A Physics-Based Context-Aware Approach for Anomaly Detection in Teleoperated Driving Operations Under False Data Injection Attacks

Abstract

Teleoperated driving (ToD) systems are a special type of cyber-physical system (CPS) where the operator remotely controls the steering, acceleration, and braking actions of the vehicle. Malicious actors may inject false data into communication channels to manipulate the teleoperator's driving commands to cause harm. Hence, protection of this communication is necessary for a safe operation of the target vehicle. However, according to the National Institute of Standards and Technology (NIST) cybersecurity framework, protection is not enough, and detecting an attack is necessary. Moreover, UN R155 mandates that vehicle fleets detect and log security incidents. Thus, the cyber-physical threats of ToD are modeled using the attack-centric approach in this paper. Then, an attack model with false data injection (FDI) on the steering control command is created from real vehicle data. A risk of this attack model is assessed for a last-mile delivery (LMD) application. Finally, a physics-based context-aware anomaly detection system (PCADS) is proposed to detect such false injection attacks, and preliminary experimental results are presented to validate the model.

Tasks

Reproductions