基于碳纳米管场效应管的物理不可克隆功能

M. Moradi, S. Tao, R. F. Mirzaee
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引用次数: 6

摘要

物理不可克隆函数(puf)是为保护资源受限设备而提出的一种新的硬件安全原语。本文介绍了电压模式和电流模式下的两种puf。新的设计是基于碳纳米管场效应晶体管(cntfet)。对强工艺变化的敏感性被认为是这种新兴纳米级器件的缺点。然而,这个缺陷可能是构造唯一PUF实例的根源。新思HSPICE采用标准的32nm CNTFET技术对所提出的电路进行了模拟和测试。对所实现的基于cntfet的puf的随机性、唯一性、可靠性、能效和面积等特性进行了评价,显示出非常有希望的结果。
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Physical Unclonable Functions Based on Carbon Nanotube FETs
Physical unclonable functions (PUFs) are new hardware security primitives proposed for protecting resource-constrained devices. This paper presents two PUFs in voltage-and current-modes. The new designs are based on carbon nanotube field effect transistors (CNTFETs). Sensitivity to strong process variation is considered as a demerit of this emerging nanoscale device. However, this deficiency can be the source of constructing unique PUF instances. The proposed circuits are simulated and tested by Synopsys HSPICE using a standard 32nm CNTFET technology. The properties of randomness, uniqueness, reliability, energy efficiency, and area of the implemented CNTFET-based PUFs are evaluated showing very promising results.
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