Resistive Memory for Computing and Security: Algorithms, Architectures, and Platforms

Abstract: Resistive random-access memory (RRAM) is gaining popularity due to its ability to offer computing within the memory and its non-volatile nature. The unique properties of RRAM, such as binary switching, multi-state switching, and device variations, can be leveraged to design novel techniques and algorithms. This thesis proposes a technique for utilizing RRAM devices in three major directions: i) digital logic implementation, ii) multi-valued computing, and iii) hardware security primitive design. We proposed new algorithms and architectures and conducted \textit{experimental studies} on each implementation. Moreover, we developed the electronic design automation framework and hardware platforms to facilitate these experiments.