Biblio

Logic locking is a well-explored defense mechanism against various types of hardware security attacks. Recent approaches to logic locking replace portions of a circuit with reconfigurable blocks such as look-up tables (LUTs) and switch boxes (SBs) to primarily achieve logic and routing obfuscation, respectively. However, these techniques may incur significant design overhead, and methods that can mitigate the implementation cost for a given security level are desirable. In this paper, we address this challenge by proposing an algorithm for deciding the location and inputs of the LUTs in LUT-based obfuscation to enhance security and reduce design overhead. We then introduce a locking method that combines LUTs with SBs to further robustify LUT-based obfuscation, largely independently of the specific LUT locations. We illustrate the effectiveness of the proposed approaches on a set of ISCAS benchmark circuits.

Alongside the rapid expansion of Internet of Things (IoT), and network evolution (5G, 6G technologies), comes the need for security of higher level and less hardware demanding modules. New cryptographic systems are developed, in order to satisfy the special needs of security, that have emerged in modern applications. In this paper, a novel lightweight data streaming system, is proposed, which operates in alternative modes. Each one of them, performs efficiently as one of three in total, stream ciphering modules. The operation of the proposed system, is based on reconfigurable logic. It aims at a lower hardware utilization and good performance, at the same time. In addition, in order to have a fair and detailed comparison, a second one design is also integrated and introduced. This one proposes a conventional architecture, consisting of the same three stream ciphering modes, implemented on the same device, as separate operation modules. The FPGA synthesis results prove that the proposed reconfigurable design achieves to minimize the area resources, from 18% to 30%, compared to the conventional one, while maintaining high performance values, for the supported modes.

Malicious Hardware Trojans can corrupt data which if undetected may cause serious harm. We propose a technique where characteristics of the data itself are used to detect Hardware Trojan (HT) attacks. In particular, we use a two-chip approach where we generate a data "signature" in analog and test for the signature in a partially reconfigurable digital microchip where the HT may attack. This paper presents an overall signature-based HT detection architecture and case study for cardiovascular signals used in medical device technology. Our results show that with minimal performance and area overhead, the proposed architecture is able to detect HT attacks on primary data inputs as well as on multiple modules of the design.