Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma

Neelam Nasir; Julien Béguinot; Wei Cheng; Ulrich Kühne; Jean Luc Danger

doi:10.1007/978-3-032-01405-4_16

Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma

Neelam Nasir
, Julien Béguinot
, Wei Cheng
, Ulrich Kühne
, Jean Luc Danger

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Contribution à une conférence › Revue par des pairs

Résumé

Strong physical unclonable functions (PUFs) provide a cost-effective authentication solution for resource-limited devices. However, they are susceptible to machine learning (ML) attacks. The lightweight defenses against ML rely on adding non-linearity in the PUF behavior (as the XOR-PUF), or limiting the number of challenges at protocol level (as the lockdown protocol) to constrain learning. Another low-cost approach is to use a non-linear quantization of the response when the PUF provides an integer response, like the RO-PUF. This paper studies the non-monotonic quantization (NMQ) which greatly enhances the security when a large number of quantization level is used. Unfortunately, this makes the PUF highly unreliable, rendering it impractical for authentication purposes. In this study, we propose a solution which circumvents the intrinsic PUF unreliability of NMQ to build an effective authentication protocol. It relies on the Neyman-Pearson test which transforms the native dependability of responses into an asset to get a reliable authentication protocol. To validate this approach, we evaluate our solution in FPGA using a loop PUF (ring oscillator-based PUF) which is a multi-bin PUF. The results show that an authentication success of nearly 100% can be obtained with a high resistance as up to 60% accuracy against three types of ML attacks.

langue originale	Anglais
titre	Constructive Approaches for Security Analysis and Design of Embedded Systems - 1st International Conference, CASCADE 2025, Proceedings
rédacteurs en chef	Matthieu Rivain, Pascal Sasdrich
Editeur	Springer Science and Business Media Deutschland GmbH
Pages	387-409
Nombre de pages	23
ISBN (imprimé)	9783032014047
Les DOIs	https://doi.org/10.1007/978-3-032-01405-4_16
état	Publié - 1 janv. 2026
Evénement	1st International Conference on Constructive Approaches for Security Analysis and Design of Embedded Systems, CASCADE 2025 - Saint-Etienne, France Durée: 2 avr. 2025 → 4 avr. 2025

Série de publications

Nom	Lecture Notes in Computer Science
Volume	15952 LNCS
ISSN (imprimé)	0302-9743
ISSN (Electronique)	1611-3349

Une conférence

Une conférence	1st International Conference on Constructive Approaches for Security Analysis and Design of Embedded Systems, CASCADE 2025
Pays/Territoire	France
La ville	Saint-Etienne
période	2/04/25 → 4/04/25

Accès au document

10.1007/978-3-032-01405-4_16

Autres fichiers et liens

Lien vers la publication dans Scopus

Contient cette citation

Nasir, N., Béguinot, J., Cheng, W., Kühne, U., & Danger, J. L. (2026). Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma. Dans M. Rivain, & P. Sasdrich (eds.), Constructive Approaches for Security Analysis and Design of Embedded Systems - 1st International Conference, CASCADE 2025, Proceedings (p. 387-409). (Lecture Notes in Computer Science; Vol 15952 LNCS). Springer Science and Business Media Deutschland GmbH. https://doi.org/10.1007/978-3-032-01405-4_16

Nasir, Neelam ; Béguinot, Julien ; Cheng, Wei et al. / Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma. Constructive Approaches for Security Analysis and Design of Embedded Systems - 1st International Conference, CASCADE 2025, Proceedings. Editeur / Matthieu Rivain ; Pascal Sasdrich. Springer Science and Business Media Deutschland GmbH, 2026. p. 387-409 (Lecture Notes in Computer Science).

