PUF-based Key Generation with Design Margin Reduction via In-Situ and PVT Sensor Fusion

ESSCIRC 2019 - IEEE 45th European Solid State Circuits Conference (ESSCIRC) Pub Date : 2019-09-01 DOI:10.1109/ESSCIRC.2019.8902733

Sachin Taneja, M. Alioto

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Abstract

This work introduces a Physically Unclonable Function (PUF) based key generation scheme with run-time in-situ instability detection and process/voltage/temperature (PVT) sensors. Such sensors are fused to evaluate the sufficient number of correction bits NECC required by Error Correcting Code (ECC) to make the PUF output stable, and meet a given key error rate target. Run-time sensing overcomes the substantial ECC energy penalty associated with the traditional design-time margin of NECC for worst-case word, die, voltage and temperature. ECC with tunable NECC is introduced to enable energy saving in typical cases where NECC is lower than its worst-case value. Sensor fusion via simple linear regression estimates the required NECC at run-time.A testchip in 40 nm demonstrates the concept, based on a static monostable current mirror PUF with NECC = 0…4. Average energy reduction by 1.8X is shown compared to a traditional margined design, at an area overhead of less than 20%. As additional benefit of adjustable NECC, such energy savings can be further expanded under applications having less stringent stability requirements.

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基于原位和PVT传感器融合的减小设计余量的puf密钥生成

本文介绍了一种基于物理不可克隆函数(PUF)的密钥生成方案，该方案具有运行时原位不稳定性检测和过程/电压/温度(PVT)传感器。这些传感器被融合以评估ECC (Error Correcting Code，纠错码)所需要的足够数量的纠错位，以使PUF输出稳定，并满足给定的关键错误率目标。运行时传感克服了大量的ECC能量损失，这与传统的NECC设计时间裕度有关，包括最坏情况、芯片、电压和温度。介绍了带可调NECC的ECC，用于在NECC低于最坏情况值的典型情况下实现节能。传感器融合通过简单的线性回归在运行时估计所需的NECC。40nm的测试芯片基于静态单稳态电流镜PUF (NECC = 0…4)演示了该概念。与传统的边缘设计相比，平均能耗降低1.8倍，面积开销不到20%。作为可调NECC的额外好处，这种节能可以在稳定性要求不那么严格的应用中进一步扩大。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ESSCIRC 2019 - IEEE 45th European Solid State Circuits Conference (ESSCIRC)

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