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25.2 A Reconfigurable RRAM Physically Unclonable Function Utilizing Post-Process Randomness Source With <6×10?6 Native Bit Error Rate

机译：25.2利用<6×10 的后处理随机性源的可重新配置的RRAM物理不可渗透函数，其中<6×10 6 本机塔错误率

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Physically unclonable functions (PUFs) are promising primitives for hardware security with wide applications in the lnternet of Things (IoT), e.g., authentication and encryption key generation [1, 2]. Most silicon PUFs utilize process variability of semiconductor manufacturing [1, 3, 4]. These implementations are sensitive to variations in operating conditions (e.g., supply voltage and temperature variations) and undergo significant native bit-error-rates (N-BERs). Thus, additional stabilizing strategies, such as ECC, majority voting, and masking, are necessary. Furthermore, the PUF key after enrollment cannot be changed in prior implementations [1-5]. This could be unsafe if the PUFs are repeatedly used in insecure environments, as PUFs suffer from the challenges of ownership change and overuse (Fig. 25.2.1).

机译：物理上不可渗透的功能（PUFS）是用于硬件安全性的有前途的原语，在物品（物联网）的Lnternet中具有广泛的应用程序，例如，身份验证和加密密钥生成[1,2]。大多数硅PUFS利用半导体制造的过程变化[1,3,4]。这些实现对操作条件（例如，电源电压和温度变化）的变化敏感，并且经历了显着的天然误码率（N-BERS）。因此，需要额外的稳定策略，例如ECC，大多数投票和掩蔽。此外，在现有实现中不能更改注册后的PUF键[1-5]。如果PUF在不安全的环境中反复使用PUF，这可能是不安全的，因为PUFS遭受所有权变化和过度使用的挑战（图25.2.1）。

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《IEEE International Solid- State Circuits Conference》|2019年|536 p. :|共3页
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Yachuan Pang; Bin Gao; Dong Wu; Shengyu Yi; Qi Liu; Wei-Hao Chen; Ting-Wei Chang; Wei-En Lin; Xiaoyu Sun; Shimeng Yu; He Qian; Meng-Fan Chang; Huaqiang Wu;
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中图分类半导体集成电路（固体电路）;
关键词
Resistance; Computer architecture; Microprocessors; Correlation; Security; Decoding; Semiconductor device measurement;

机译：抵抗;计算机架构;微处理器;相关;安全;解码;半导体器件测量;

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专利

1. Static Physically Unclonable Functions for Secure Chip Identification With 1.9–5.8% Native Bit Instability at 0.6–1 V and 15 fJ/bit in 65 nm [J] . Anastacia B. Alvarez, Wenfeng Zhao, Massimo Alioto IEEE Journal of Solid-State Circuits . 2016,第3期

机译：静态物理上无法克隆的功能，可确保芯片识别安全，在0.6–1 V和65 nm的15 fJ / bit时具有1.9–5.8％的固有位不稳定性
2. Spin-orbit torque-based reconfigurable physically unclonable functions [J] . Jian Zhang, Zhe Guo, Shuai Zhang, Applied Physics Letters . 2020,第19期

机译：基于旋转轨道扭矩的可重新配置物理不可渗透功能
3. 0.67-μm2/bitcell two-transistor leakage-based physically unclonable function with native bit-instability of 0.89% at 65 nm [J] . Li Gang, Wang Pengjun, Ma Xuejiao, Electronics Letters . 2020,第23期

机译：0.67-μm2/位电池双晶体管泄漏的物理上不可渗透功能，目的位不稳定为0.89％，65 nm
4. 25.2 A Reconfigurable RRAM Physically Unclonable Function Utilizing Post-Process Randomness Source With <6×10⁻⁶ Native Bit Error Rate [C] . Yachuan Pang, Bin Gao, Dong Wu, IEEE International Solid- State Circuits Conference . 2019

机译：25.2利用后处理随机性源具有<6×10 ^{−6 本机误码率的可重配置RRAM物理上不可克隆的功能}
5. Development of a Field Deploy Able Bit Error Rate Tester for 10 Gigabit Fiber Optic by Utilizing Field Programmable Gate Array Technology [D] . howell, Jeremy Brandon. 2020

机译：通过利用现场可编程门阵列技术，开发一个现场部署的钻头误差率测试仪10千兆光纤测试仪
6. Design of Resistor-Capacitor Physically Unclonable Function for Resource-Constrained IoT Devices [O] . Sangjae Lee, Mi-Kyung Oh, Yousung Kang, 2020

机译：资源受限物联网设备的电阻电容物理不可克隆功能设计
7. 0.67‐μm 2 /bitcell two‐transistor leakage‐based physically unclonable function with native bit‐instability of 0.89 at 65 nm [O] . Gang Li, Pengjun Wang, Xuejiao Ma, 2020

机译：0.67-μm2 /位电池两晶体管泄漏的物理上不可渗透功能，目的位 - 不稳定性为0.89％，65 nm
8. Narrowband (LPC-10) Vocoder Performance under Combined Effects of Random Bit Errors and Jet Aircraft Cabin Noise [R] . Smith, C. P. 1983

机译：随机比特误差与喷气式飞机机舱噪声组合效应下的窄带（LpC-10）声码器性能

25.2 A Reconfigurable RRAM Physically Unclonable Function Utilizing Post-Process Randomness Source With <6×10?6 Native Bit Error Rate

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