Detection and Identification of Malicious Cyber-Attacks in Connected and Automated Vehicles’ Real-Time Sensors

Elvin Eziama,Faroq Awin,Luz Marina Santos-Jaimes,Danilo Corral-De-Witt,Sabbir Ahmed,Akinyemi Pelumi

doi:10.3390/app10217833

Abstract

Connected and automated vehicles (CAVs) as a part of Intelligent Transportation Systems (ITS) are projected to revolutionise the transportation industry, primarily by allowing real-time and seamless information exchange of vehicle-to-vehicle (V2V) and vehicle-to-infrastructure (V2I). However, these connectivity and automation are expected to offer vast numbers of benefits, new challenges in terms of safety, security and privacy also emerge. CAVs continue to rely heavily on their sensor readings, the input obtained from other vehicles and the road side units to inspect roadways. Consequently, anomalous reading of sensors triggered by malicious cyber attacks may lead to fatal consequences. Hence, like all other safety-critical applications, in CAVs also, reliable and secure information dissemination is of utmost importance. As a result, real time detection of anomaly along with identifying the source is a pre-requisite for mass deployment of CAVs. Motivated by this safety concerns in CAVs, we develop an efficient anomaly detection method through the combination of Bayesian deep learning (BDL) with discrete wavelet transform (DWT) to improve the safety and security in CAVs. In particular, DWT is used to smooth sensor reading of a CAV and then feed the data to a BDL module for analysis of the detection and identification of anomalous sensor behavior/data points caused by either malicious cyber attacks or faulty vehicle sensors. Our numerical experiments show that the proposed method demonstrates significant improvement in detection anomalies in terms of accuracy, sensitivity, precision, and F1-score evaluation metrics. For these metrics, the proposed method shows an average performance gain of 7.95%, 9%, 8.77% and 7.33%, respectively when compared with Convolutional Neural Network (CNN-1D), and when compared with BDL, the corresponding numbers are 5%, 7.9%, 7.54% and 4.1% respectively.

Highlights

Intelligent transportation (IT) is an emerging technology where a large number of vehicles can collect, process and communicate information to make collaborative decisions without direct human intervention [1], through Vehicle to Vehicle (V2V) and Vehicle to Infrastructure (V2I) communications.Taking into account the enormous benefits expected from vehicular communications and the number of vehicles, it is evident that vehicular communications will possibly become the most important mobile ad hoc network realization
We develop anomaly detection approach through combining Bayesian deep learning (BDL), with a well established filter techniques, discrete wavelet transform (DWT), applied to time series basic safety messages (BSMs) data obtained from multiple sensors
The three anomaly types are simulated from the Connected and Automated Vehicles (CAVs) data-set with varying anomaly durations, magnitudes of network density and the anomaly rate α to draw insight on the performance strength from the use of convolutional neural network (CNN), BDL, and the proposed approach (DWT-BDL) in detecting/identifying anomalous sensor behaviors in real-time

Summary

Introduction

Intelligent transportation (IT) is an emerging technology where a large number of vehicles can collect, process and communicate information to make collaborative decisions without direct human intervention [1], through Vehicle to Vehicle (V2V) and Vehicle to Infrastructure (V2I) communications.Taking into account the enormous benefits expected from vehicular communications and the number of vehicles (millions worldwide), it is evident that vehicular communications will possibly become the most important mobile ad hoc network realization. Intelligent transportation (IT) is an emerging technology where a large number of vehicles can collect, process and communicate information to make collaborative decisions without direct human intervention [1], through Vehicle to Vehicle (V2V) and Vehicle to Infrastructure (V2I) communications. Statistics show that as of 2018, in US alone traffic accident amounts to a total of 36,473 deaths and traffic congestion resulted in the economic cost of about 115 billion US Dollars [2]. This impending situation calls for meaningful enhancement of transportation safety and efficiency. A promising approach to this end is to integrate transportation systems with information technology in an intelligent fashion, where V2Vs communication networks have been envisioned as an indispensable component

Methods

Results

Discussion

Conclusion