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A Nonstationary Poisson View of Internet Traffic

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A Nonstationary Poisson View of Internet Traffic T. Karagiannis, M. Molle, M. Faloutsos University of California, Riverside A. Broido University of California, San Diego – PowerPoint PPT presentation

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Title: A Nonstationary Poisson View of Internet Traffic


1
A Nonstationary Poisson View of Internet Traffic
  • T. Karagiannis, M. Molle, M. Faloutsos
  • University of California, Riverside
  • A. Broido
  • University of California, San Diego
  • IEEE INFOCOM 2004

Presented by Ryan
2
Outline
  • Introduction
  • Background
  • Definitions
  • Previous Models
  • Observed Behavior
  • A time-dependent Poisson characterization
  • Conclusion

3
Introduction
  • Nature of Internet Traffic
  • How does Internet traffic look like?
  • Modeling of Internet Traffic
  • Provisioning
  • Resource Management
  • Traffic generation in simulation

4
Introduction
  • Comparing with ten years ago
  • Three orders of magnitude increase in
  • Links speed
  • Number of hosts
  • Number of flows
  • Limiting behavior of an aggregate traffic flow
    created by multiplexing large number of
    independent flows ? Poisson model

5
Background Definitions
  • Complementary cumulative distribution function
    (CCDF)
  • Autocorrelation Function (ACF)
  • Correlation between a time series Xt and its
    k-shifted time series Xtk

exponential distribution
6
Background Definitions
  • Long Range Dependence (LRD)
  • The sum of its autocorrelation does not converge
  • Memory is built-in to the process

7
Background Definitions
  • Self-similarity
  • Certain properties are preserved irrespective of
    scaling in space or time
  • H Hurst exponent

8
Background Definitions
Self-similar
9
Background Definitions
  • Second-order self-similar
  • ACF is preserved irrespective of time aggregation
  • Model LRD process
  • H ? 1, the dependence is stronger

10
Background Previous Model
  • Telephone call arrival process (70s 80s)
  • Poisson Model
  • Independent inter-arrival time
  • Internet Traffic (90s)
  • Self-similarity
  • Long-range dependence (LRD)
  • Heavy tailed distribution

11
Findings in the Paper
  • At Sub-Second Scales
  • Poisson and independent packets arrival
  • At Multi-Second Scales
  • Nonstationary
  • At Larger Time Scales
  • Long Range Dependence

12
Traffic Traces
  • Traces from CAIDA (primary focus)
  • Internet backbone, OC48 link (2.5Gbps)
  • August 2002, January and April 2003
  • Traces from WIDE
  • Trans-Pacific link (100Mbps)
  • June 2003

13
Traffic Traces
  • BC-pAug89 and LEL-PKT-4 traces
  • On the Self-Similar Nature of Ethernet Traffic.
    (1994)
  • W. E. Leland, M. S. Taqqu, W. Willinger, and D.
    V. Wilson.
  • Wide Area Traffic The Failure of Poisson
    Modeling. (1995)
  • V. Paxson and S. Floyd.

14
Traffic Traces
  • Analysis of OC48 traces
  • The link is overprovisioned
  • Below 24 link unilization
  • 90 bytes (TCP)
  • 95 packets (TCP)

15
Poisson at Sub-Second Time Scales
  • Distribution of Packet Inter-arrival Times
  • Red line corresponding to exponential
    distribution
  • Blue line OC48 traces
  • Linear least squares fitting ? 99.99 confidence

16
Poisson at Sub-Second Time Scales
LBL-PKT-4 trace
WIDE trace
17
Poisson at Sub-Second Time Scales
  • Independence

18
Nonstationary at Multi-Second Time Scales
  • Rate changes at second scales
  • Changes detection
  • Canny Edge Detector algorithm

change point
19
Nonstationary at Multi-Second Time Scales
  • Similar in BC-pAug89 trace

20
Nonstationary at Multi-Second Time Scales
  • Possible causes for nonstationarity
  • Variation of the number of active sources over
    time
  • Self-similarity in the traffic generation process
  • Change of routing

21
Nonstationary at Multi-Second Time Scales
  • Characteristics of nonstationary
  • Magnitude of the rate change events
  • Significant negative correlation at lag one
  • An increase followed by a decrease

22
Nonstationary at Multi-Second Time Scales
  • Duration of change free intervals
  • Follow the exponential distribution

23
LRD at Large Time Scales
  • Measure LRD by the Hurst exponent (H) estimators
  • LRD, H ? 1
  • Point of Change (Dichotomy in scaling)
  • Below 0.6, Above 0.85

Point of Change
24
LRD at Large Time Scales
  • Effect of nonstationarity
  • Remove nonstationarity by moving average
    (Gaussian window)

Point of Change
25
Conclusion
  • Revisit Poisson assumption
  • Analyzing a combination of traces
  • Different observations at different time scales
  • Network Traffic
  • Time-dependent Poisson
  • Backbone links only
  • Massive scale and multiplexing
  • MAY lead to a simpler model

26
Background Definitions
  • Poisson Process
  • The number of arrivals occurring in two disjoint
    (non-overlapping) subintervals are independent
    random variables.
  • The probability of the number of arrivals in some
    subinterval t,t t is given by
  • The inter-arrival time is exponentially
    distributed
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