Title :
Pareto process as a model of self-similar packet traffic
Author_Institution :
Bellcore, Red Bank, NJ, USA
Abstract :
In the past few years packet traffic from various sources-Ethernet, ISDN, CCSN and VBR video-has been shown to exhibit self-similarity, and related properties of long range correlation, slowly decaying variances and fractal dimensions. This discovery has motivated research into unconventional traffic models such as fractional Brownian motion, fractional ARIMA and chaotic maps. These models explain certain queueing effects in packet networks that are difficult to explain using conventional traffic models. We argue that such exotic models may not be needed to describe self-similar traffic. We analyze the G/M/1 queue with Pareto input. Although a renewal process, and solvable by standard methods, the Pareto process generates self-similar arrivals. Its long range dependence produces qualitatively different queueing behavior from exponential models. In particular, delays can rise sharply for ρ much less than one
Keywords :
correlation methods; fractals; packet switching; probability; queueing theory; telecommunication traffic; CCSN; Ethernet; G/M/1 queue; ISDN; Pareto input; Pareto process; VBR video; chaotic maps; exponential model; fractal dimensions; fractional ARIMA; fractional Brownian motion; long range correlation; packet networks; queueing effects; renewal process; self similar arrivals; self similar packet traffic; slowly decaying variances; traffic models; Autocorrelation; Brownian motion; Chaos; Ethernet networks; Fractals; ISDN; Pareto analysis; Queueing analysis; Telecommunication traffic; Traffic control;
Conference_Titel :
Global Telecommunications Conference, 1995. GLOBECOM '95., IEEE
Print_ISBN :
0-7803-2509-5
DOI :
10.1109/GLOCOM.1995.502798
