中文

ARMOR-IMC: Adaptive Resource Mapping for Operational Robustness via Secure In-Memory Computing

密码学与安全 2026-07-12 v1 新兴技术

摘要

The massive data-movement overhead in traditional architectures has led to the adoption of In-Memory Computing (IMC) for energy-efficient Deep Neural Network (DNN) processing. By leveraging emerging devices like Spin-Orbit Torque Magnetic Tunnel Junctions (SOT-MTJs), IMC bypasses the "memory wall" and reduces leakage power inherent in traditional CMOS. However, this shift introduces dual hardware threats: manufacturing Process Variation (PV) degrades reliability and increases vulnerability to fault injection, while power Side-Channel Attacks (SCAs) compromise security. Existing defenses address these threats in isolation. This work presents a posttraining framework that simultaneously hardens analog IMC accelerators against both threats without retraining the model. Implemented in the IMAC-Sim simulator, our approach uses the proposed Variation Impact Score (VIS) to guide the mapping of Fault Observation Windows (FOWs) and introduces the Leakage Per Inference (LPI) metric to quantify input-dependent power variability under stochastic injection and the resulting reduction in effective signal-to-noise ratio. Experiments show that PV-induced faults can degrade accuracy by over 50%, while our method restores near-baseline accuracy and mitigates the threat of correlation-based power analysis attacks.

引用

@article{arxiv.2607.10938,
  title  = {ARMOR-IMC: Adaptive Resource Mapping for Operational Robustness via Secure In-Memory Computing},
  author = {Muhtasim Alam Chowdhury and Ramtin Zand and Soheil Salehi},
  journal= {arXiv preprint arXiv:2607.10938},
  year   = {2026}
}

备注

4 pages, 5 figures. Accepted for presentation at the IEEE International Conference on Omni-Layer Intelligent Systems (COINS 2026)