it is memoryless • D (Deterministic):all values from a deterministic “distribution” are constant • Erlang-k: • Hk (Hyper-k): • G (General): general distribution

7. Markovian Systems • M/M/1 Queue: • the simplest queueing system to analyze • Arrival and service time are negative exponentially distributed (Poisson) • Mean number of customers • Mean response time • The probability of that the system have k or more customers

8. Markovian Systems • M/M/m-Queue: • m serversand the waiting line is infinitely long • The mean number of customers • Probability formula (Erlang C)

9. Markovian Systems • M/M/1/K -Queue: • has exponential interarrival time and service time distributions • FIFO, single server so system can hold K customers at the same time. • When a new customer comes it is blocked • pure birth-death system • suited to approximate “real systems”

10. Markovian Systems • M/M/1/K -Queue: • The mean number of customers in the system: • N Graph for K=10

11. Comparison of Markovian Systems • Comparison is made that each system has the probability for a new customer • The best one is M/M/m, the worst one is M/M/1/K according to mean delay times...

12. Queueing Netwoks • Open networks:receive customers from an external source and send them to an external destination. • have a fixed population that moves between the queues but never leaves the system

13. Summary • Queueing theory is very useful to analyse serving time or blockage rate for a lot of systems • It has a lot of combination to explain most situation based on number of servers, availability of blockage (overflow) or number of customers • It determines how much investment is needed to have better Quality of Service. Also we can see if investment is justified.

14. References • http://www.dcs.ed.ac.uk/home/jeh/Simjava/queueing/ • http://www.win.tue.nl/~iadan/queueing.pdf • http://www.eventhelix.com/realtimemantra/CongestionControl/queueing_theory.htm • http://www.eventhelix.com/realtimemantra/CongestionControl/m_m_1_queue.htm • A Short Introduction to Queueing Theory, A.Willig, TUB, 1999 • An introduction into Queueing Theory, M. Krondorf, TUD, 2006 • Kuyruk Teorisi, Y.SUCU, M. SIMSEKLER, Trakya University, 2003