High-speed SABER Key Encapsulation Mechanism in 65nm CMOS

Malik Imran; Felipe Almeida; Andrea Basso; Sujoy Sinha Roy; Samuel Pagliarini

doi:10.1007/s13389-023-00316-2

High-speed SABER Key Encapsulation Mechanism in 65nm CMOS

Malik Imran^*, Felipe Almeida, Andrea Basso, Sujoy Sinha Roy, Samuel Pagliarini

^*Corresponding author for this work

Institute of Applied Information Processing and Communications (7050)

Research output: Contribution to journal › Article › peer-review

Abstract

Quantum computers will break cryptographic primitives that are based on integer factorization and discrete logarithm problems. SABER is a key agreement scheme based on the Learning With Rounding problem that is quantum-safe, i.e., resistant to quantum computer attacks. This article presents a high-speed silicon implementation of SABER in a 65nm technology as an Application Specific Integrated Circuit. The chip measures 1mm ² in size and can operate at a maximum frequency of 715MHz at a nominal supply voltage of 1.2V. Our chip takes 10, 9.9 and 13μ s for the computation of key generation, encapsulation, and decapsulation operations of SABER. The average power consumption of the chip is 153.6mW. Physical measurements reveal that our design is 8.96x (for key generation), 11.80x (for encapsulation), and 11.23x (for decapsulation) faster than the best known silicon-proven SABER implementation.

Original language	English
Pages (from-to)	461-471
Number of pages	11
Journal	Journal of Cryptographic Engineering
Volume	13
Issue number	4
Early online date	29 Mar 2023
DOIs	https://doi.org/10.1007/s13389-023-00316-2
Publication status	Published - Nov 2023

Keywords

ASIC
Crypto accelerator
Post-quantum
SABER
Silicon-proven

ASJC Scopus subject areas

Software
Computer Networks and Communications

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10.1007/s13389-023-00316-2

Cite this

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title = "High-speed SABER Key Encapsulation Mechanism in 65nm CMOS",

abstract = "Quantum computers will break cryptographic primitives that are based on integer factorization and discrete logarithm problems. SABER is a key agreement scheme based on the Learning With Rounding problem that is quantum-safe, i.e., resistant to quantum computer attacks. This article presents a high-speed silicon implementation of SABER in a 65nm technology as an Application Specific Integrated Circuit. The chip measures 1mm 2 in size and can operate at a maximum frequency of 715MHz at a nominal supply voltage of 1.2V. Our chip takes 10, 9.9 and 13μ s for the computation of key generation, encapsulation, and decapsulation operations of SABER. The average power consumption of the chip is 153.6mW. Physical measurements reveal that our design is 8.96x (for key generation), 11.80x (for encapsulation), and 11.23x (for decapsulation) faster than the best known silicon-proven SABER implementation.",

keywords = "ASIC, Crypto accelerator, Post-quantum, SABER, Silicon-proven",

author = "Malik Imran and Felipe Almeida and Andrea Basso and {Sinha Roy}, Sujoy and Samuel Pagliarini",

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AU - Imran, Malik

AU - Almeida, Felipe

AU - Basso, Andrea

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AU - Pagliarini, Samuel

PY - 2023/11

Y1 - 2023/11

N2 - Quantum computers will break cryptographic primitives that are based on integer factorization and discrete logarithm problems. SABER is a key agreement scheme based on the Learning With Rounding problem that is quantum-safe, i.e., resistant to quantum computer attacks. This article presents a high-speed silicon implementation of SABER in a 65nm technology as an Application Specific Integrated Circuit. The chip measures 1mm 2 in size and can operate at a maximum frequency of 715MHz at a nominal supply voltage of 1.2V. Our chip takes 10, 9.9 and 13μ s for the computation of key generation, encapsulation, and decapsulation operations of SABER. The average power consumption of the chip is 153.6mW. Physical measurements reveal that our design is 8.96x (for key generation), 11.80x (for encapsulation), and 11.23x (for decapsulation) faster than the best known silicon-proven SABER implementation.

AB - Quantum computers will break cryptographic primitives that are based on integer factorization and discrete logarithm problems. SABER is a key agreement scheme based on the Learning With Rounding problem that is quantum-safe, i.e., resistant to quantum computer attacks. This article presents a high-speed silicon implementation of SABER in a 65nm technology as an Application Specific Integrated Circuit. The chip measures 1mm 2 in size and can operate at a maximum frequency of 715MHz at a nominal supply voltage of 1.2V. Our chip takes 10, 9.9 and 13μ s for the computation of key generation, encapsulation, and decapsulation operations of SABER. The average power consumption of the chip is 153.6mW. Physical measurements reveal that our design is 8.96x (for key generation), 11.80x (for encapsulation), and 11.23x (for decapsulation) faster than the best known silicon-proven SABER implementation.

KW - ASIC

KW - Crypto accelerator

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High-speed SABER Key Encapsulation Mechanism in 65nm CMOS

Abstract

Keywords

ASJC Scopus subject areas

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