Self-Secured Control with Anomaly Detection and Recovery in Automotive Cyber-Physical Systems
Title | Self-Secured Control with Anomaly Detection and Recovery in Automotive Cyber-Physical Systems |
Publication Type | Conference Paper |
Year of Publication | 2019 |
Authors | Vatanparvar, Korosh, Al Faruque, Mohammad Abdullah |
Conference Name | 2019 Design, Automation Test in Europe Conference Exhibition (DATE) |
Publisher | IEEE |
ISBN Number | 978-3-9819263-2-3 |
Keywords | anomaly detection, automotive controllers, Automotive cyber-physical systems, Automotive engineering, Batteries, battery, battery management system, Computer architecture, control engineering computing, control loop behavior, CPS, Cyber-physical systems, electric vehicle, generative adversarial networks, learning (artificial intelligence), machine learning, machine learning models, Mathematical model, neural nets, pubcrawl, recovery estimation error, resilience, Resiliency, security, security of data, self-secured control, Sensors, System recovery |
Abstract | Cyber-Physical Systems (CPS) are growing with added complexity and functionality. Multidisciplinary interactions with physical systems are the major keys to CPS. However, sensors, actuators, controllers, and wireless communications are prone to attacks that compromise the system. Machine learning models have been utilized in controllers of automotive to learn, estimate, and provide the required intelligence in the control process. However, their estimation is also vulnerable to the attacks from physical or cyber domains. They have shown unreliable predictions against unknown biases resulted from the modeling. In this paper, we propose a novel control design using conditional generative adversarial networks that will enable a self-secured controller to capture the normal behavior of the control loop and the physical system, detect the anomaly, and recover from them. We experimented our novel control design on a self-secured BMS by driving a Nissan Leaf S on standard driving cycles while under various attacks. The performance of the design has been compared to the state-of-the-art; the self-secured BMS could detect the attacks with 83% accuracy and the recovery estimation error of 21% on average, which have improved by 28% and 8%, respectively. |
URL | https://ieeexplore.ieee.org/document/8714833 |
DOI | 10.23919/DATE.2019.8714833 |
Citation Key | vatanparvar_self-secured_2019 |
- learning (artificial intelligence)
- System recovery
- sensors
- self-secured control
- security of data
- security
- Resiliency
- resilience
- recovery estimation error
- pubcrawl
- neural nets
- Mathematical model
- machine learning models
- machine learning
- Anomaly Detection
- generative adversarial networks
- electric vehicle
- cyber-physical systems
- CPS
- control loop behavior
- control engineering computing
- computer architecture
- battery management system
- battery
- batteries
- Automotive engineering
- Automotive cyber-physical systems
- automotive controllers