Accurate network anomaly classification with generalized entropy metrics

The accurate detection and classification of network anomalies based on traffic feature distributions is still a major challenge. Together with volume metrics, traffic feature distributions are the primary source of information of approaches scalable to high-speed and large scale networks. In previous work, we proposed to use the Tsallis entropy based traffic entropy spectrum (TES) to capture changes in specific activity regions, such as the region of heavy-hitters or rare elements. Our preliminary results suggested that the TES does not only provide more details about an anomaly but might also be better suited for detecting them than traditional approaches based on Shannon entropy. We refine the TES and propose a comprehensive anomaly detection and classification system called the entropy telescope. We analyze the importance of different entropy features and refute findings of previous work reporting a supposedly strong correlation between different feature entropies and provide an extensive evaluation of our entropy telescope. Our evaluation with three different detection methods (Kalman filter, PCA, KLE), one classification method (SVM) and a rich set of anomaly models and real backbone traffic demonstrates the superiority of the refined TES approach over TES and the classical Shannon-only approaches. For instance, we found that when switching from Shannon to the refined TES approach, the PCA method detects small to medium sized anomalies up to 20% more accurately. Classification accuracy is improved by up to 19% when switching from Shannon-only to TES and by another 8% when switching from TES to the refined TES approach. To complement our evaluation, we run the entropy telescope on one month of backbone traffic finding that most prevalent anomalies are different types of scanning (69–84%) and reflector DDoS attacks (15–29%).