The Case for Retraining of ML Models for IoT Device Identification at the Edge

• URL: http://arxiv.org/abs/2011.08605v1
• Date: Tue, 17 Nov 2020 13:01:04 GMT
• Title: The Case for Retraining of ML Models for IoT Device Identification at the Edge
• Authors: Roman Kolcun (1), Diana Andreea Popescu (2), Vadim Safronov (2), Poonam Yadav (3), Anna Maria Mandalari (1), Yiming Xie (1), Richard Mortier (2) and Hamed Haddadi (1) ((1) Imperial College London, (2) University of Cambridge, (3) University of York)
• Abstract summary: We show how to identify IoT devices based on their network behavior using resources available at the edge of the network. It is possible to achieve device identification and categorization with over 80% and 90% accuracy respectively at the edge.
• Score: 0.026215338446228163
• License: http://creativecommons.org/licenses/by/4.0/
• Abstract: Internet-of-Things (IoT) devices are known to be the source of many security problems, and as such they would greatly benefit from automated management. This requires robustly identifying devices so that appropriate network security policies can be applied. We address this challenge by exploring how to accurately identify IoT devices based on their network behavior, using resources available at the edge of the network. In this paper, we compare the accuracy of five different machine learning models (tree-based and neural network-based) for identifying IoT devices by using packet trace data from a large IoT test-bed, showing that all models need to be updated over time to avoid significant degradation in accuracy. In order to effectively update the models, we find that it is necessary to use data gathered from the deployment environment, e.g., the household. We therefore evaluate our approach using hardware resources and data sources representative of those that would be available at the edge of the network, such as in an IoT deployment. We show that updating neural network-based models at the edge is feasible, as they require low computational and memory resources and their structure is amenable to being updated. Our results show that it is possible to achieve device identification and categorization with over 80% and 90% accuracy respectively at the edge.

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