Jeyavijayan Rajendran, G. Rose, R. Karri, M. Potkonjak
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CMOS devices have been used to build hardware security primitives such as physical unclonable functions. Since MOS devices are relatively easy to model and simulate, CMOS-based security primitives are increasingly prone to modeling attacks. We propose memristor-based Public Physical Unclonable Functions (nano-PPUFs), they have complex models that are difficult to simulate. We leverage sneak path currents, process variations, and computationally intensive SPICE models as features to build the nano-PPUF. With just a few hundreds of memristors, we construct a time-bounded authentication protocol that will take several years for an attacker to compromise.
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