Networking activities of many different forms have taken place primarily in a virtual setting. The SAFEST project has organized two events in year 1, namely a summer school and a workshop, two summer schools in year 2, and a summer school and a workshop in year 3. The events were fairly well attended and covered all topical areas of interest for the project. Many other exchanges took place via numerous online meeting (i.e. Zoom conf. calls). The SAFEST project had 131 of such meetings, indicating a high level of cohesion and commitment of the project partners.
In terms of practical results achieved, these appears as jointly-authored publications of the SAFEST partners. For the purpose of this short report, we will highlight two articles:
- In “Hardware Obfuscation of Digital FIR Filters”, researchers from TalTech and TUM investigated how to protect digital circuits against reverse engineering practices. This work was published as a conference paper in the 25th International Symposium on Design and Diagnostics of Electronic Circuits and Systems (DDECS 2022). This work has received a best paper award. An image related to this work is provided, where the reverse engineering view of the many connections of a circuit is given. This type of analysis is performed by both attackers and defenders, albeit with different goals, naturally.
- In “Design Space Exploration of SABER in 65nm ASIC”, researchers from TalTech and TUG investigated how to accelerate cryptographic operations in hardware. This work was published as a conference paper in the Workshop on Attacks and Solutions in Hardware Security (ASHES ’21). Here we highlight that this work is incredibly representative of the spirit of the Twinning collaboration in SAFEST: TalTech provided its expertise in chip design while TUG provided its expertise in security. Together, both partners worked on a chip that serves as a demonstrator of their effort. Furthermore, the cryptographic algorithm utilized in this work (SABER) is currently being considered for standardization, thus showing how relevant and timely the research on this topic is. An image related to this work is provided, where our tiny chip that measures only 1mm x 1mm has been photographed under a microscope.