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Analysis of a discrete-time single-server queue with bursty inputs for traffic control in ATM networks

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4 Author(s)
Murata, M. ; Osaka Univ., Japan ; Oie, Y. ; Suda, T. ; Miyahara, H.

The performance of an asynchronous transfer mode (ATM) network subject to admission control and traffic smoothing is analyzed. Basically, an ATM switch is modeled as a discrete-time single-server queuing system in which a new call joins existing calls. Cell arrivals from a new call are assumed to follow a general distribution. It is also assumed that aggregated arrivals of cells from existing calls form batch arrivals with a general batch size distribution and a geometric distribution of the interarrival times between batches. Both finite- and infinite-buffer cases are considered. An exact analysis yields the waiting time distribution and cell loss probability for a new call and for existing calls. Numerical examples are given to show how the network performance depends on the statistics of a new call (burstiness, time that a call stays in an active or inactive state, etc.) and to demonstrate the effectiveness of admission control and traffic smoothing

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Selected Areas in Communications, IEEE Journal on  (Volume:8 ,  Issue: 3 )