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Monitoring and Early Warning for Internet Worms

Monitoring and Early Warning for Internet Worms. Cliff C. Zou, Lixin Gao, Weibo Gong, Don Towsley Univ. Massachusetts, Amherst. How to detect an unknown worm at its early stage?. Monitoring : Monitor worm scan traffic (non-legitimate traffic).

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Monitoring and Early Warning for Internet Worms

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  1. Monitoring and Early Warning for Internet Worms Cliff C. Zou, Lixin Gao, Weibo Gong, Don Towsley Univ. Massachusetts, Amherst

  2. How to detect an unknown worm at its early stage? • Monitoring: • Monitor worm scan traffic (non-legitimate traffic). • Connections to nonexistent IP addresses. • Connections to unused ports. • Observation data is very noisy. • Old worms’ scans. • Port scans by hacking toolkits. • Detecting: • Anomaly detection for unknown worms • Traditional anomaly detection: threshold-based • Check traffic burst (short-term or long-term). • Difficulties: False alarms; threshold tuning.

  3. Worm traffic “Trend Detection”  Detect traffic trend, not burst Trend: wormexponential growth trend at the beginning Detection: the exponential rate should be a positive, constant value Monitored illegitimate traffic rate Exponential rate a on-line estimation Non-worm traffic burst

  4. Why exponential growth at the beginning? • The law of natural growth reproduction • Exponential growth — fastest growth pattern when: • Negligible interference (beginning phase). • All objects have similar reproductive capability. • Large-scale system — law of large number. • Fast worm has exponential growth pattern • Attacker’s incentive: infect as many as possible before counteractions. • If not, a worm does not reach its spreading speed limit. • Slow spreading worms can be detected by other ways.

  5. At very early stage: Worm modeling — simple epidemic model : # of susceptible : # of infectious : Total # of hosts : Infectious ability # of contacts IS Simple epidemic model: It Discrete model: with exponential rate

  6. SQL Slammer Code Red Why use simple epidemic model? • Can model most scan-based worms. • We can use other worm models as well with minor modifications (such as exponential model). Figures from: D. Moore, V. Paxson, S. Savage, C. Shannon, S. Staniford, N. Weaver, “Inside the Slammer Worm”, IEEE Security & Privacy, July 2003.

  7. Kalman Filter Estimation • Equivalent to Recursive Least Square Estimator: • Give estimation at each discrete time. • Robust to noise. • System:Discrete-time simple epidemic model • System state: • Worm infection rate a. (a= bN, exponential growth rate at beginning) • Epidemic parameter b. (worm infectious ability) • Measurement from monitors: • Ci : cumulative # of observed infected, Zi :# of scans at time i.

  8. Kalman Filter Estimation System: where Kalman Filter for estimation of Xt :

  9. Code Red simulation experiments Population: N=360,000, Infection rate: a = 1.8/hour, Scan rate h = N(358/min, 1002), Initially infected: I0=10 Monitored IP space 220, Monitoring interval: D = 1 minute Consider background noise Before 2% (223 min): estimate is already stabilized and oscillating a little around a positiveconstant value

  10. SQL Slammer simulation experiments Population: N=100,000, Monitored IP space 220, Scan rate h = N(4000/sec, 20002), Initially infected: I0=10 Monitoring interval: D = 1 second, Consider background noise Before 1% (45 sec): estimate is already stabilized and oscillating around a positiveconstant value

  11. After using low-pass filter Early detection of Blaster • Blaster: sequentially scans from a starting IP address: • 40% from local Class C address. • 60% from a random IP address. • It follows simple epidemic model.

  12. Bias correction for uniform-scan worms • Bernoulli trial for a worm to hit monitors (hitting prob. = p). Bias correction: : Average scan rate Monitoring 214 IP space Monitoring 217 IP space Bias correction can provide unbiased estimate of It

  13. Prediction of Vulnerable population size N Direct from Kalman filter:  Alternative method: h : A worm sends out h scans per D time (derived from egress scan monitor)  Estimation of population N

  14. : observation data Use exponential growth model At the early stage:   Early stage of worm propagation Model #2: Autoregressive (AR) model  Model #3: Transformed linear model 

  15. Comparison between three estimation models • Observations • AR exponential model is smoother than epidemic model • Transformed linear model gives best results • Detect a worm when it infects about 0.5% population Epidemic model AR exponential model Transformed linear model

  16. Simple analysis of three estimation models • Why AR exponential model is smoother than epidemic model? • Introduced errors from measurement data: • Epidemic model • AR exponential model • Why transformed linear model is better than AR model? assume AR exponential model: Transformed linear model: where

  17. Summary • Trend detection: non-threshold-based methodology • Principle: detect traffic trend, not burst • Pros : Robust to background noise low false alarm rate • Cons: Rely on worm model, representation of measurement data • Epidemic model, exponential model • Using low-pass filter on noisy observation data • For uniform-scan worms • Bias correction: • Forecasting N: ( IPv4 )  Routing worm  : Average scan rate : Infection rate : scanning IP space : cumulative # of observed infectious : scan hitting prob.

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