Bollmann, ChadTummala, MuraliMcEachen, JohnScrofani, JimKragh, Mark2017-12-282017-12-282018-01-03978-0-9981331-1-9http://hdl.handle.net/10125/50578The stable distribution has been shown to more accurately model some aspects of network traffic than alternative distributions. In this work, we quantitatively examine aspects of the modeling performance of the stable distribution as envisioned in a statistical network cyber event detection system. We examine the flexibility and robustness of the stable distribution, extending previous work by comparing the performance of the stable distribution against alternatives using three different, public network traffic data sets with a mix of traffic rates and cyber events. After showing the stable distribution to be the overall most accurate for the examined scenarios, we use the Hellinger metric to investigate the ability of the stable distribution to reduce modeling error when using small data windows and counting periods. For the selected case and metric, the stable model is compared to a Gaussian model and is shown to produce the best overall fit as well as the best (or at worst, equivalent) fit for all counting periods. Additionally, the best stable fit occurs at a counting period that is five times shorter than the best Gaussian case. These results imply that the stable distribution can provide a more robust and accurate model than Gaussian-based alternatives in statistical network anomaly detection implementations while also facilitating faster system detection and response.8 pagesengAttribution-NonCommercial-NoDerivatives 4.0 InternationalCyber Threat Intelligence and Analyticsalpha stable, network anomaly detection, optimal window size, traffic analysisTechniques to Improve Stable Distribution Modeling of Network TrafficConference Paper10.24251/HICSS.2018.689