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abstract = "Strong physical unclonable functions (PUFs) provide a cost-effective authentication solution for resource-limited devices. However, they are susceptible to machine learning (ML) attacks. The lightweight defenses against ML rely on adding non-linearity in the PUF behavior (as the XOR-PUF), or limiting the number of challenges at protocol level (as the lockdown protocol) to constrain learning. Another low-cost approach is to use a non-linear quantization of the response when the PUF provides an integer response, like the RO-PUF. This paper studies the non-monotonic quantization (NMQ) which greatly enhances the security when a large number of quantization level is used. Unfortunately, this makes the PUF highly unreliable, rendering it impractical for authentication purposes. In this study, we propose a solution which circumvents the intrinsic PUF unreliability of NMQ to build an effective authentication protocol. It relies on the Neyman-Pearson test which transforms the native dependability of responses into an asset to get a reliable authentication protocol. To validate this approach, we evaluate our solution in FPGA using a loop PUF (ring oscillator-based PUF) which is a multi-bin PUF. The results show that an authentication success of nearly 100\% can be obtained with a high resistance as up to 60\% accuracy against three types of ML attacks.",

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Nasir, N, Béguinot, J, Cheng, W, Kühne, U & Danger, JL 2026, Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma. Dans M Rivain & P Sasdrich (eds), Constructive Approaches for Security Analysis and Design of Embedded Systems - 1st International Conference, CASCADE 2025, Proceedings. Lecture Notes in Computer Science, VOL. 15952 LNCS, Springer Science and Business Media Deutschland GmbH, p. 387-409, 1st International Conference on Constructive Approaches for Security Analysis and Design of Embedded Systems, CASCADE 2025, Saint-Etienne, France, 2/04/25. https://doi.org/10.1007/978-3-032-01405-4_16

Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma. / Nasir, Neelam; Béguinot, Julien; Cheng, Wei et al.
Constructive Approaches for Security Analysis and Design of Embedded Systems - 1st International Conference, CASCADE 2025, Proceedings. Ed. / Matthieu Rivain; Pascal Sasdrich. Springer Science and Business Media Deutschland GmbH, 2026. p. 387-409 (Lecture Notes in Computer Science; Vol 15952 LNCS).

Résultats de recherche: Le chapitre dans un livre, un rapport, une anthologie ou une collection › Contribution à une conférence › Revue par des pairs

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AU - Nasir, Neelam

AU - Béguinot, Julien

AU - Cheng, Wei

AU - Kühne, Ulrich

AU - Danger, Jean Luc

N1 - Publisher Copyright: © The Author(s), under exclusive license to Springer Nature Switzerland AG 2026.

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N2 - Strong physical unclonable functions (PUFs) provide a cost-effective authentication solution for resource-limited devices. However, they are susceptible to machine learning (ML) attacks. The lightweight defenses against ML rely on adding non-linearity in the PUF behavior (as the XOR-PUF), or limiting the number of challenges at protocol level (as the lockdown protocol) to constrain learning. Another low-cost approach is to use a non-linear quantization of the response when the PUF provides an integer response, like the RO-PUF. This paper studies the non-monotonic quantization (NMQ) which greatly enhances the security when a large number of quantization level is used. Unfortunately, this makes the PUF highly unreliable, rendering it impractical for authentication purposes. In this study, we propose a solution which circumvents the intrinsic PUF unreliability of NMQ to build an effective authentication protocol. It relies on the Neyman-Pearson test which transforms the native dependability of responses into an asset to get a reliable authentication protocol. To validate this approach, we evaluate our solution in FPGA using a loop PUF (ring oscillator-based PUF) which is a multi-bin PUF. The results show that an authentication success of nearly 100% can be obtained with a high resistance as up to 60% accuracy against three types of ML attacks.

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KW - Neyman-Pearson test

KW - Non-monotonic quantization

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KW - Reliability

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Nasir N, Béguinot J, Cheng W, Kühne U, Danger JL. Robust and Reliable PUF Protocol Exploiting Non-monotonic Quantization and Neyman-Pearson Lemma. Dans Rivain M, Sasdrich P, rédacteurs en chef, Constructive Approaches for Security Analysis and Design of Embedded Systems - 1st International Conference, CASCADE 2025, Proceedings. Springer Science and Business Media Deutschland GmbH. 2026. p. 387-409. (Lecture Notes in Computer Science). doi: 10.1007/978-3-032-01405-4_16