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Title:
Depth Optimized Quantum Circuits for HIGHT and LEA

Authors: Kyungbae Jang, Yujin Oh, Minwoo Lee, Dukyoung Kim, Hwajeong Seo

Quantum computers can model and solve several problems that have posed challenges for classical super computers, leveraging their natural quantum mechanical characteristics. A large-scale quantum computer is poised to significantly reduce security strength in cryptography. In this context, extensive research has been conducted on quantum cryptanalysis. In this paper, we present optimized quantum circuits for Korean block ciphers, HIGHT and LEA. Our quantum circuits for HIGHT and LEA demonstrate the lowest circuit depth compared to previous results. Specifically, we achieve depth reductions of 48% and 74% for HIGHT and LEA, respectively. We employ multiple novel techniques that effectively reduce the quantum circuit depth with a reasonable increase in qubit count. Based on our depth-optimized quantum circuits for HIGHT and LEA block ciphers, we estimate the lowest quantum attack complexity for Grover’s key search. Our quantum circuit can be utilized for other quantum algorithms, not only for Grover’s algorithm. Furthermore, the optimization methods gathered in this work can be adopted for generic quantum implementations in cryptography.

ePrint: https://eprint.iacr.org/2024/1221

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