A highly reliable dual-mode RRAM PUF with key concealment scheme

Jiang Li; Yijun Cui; Chongyan Gu; Chenghua Wang; Weiqiang Liu; Shahar Kvatinsky

doi:10.1109/TCAD.2025.3536376

A highly reliable dual-mode RRAM PUF with key concealment scheme

Jiang Li, Yijun Cui, Chongyan Gu, Chenghua Wang, Weiqiang Liu, Shahar Kvatinsky

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Abstract

Physical Unclonable Function (PUF) has been widely used in the Internet of Things (IoT) as a promising hardware security primitive. In recent years, PUFs based on resistive random access memory (RRAM) have demonstrated excellent reliability and integration density. Most previous designs store PUF keys directly in RRAMs, increasing vulnerability to attacks. This paper proposes a dual-mode RRAM PUF, named differential mode and flexible mode, utilizing the difference in switching capability between RRAMs during parallel SET operations as the entropy source. The proposed PUF can reliably reproduce keys between cycles, so a key concealment scheme is used to protect PUF keys from being continuously exposed, improving the security of the RRAM PUF. The proposed RRAM PUF exhibits high reliability over ± 10% VDD and a wide temperature range from -25∘C to 125∘C through post-processing operations. The flexible mode can generate a significant number of keys for high-security applications. Since the PUF keys can be concealed, the proposed PUF is compatible with in-memory computing. It can be implemented using the same RRAM array as experimentally validated using a MAGIC operation, thus reducing the hardware overhead.

Original language	English
Number of pages	13
Journal	IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems
Early online date	28 Jan 2025
DOIs	https://doi.org/10.1109/TCAD.2025.3536376
Publication status	Early online date - 28 Jan 2025

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A highly reliable dual-mode RRAM PUF with key concealment scheme
© 2025 The Authors. This is an accepted manuscript distributed under a Creative Commons Attribution License (https://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium, provided the author and source are cited
Accepted author manuscript, 15.4 MBLicence: CC BY

Cite this

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title = "A highly reliable dual-mode RRAM PUF with key concealment scheme",

abstract = "Physical Unclonable Function (PUF) has been widely used in the Internet of Things (IoT) as a promising hardware security primitive. In recent years, PUFs based on resistive random access memory (RRAM) have demonstrated excellent reliability and integration density. Most previous designs store PUF keys directly in RRAMs, increasing vulnerability to attacks. This paper proposes a dual-mode RRAM PUF, named differential mode and flexible mode, utilizing the difference in switching capability between RRAMs during parallel SET operations as the entropy source. The proposed PUF can reliably reproduce keys between cycles, so a key concealment scheme is used to protect PUF keys from being continuously exposed, improving the security of the RRAM PUF. The proposed RRAM PUF exhibits high reliability over ± 10\% VDD and a wide temperature range from -25∘C to 125∘C through post-processing operations. The flexible mode can generate a significant number of keys for high-security applications. Since the PUF keys can be concealed, the proposed PUF is compatible with in-memory computing. It can be implemented using the same RRAM array as experimentally validated using a MAGIC operation, thus reducing the hardware overhead.",

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AU - Li, Jiang

AU - Cui, Yijun

AU - Gu, Chongyan

AU - Wang, Chenghua

AU - Liu, Weiqiang

AU - Kvatinsky, Shahar

PY - 2025/1/28

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N2 - Physical Unclonable Function (PUF) has been widely used in the Internet of Things (IoT) as a promising hardware security primitive. In recent years, PUFs based on resistive random access memory (RRAM) have demonstrated excellent reliability and integration density. Most previous designs store PUF keys directly in RRAMs, increasing vulnerability to attacks. This paper proposes a dual-mode RRAM PUF, named differential mode and flexible mode, utilizing the difference in switching capability between RRAMs during parallel SET operations as the entropy source. The proposed PUF can reliably reproduce keys between cycles, so a key concealment scheme is used to protect PUF keys from being continuously exposed, improving the security of the RRAM PUF. The proposed RRAM PUF exhibits high reliability over ± 10% VDD and a wide temperature range from -25∘C to 125∘C through post-processing operations. The flexible mode can generate a significant number of keys for high-security applications. Since the PUF keys can be concealed, the proposed PUF is compatible with in-memory computing. It can be implemented using the same RRAM array as experimentally validated using a MAGIC operation, thus reducing the hardware overhead.

AB - Physical Unclonable Function (PUF) has been widely used in the Internet of Things (IoT) as a promising hardware security primitive. In recent years, PUFs based on resistive random access memory (RRAM) have demonstrated excellent reliability and integration density. Most previous designs store PUF keys directly in RRAMs, increasing vulnerability to attacks. This paper proposes a dual-mode RRAM PUF, named differential mode and flexible mode, utilizing the difference in switching capability between RRAMs during parallel SET operations as the entropy source. The proposed PUF can reliably reproduce keys between cycles, so a key concealment scheme is used to protect PUF keys from being continuously exposed, improving the security of the RRAM PUF. The proposed RRAM PUF exhibits high reliability over ± 10% VDD and a wide temperature range from -25∘C to 125∘C through post-processing operations. The flexible mode can generate a significant number of keys for high-security applications. Since the PUF keys can be concealed, the proposed PUF is compatible with in-memory computing. It can be implemented using the same RRAM array as experimentally validated using a MAGIC operation, thus reducing the hardware overhead.

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SN - 0278-0070

JO - IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems

JF - IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems

ER -

A highly reliable dual-mode RRAM PUF with key concealment scheme

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