A Nonstationary Poisson View of Internet Traffic

1. A Nonstationary Poisson View of Internet Traffic Thomas Karagiannis joint work with Mart Molle, Michalis Faloutsos, Andre Broido

2. What is the nature of Internet traffic? • The fundamental question • How does Internet traffic look like? • Two competing models • Poisson and independence assumption • Kleinrock (1976) • Self-similarity, Long-Range Dependence, heavy tails • Revolutionized modeling • Poisson has largely been discredited

3. The Poisson assumption may still be applicable ! • We revisit the question: LRD or Poisson? • We focus on Internet core • Things may have changed: massive scale and multiplexing • Our observations: • Packet arrivals appear Poisson and independent • We observe nonstationarity at multi-second time scales • Traffic exhibits LRD properties at scales of seconds and above • Our conjecture: Traffic as a nonstationary Poisson process? • This view appears to reconcile the multifaceted behavior

4. Background: Self-similarity and LRD • Self-similarity opens new horizons in traffic modeling • 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. • Self-similarity through high-variability: statistical analysis of ethernet LAN traffic at the source level (1995) • W. Willinger, M. S. Taqqu, R. Sherman, and D. V. Wilson. • Self-Similarity in World Wide Web Traffic: Evidence and Possible Causes. (1997) • M. E. Crovella and A. Bestavros. • New tools and models • Wavelet Analysis of Long-Range Dependence (1998) • P. Abry and D. Veitch.

5. Traces • Traces taken by CAIDA monitors at a Tier 1 Internet Service Provider (ISP) • OC48 link (2.4Gbps) • State of the art Dag4 monitors • August 2002, January 2003, April 2003 • Traces from the WIDE backbone • Trans-Pacific 100Mbps link (June 2003)

6. Packet arrivals appear Poisson! • Backbone: Interarrival times follow the exponential distribution • CCDF is a straight line with 99.99% correlation coefficient • Arrivals appear uncorrelated • We examine correlations with several tools CCDF of packet interarrival times (100Mbps) CCDF of packet interarrival times (OC48) log(P[X>x]) log(P[X>x]) interarrival times (microsec) interarrival times (microsec)

7. LAN 1989 vs. Backbone 2003 • LAN - August 1989 • Bellcore traces • The trace that started the LRD revolution • Backbone - January 2003 • Current backbone traces Packet interarrival distribution

8. At the same time, traffic exhibits LRD properties • Statistical tools show LRD at large scales • Dichotomy in scaling behavior • Hurst exponent 0.7-0.85 at larger scales Abry-Veitch Wavelet estimator

9. Backbone traffic appears smooth but nonstationary at multi-second time-scales • Rate changes at second scales • Canny Edge Detector algorithm from image processing to detect changes

10. Could nonstationarity appear as LRD? • LRD properties diminish when global average is replaced by moving average in ACF

11. How can we reconcile the observed behavior? • Observed behavior • Poisson packet arrivals • Nonstationary rate variation • Long-range dependence • Our conjecture: A time-dependent Poisson characterization of traffic • when viewed across very long time scales, exhibits the observed long-range dependence • It has been supported by theoretical work • (e.g., Andersen et al. JSAC ’98)

12. Caveats – Why we don’t have a definitive answer • Data collection • Duration, representative sample • Backbone versus access link • Estimation not calculation • Tools offer approximations and not definite conclusions • Approaching the truth • Different theories may explain different facets of the behavior at different scales