Visible to the public Biblio

Filters: Author is Beroulle, V.  [Clear All Filters]
2021-03-29
Kazemi, Z., Fazeli, M., Hély, D., Beroulle, V..  2020.  Hardware Security Vulnerability Assessment to Identify the Potential Risks in A Critical Embedded Application. 2020 IEEE 26th International Symposium on On-Line Testing and Robust System Design (IOLTS). :1—6.

Internet of Things (IoT) is experiencing significant growth in the safety-critical applications which have caused new security challenges. These devices are becoming targets for different types of physical attacks, which are exacerbated by their diversity and accessibility. Therefore, there is a strict necessity to support embedded software developers to identify and remediate the vulnerabilities and create resilient applications against such attacks. In this paper, we propose a hardware security vulnerability assessment based on fault injection of an embedded application. In our security assessment, we apply a fault injection attack by using our clock glitch generator on a critical medical IoT device. Furthermore, we analyze the potential risks of ignoring these attacks in this embedded application. The results will inform the embedded software developers of various security risks and the required steps to improve the security of similar MCU-based applications. Our hardware security assessment approach is easy to apply and can lead to secure embedded IoT applications against fault attacks.

2018-05-01
Fraj, R. Ben, Beroulle, V., Fourty, N., Meddeb, A..  2017.  A Global Approach for the Improvement of UHF RFID Safety and Security. 2017 12th International Conference on Design Technology of Integrated Systems In Nanoscale Era (DTIS). :1–2.
Radio Frequency Identification (RFID) devices are widely used in many domains such as tracking, marking and management of goods, smart houses (IoT), supply chains, etc. However, there is a big number of challenges which must still be overcome to ensure RFID security and privacy. In addition, due to the low cost and low consumption power of UHF RFID tags, communications between tags and readers are not robust. In this paper, we present our approach to evaluate at the same time the security and the safety of UHF RFID systems in order to improve them. First, this approach allows validating UHF RFID systems by simulation of the system behavior in presence of faults in a real environment. Secondly, evaluating the system robustness and the security of the used protocols, this approach will enable us to propose the development of new more reliable and secure protocols. Finally, it leads us to develop and validate new low cost and secure tag hardware architectures.