连续变量量子密钥分发实际系统中量子攻防研究进展

摘要/Abstract

摘要： Continuous-variable quantum key distribution (CVQKD) is a promosing technology, which can share theoretical unconditionally secure key between Alice and Bob. In particular,CVQKD with the Gaussian- modulated coherent states (GMCS)is one representative scheme, which has been fully proven to be secure against general attack. Over the past years, the GMCSCVQKDscheme has been experimentally implemented by many research groups in laboratories and in field environments.However, in a practicalCVQKDsystem, there are some direct or indirect imperfections that deviates from the assumption in security proofs, which can open security loopholes for Eve to hide himself to successfully steal information about the secret key. Although quantum hacking attacks seriously affect the practical security of CVQKD systems, these attacks have been effectively resisted. These studies promote the commercial applications of CVQKD. In this work, we clearly show different quantum hacking attacks and corresponding countermeasures in hardware of system, i.e., information source, sink,andquantumchannel. Moreover, a brief prospection is given for the study of practical security ofCVQKD.

关键词: 连续变量, 量子密钥分发, 量子黑客攻击

Abstract: 连续变量量子密钥分发是一种理论上可以提供无条件安全密钥分发的技术，具有广泛的应用前景。然而，实际的连续变量量子密钥分发系统中却存在着一些违背安全性证明中假设的不完美性，它们可能为窃听者打开安全漏洞来隐藏他们的窃听行为，从而成功地窃取安全密钥信息。虽然量子黑客攻击严重地影响了系统的实际应用安全性，但这些攻击均有相应完善的防御方案，从而有效地促进了系统的商业化应用。本文分别详细地展示了连续变量量子密钥分发系统硬件光路的信源、信道及信宿3 个模块中不同的量子黑客攻击及防御策略，并对该研究方向进行了展望。

Key words: continuous-variable, quantumkey distribution, quantumhacking attack

郑异, 黄鹏, 彭进业, 曾贵华. 连续变量量子密钥分发实际系统中量子攻防研究进展[J]. 信息通信技术与政策, 2019, 45(10): 43-48.

ZHENGYi, HUANGPeng, PENGJinye, ZENGGuihua. Thedevelopment of studyonquantumattacks and defenses in practical continuous-variablequantumkey distribution systems[J]. Information and Communications Technology and Policy, 2019, 45(10): 43-48.

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链接本文: http://ictp.caict.ac.cn/CN/Y2019/V45/I10/43

