用量子近似优化算法解码m -玛利线性码

Markel Epelde, E. Combarro, I. F. R ́ua,
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引用次数: 0

摘要

摘要最小距离译码问题(MDDP)的NP硬度是McEliece密码系统的核心。将接收到的字解码为给定任意代码中最接近的码字的难度是其安全性的关键。与MDDP相关的是Coset Leader问题(CLP),该问题包括找到给定综合征和最小Hamming权重的单词。两者都可以被建模为优化问题,并使用量子近似优化算法(QAOA)来解决,这是一种著名的量子-经典混合算法。在本文中,我们对任意m元字母上的线性码的MDDP和CLP进行了建模,对二进制CLP问题进行了第一级的理论分析,并介绍了一些实验来测试其性能。实验在量子计算机模拟器和真实量子设备上进行,并使用不同长度和不同深度的QAOA代码。
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DECODING M-ARY LINEAR CODES WITH THE QUANTUM APPROXIMATE OPTIMIZATION ALGORITHM
Abstract The NP-hardness of the Minimum Distance Decoding Problem (MDDP) is the core of the McEliece cryptosystem. The difficulty of decoding a received word to the closest codeword in a given arbitrary code is key to its security. Related to the MDDP is the Coset Leader Problem (CLP), which consists in finding a word of a given syndrome and minimum Hamming weight. Both can be modelled as optimization problems, and solved using the Quantum Approximate Optimization Algorithm (QAOA), a well-known hybrid quantum- classical algorithm. In this paper, we model both the MDDP and CLP for linear codes over arbitrary m−ary alphabets, we make the theoretical analysis of the first level for the binary CLP problem, and introduce some experiments to test its performance. The experiments were carried out on both quantum computer simulators and real quantum devices, and use codes of different lengths and different depths of the QAOA.
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