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An Analytical Model for Network Flow Analysis

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1 An Analytical Model for Network Flow Analysis
Ernesto Gomez, Yasha Karant, Keith Schubert Institute for Applied Supercomputing Department of Computer Science CSU San Bernardino The authors gratefully acknowledge the support of the NSF under award CISE

2 Outline Networks and Flows History Statistical Mechanics
Self-similar traffic Traffic creation and destruction Master Equation and traffic flow

3 One View of Network

4 Network Flows

5 Outline Networks and Flows History Statistical Mechanics
Self-similar traffic Traffic creation and destruction Master Equation and traffic flow

6 Brief History Shannon-Hartley (classical channel capacity)
C=B log2(1+SNR) Leland, Taqqu, Willinger, Wilson, Paxon, … Self-similar traffic Cao, Cleveland, Lin, Sun, Ramanan Poisson in limit

7 Stochastic vs. Analytic
Stochastic best tools currently Opnet, NS Problems limiting cases Improving estimates Analytic (closed form equations) Handles problems of stochastic Insight into structure Fluid models Statistical Mechanics

8 Outline Networks and Flows History Statistical Mechanics
Self-similar traffic Traffic creation and destruction Master Equation and traffic flow

9 Overview Large number of entities
Bulk properties Equilibrium or non-equilibrium properties Time-dependence Conservation over ensemble averages Can handle classical and quantum flows

10 Density Matrix Formalism
Each component Label by state n = node source and destination f = flow index c = flow characteristics t = time step

11 Density Matrix II Probability of a flow Element in Density Matrix is
Averaged Properties

12 Outline Networks and Flows History Statistical Mechanics
Self-similar traffic Traffic creation and destruction Master Equation and traffic flow

13 Poisson Distribution  is mean Thin Tail

14 Problem with Poisson Burst Long-range dependence
Extended period above the mean Variety of timescales Long-range dependence Poisson or Markovian arrivals Characteristic burst length Smoothed by averaging over time Real distribution is self-similar or multifractal Proven for Ethernet

15 Real versus Poisson

16 Pareto Distribution Shape parameter () Location parameter (k)
Smaller means heavier tail Infinite varience when 2 ≥  Infinite mean when 1 ≥  Location parameter (k) t≥k

17 Pareto Distribution

18 Outline Networks and Flows History Statistical Mechanics
Self-similar traffic Traffic creation and destruction Master Equation and traffic flow

19 Flow Origination Unicast Multicast One source One destination
Many segments Multicast Many destinations

20 Multicast Possibilities

21 Outline Networks and Flows History Statistical Mechanics
Self-similar traffic Traffic creation and destruction Master Equation and traffic flow

22 Probability in Density Matrix
Tr = eHt (H is energy function) Tr= (1+t/tns)-1 Cauchy Boundary conditions hypersurface of flow space Ill behaved Gaussian quadrature, Monte Carlo, Pade Approximation

23 Unicast Flow Time

24 Future Directions More detailed network Bulk properties Online tool

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