Quantum Implementation of AIM: Aiming for Low-Depth

Quantum Implementation of AIM: Aiming for Low-Depth

Security vulnerabilities in the symmetric-key primitives of a cipher can undermine the overall security claims of the cipher. With the rapid advancement of quantum computing in recent years, there is an increasing effort to evaluate the security of symmetric-key cryptography against potential quantu...

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Veröffentlicht in:Applied sciences 2024-04, Vol.14 (7), p.2824
Hauptverfasser: Jang, Kyungbae, Oh, Yujin, Kim, Hyunji, Seo, Hwajeong
Format: Artikel
Sprache:eng
Schlagworte:
AIM
AIMer
Algorithms
Analysis
Circuits
Computers
Costs
Cryptography
Data security
Digital signatures
Estimates
Grover’s search
Integrated circuits
Investment analysis
Quantum computing
Semiconductor chips
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Zusammenfassung:Security vulnerabilities in the symmetric-key primitives of a cipher can undermine the overall security claims of the cipher. With the rapid advancement of quantum computing in recent years, there is an increasing effort to evaluate the security of symmetric-key cryptography against potential quantum attacks. This paper focuses on analyzing the quantum attack resistance of AIM, a symmetric-key primitive used in the AIMer digital signature scheme. We present the first quantum circuit implementation of AIM and estimate its complexity (such as qubit count, gate count, and circuit depth) with respect to Grover’s search algorithm. For Grover’s key search, the most important optimization metric is depth, especially when considering parallel search. Our implementation gathers multiple methods for a low-depth quantum circuit of AIM in order to reduce the Toffoli depth and full depth (such as the Karatsuba multiplication and optimization of inner modules; Mer, LinearLayer).
ISSN:2076-3417
2076-3417
DOI:10.3390/app14072824