量子同态加密的实现与分析

2022 13th International Conference on Information, Intelligence, Systems & Applications (IISA) Pub Date : 2022-07-18 DOI:10.1109/IISA56318.2022.9904399

Maxwell Yarter, Glen S. Uehara, A. Spanias

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引用次数: 5

摘要

随着量子计算机在速度和安全性方面的“量子霸权”，人们对量子计算领域的兴趣日益浓厚。超高速的潜力可能会在数据科学、机器学习、分析和信息处理方面产生巨大的变化。本研究将集中于加密算法，其中量子计算可能会影响协议和解码代码。具体来说，同态加密(HE)允许在加密数据上执行数学运算，而不必在过程中解密数据。量子同态加密(QHE)使量子电路能够在加密的量子比特上进行。在本研究中，我们设计了量子电路，在量子隐形传态电路上实现QHE。从性能和复杂性方面对隐形传态算法进行了概述，并提供了编码与非编码电路的比较结果。这项工作为加密更复杂的量子算法(如量子神经网络(QNN))提供了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Implementation and Analysis of Quantum Homomorphic Encryption

Growing interest in the field of quantum computing is fueled by quantum computers projected ”quantum supremacy” in speed and security. The potential for ultra-high speeds may produce a dramatic change in data science, machine learning, analytics, and information processing. This research study will focus on encryption algorithms where quantum computing may affect protocols and deciphering codes. Specifically, homomorphic encryption (HE) enables mathematical operations to be performed on encrypted data without having to decrypt the data in the process. Quantum homomorphic encryption (QHE) enables quantum circuits to be performed on encrypted qubits. In this research experience for undergraduates (REU) study, we design quantum circuits to implement QHE on a quantum teleportation circuit. The teleportation algorithm is profiled in terms of performance and complexity and comparative results are provided for encoded versus unencoded circuits. This work serves as a building block for encrypting more complex quantum algorithms such as Quantum Neural Networks (QNN).

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来源期刊

2022 13th International Conference on Information, Intelligence, Systems & Applications (IISA)

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