Samuel Pagliarini scite author profile

In today's integrated circuit (IC) ecosystem, owning a foundry is not economically viable, and therefore most IC design houses are now working under a fabless business model. In order to overcome security concerns associated with the outsorcing of IC fabrication, the Split Manufacturing technique was proposed. In Split Manufacturing, the Front End of Line (FEOL) layers (transistors and lower metal layers) are fabricated at an untrusted high-end foundry, while the Back End of Line (BEOL) layers (higher metal layers) are manufactured at a trusted low-end foundry. This approach hides the BEOL connections from the untrusted foundry, thus preventing overproduction and piracy threats. However, many works demonstrate that BEOL connections can be derived by exploiting layout characteristics that are introduced by heuristics employed in typical floorplanning, placement, and routing algorithms. Since straightforward Split Manufacturing may not afford a desirable security level, many authors propose defense techniques to be used along with Split Manufacturing. In our survey, we present a detailed overview of the technique, the many types of attacks towards Split Manufacturing, as well as possible defense techniques described in the literature. For the attacks, we present a concise discussion on the different threat models and assumptions, while for the defenses we classify the studies into three categories: proximity perturbation, wire lifting, and layout obfuscation. The main outcome of our survey is to highlight the discrepancy between many studiessome claim netlists can be reconstructed with near perfect precision, while others claim marginal success in retrieving BEOL connections. Finally, we also discuss future trends and challenges inherent to Split Manufacturing, including the fundamental difficulty of evaluating the efficiency of the technique.

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High-level Intellectual Property Obfuscation via Decoy Constants

Aksoy

Nguyen

Almeida

et al. 2021

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A Fault Tolerant Approach to Detect Transient Faults in Microprocessors Based on a Non-Intrusive Reconfigurable Hardware

Azambuja

Pagliarini

Altieri

et al. 2012

IEEE Trans. Nucl. Sci.

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International audienceThis paper presents a non-intrusive hybrid fault detection approach that combines hardware and software techniques to detect transient faults in microprocessors. Such faults have a major influence in microprocessor-based systems, affecting both data and control flow. In order to protect the system, an application-oriented hardware module is automatically generated and reconfigured on the system during runtime. When combined with fault tolerance techniques based on software, this solution offers full system protection against transient faults. A fault injection campaign is performed using a MIPS microprocessor executing a set of applications. HW/SW implementation in a reprogrammable platform shows smaller memory area and execution time overhead when compared to related works. Fault injection results show the efficiency of this method by detecting 100% of faults

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