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Code Red Worm Propagation Modeling and Analysis Zou, Gong, & Towsley Michael E. Locasto March 4, 2003 Paper # 46.

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Presentation on theme: "Code Red Worm Propagation Modeling and Analysis Zou, Gong, & Towsley Michael E. Locasto March 4, 2003 Paper # 46."— Presentation transcript:

1 Code Red Worm Propagation Modeling and Analysis Zou, Gong, & Towsley Michael E. Locasto March 4, 2003 Paper # 46

2 Overview Code Red incident data & impact epidemiology models –traditional (biological) infection models –two-factor worm model related work & questions –(Weaver & Sapphire)

3 Motivation Internet great medium for spreading malicious code –Code Red & Co. renew interest in worm studies Issues: –How to explain worm propagation curves? –What factors affect spreading behavior? –Can we generate a more accurate model?

4 Epidemic Models Deterministic vs. Stochastic –Simple epidemic model (paper #45) –general epidemic model (Kermack-Mckendrick add notion of removed hosts) good baseline, need to be adjusted to explain Internet worm data any model must be deterministic (b/c of scale)

5 Two-Factor Worm Model Two major factors affect worm spread: –dynamic human countermeasures anti-virus software cleaning patching firewall updates disconnect/shutdown –interference due to aggressive scanning Rate of infection (ß) is not constant

6 Two-Factor Worm Model (con) Two important restrictions: –consider only “continuously activated” worms –consider worms that propagate w/ort topology

7 Infection Statistics

8 Classic Simple Epidemic Model Model presented in paper 45 (classic simple epidemic model, k=1.8, k=BN) a(t) = J(t) / N (fraction of population infected) Wrong! (compare to last slide)

9 Simple Epidemic Model Math Variables: infected hosts (had virus at some point) = J(t) population size = N infection rate = ß(t) dJ(t)/dt = βJ(t)[N - J(t)]

10 Two-Factor Model Math dI(t)/dt = β(t)[N - R(t) - I(t) - Q(t)]I(t) - dR(t)/dt –S(t) = susceptible hosts –I(t) = infectious hosts –R(t) = removed hosts from I population –Q(t) = removed hosts from S population –J(t) = I(t) + R(t) –C(t) = R(t) + Q(t) –J(t) = I(t) + R(t) –N = population (I+R+Q+S)

11 Two-Factor Fit Take removed hosts from both S and I populations into account non-constant infection rate (decreases) fits well with observed data

12 Results Two-factor worm model –accurate model without topology constraints –explains exponential start & end drop off –identifies 2 critical factors in worm propagation Only 60% of CR targets infected

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