参考文献 29

[1]	Grosshans F, Van Assche G, Wenger J, et al. Quantum key distribution using gaussian-modulated coherent states[J]. Nature,2003,421(6920):238.
[2]	Jouguet P, Kunz- Jacques S, Leverrier A, et al. Experimental demonstration of long-distance continuous-variable quantum key distribution[J]. Nature photonics,2013,7(5):378.
[3]	Ma X C, Sun S H, JiangMS, et al. Local oscillator fluctuation opens a loophole for Eve in practical continuous- variable quantum-key-distribution systems[J]. Physical ReviewA, 2013, 88(2):022339.
[4]	Jouguet P, Kunz-Jacques S, Diamanti E. Preventing calibration attacks on the local oscillator in continuous-variable quantum key distribution[J]. PhysicalReviewA, 2013, 87(6):062313.
[5]	Huang J Z,Weedbrook C,Yin Z Q, et al. Quantum hacking of a continuous- variable quantum- key- distribution system using a wavelength attack[J]. PhysicalReviewA, 2013,87(6):062329.
[6]	MaXC, Sun S H, JiangMS, et al.Wavelength attack on practical continuous-variable quantum-key-distribution system with a heterodyne protocol[J]. PhysicalReviewA, 2013,87(5):052309.
[7]	Qin H, Kumar R, Alléaume R. Quantum hacking: Saturation attack on practical continuous-variable quantum key distribution [J]. PhysicalReviewA, 2016,94(1):012325.
[8]	Qin H, Kumar R, MakarovV, et al. Homodyne-detector-blinding attack in continuous- variable quantum key distribution[J].PhysicalReviewA, 2018, 98(1):012312.
[9]	Wang C, Huang P, Huang D, et al. Practical security of continuous-variable quantum key distribution with finite sampling bandwidth effects[J]. PhysicalReviewA, 2016, 93(2):022315.
[10]	Zheng Y, Huang P, Huang A, Peng J, and Zeng G. Practical security of continuous- variable quantum key distribution with reduced optical attenuation[J]. Physical Review A,2019, 100(1):012313.
[11]	HuangW, MaoY, Xie C, et al. Quantum hacking of free-space continuous-variable quantum key distribution by using a machinelearning technique[J]. PhysicalReviewA, 2019,100(1):012316.
[12]	Kunz-Jacques S, Jouguet P. Robust shot-noise measurement for continuous- variable quantum key distribution[J]. Physical ReviewA, 2015, 91(2):022307.
[13]	Huang D, Huang P, Lin D, et al. High-speed continuous-variable quantum key distribution without sending a local oscillator [J]. Optics letters,2015,40(16):3695-3698.
[14]	SohDBS, Brif C, ColesPJ, et al. Self-referenced continuousvariable quantum key distribution protocol[J]. Physical Review X, 2015,5(4):041010.
[15]	Qi B, Lougovski P, Pooser R, et al. Generating the local oscillator“ locally”in continuous- variable quantum key distribution based on coherent detection[J]. Physical Review X, 2015, 5(4):041009.
[16]	WangT,HuangP,ZhouY, et al. High key rate continuous-variable quantum key distribution with a real local oscillator[J].Optics express, 2018,26(3):2794-2806.
[17]	WangT, HuangP, ZhouY, et al. Pilot-multiplexed continuousvariable quantum key distribution with a real local oscillator[J].PhysicalReviewA, 2018, 97(1):012310.
[18]	LiuW, Huang P, Peng J, et al. Integrating machine learning to achieve an automatic parameter prediction for practical continuous-variable quantum key distribution[J]. Physical Review A,2018,97(2):022316.
[19]	Huang P, Huang J,Wang T, et al. Robust continuous-variable quantum key distribution against practical attacks[J]. Physical ReviewA, 2017, 95(5):052302.
[20]	Pirandola S, Ottaviani C, Spedalieri G, et al. High-rate measurement- device- independent quantum cryptography[J]. Nature Photonics,2015, 9(6):397.
[21]	Li Z, Zhang Y C, Xu F, et al. Continuous- variable measurement-device- independent quantum key distribution[J]. PhysicalReviewA, 2014, 89(5):052301.
[22]	Ma H X, Huang P, Bai D Y, et al. Continuous-variable mea-surement-device-independent quantum key distribution with photon subtraction[J]. PhysicalReviewA, 2018,97(4):042329.
[23]	Ma H X, Huang P, Bai DY, et al. Long-distance continuousvariable measurement-device-independent quantum key distribution with discrete modulation[J]. Physical ReviewA, 2019, 99(2):022322.
[24]	MaXC, SunSH, JiangMS, et al. Gaussian-modulated coherent- state measurement-device-independent quantum key distribution[J]. PhysicalReviewA, 2014,89(4):042335.
[25]	Huang B, HuangY, Peng Z. Practical security of the continuous-variable quantum key distribution with real local oscillators under phase attack[J]. Optics Express, 2019, 27(15): 20621-20631.
[26]	ZhaoY, ZhangY, HuangY, et al. Polarization attack on continuous- variable quantum key distribution[J]. Journal of Physics B:Atomic, Molecular and Optical Physics, 2018,52(1):015501.
[27]	Xie C, Guo Y, Liao Q, et al. Practical security analysis of continuous-variable quantum key distribution with jitter in clock synchronization[J]. Physics LettersA, 2018, 382(12):811-817.
[28]	ZhouY, JiangX Q, LiuW, et al. Practical security of continuous-variable quantum key distribution under finite- dimensional effect of multi-dimensional reconciliation[J]. Chinese Physics B,2018,27(5):050301.
[29]	LeverrierA, Grosshans F, Grangier P. Finite-size analysis of a continuous- variable quantum key distribution[J]. Physical ReviewA, 2010, 81(6):062343.