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Fine-grained Augmentation for RF Fingerprinting under Impaired Channels

Ömer Melih Gül, Michel Kulhandjian, Burak Kantarcı, Azzedine Touazi, Cliff Ellement, Claude D’Amours

202216 citationsDOI

Abstract

Critical infrastructures such as connected and au-tonomous vehicles, are susceptible to cyber attacks due to their mission-critical deployment. To ensure security by design, radio frequency (RF)-based security is considered as an effective technique for a wirelessly monitored or actuated critical infrastructure. For this purpose, this paper proposes a novel augmentation-driven deep learning approach to analyze unique transmitter fingerprints to determine the legitimacy of a user device or transmitter. An RF fingerprinting model is susceptible to various channel and environmental conditions that impact the learning performance of a machine/deep learning model. As data gathering cannot be considered as a feasible alternative, efficient solutions that can tackle the impact of varying channels on learning performance are emergent. This work aims to shed light on the RF fingerprinting problem from a different angle when 4G, 5G and WiFi data samples are collected from different transmitters by proposing a fine-grained augmentation approach to improve the learning performance of a deep learning model. Numerical results point out the promising RF fingerprinting performance when training data are augmented in a waveform-specific fine-grained manner as fingerprinting accuracy (87.94%) under the previously presented TDL/CDL augmentation can be boosted to 95.61% under previously unseen RF data instances.

Topics & Concepts

Computer scienceSoftware deploymentTransmitterDeep learningRadio frequencyArtificial intelligenceInterference (communication)Machine learningChannel (broadcasting)Real-time computingTelecommunicationsOperating systemWireless Signal Modulation ClassificationInternet Traffic Analysis and Secure E-votingHate Speech and Cyberbullying Detection
Fine-grained Augmentation for RF Fingerprinting under Impaired Channels | Litcius