Distributed secure quantum machine learning

被引：0

作者：

Yu-Bo Sheng ^{[1
]}

Lan Zhou ^{[2
]}

机构：

[1] Key Laboratory of Broadband Wireless Communication and Sensor Network Technology, Nanjing University of Posts and Telecommunications, Ministry of Education

[2] College of Mathematics & Physics, Nanjing University of Posts and Telecommunications

来源：

Science Bulletin | 2017年 / 62卷 / 14期

基金：

中国国家自然科学基金;

关键词：

Quantum machine learning; Quantum communication; Quantum computation; Big data;

D O I：

暂无

中图分类号：

TP181 [自动推理、机器学习];

学科分类号：

081104 ; 0812 ; 0835 ; 1405 ;

摘要：

Distributed secure quantum machine learning(DSQML) enables a classical client with little quantum technology to delegate a remote quantum machine learning to the quantum server with the privacy data preserved. Moreover, DSQML can be extended to a more general case that the client does not have enough data, and resorts both the remote quantum server and remote databases to perform the secure machine learning. Here we propose a DSQML protocol that the client can classify two-dimensional vectors to different clusters, resorting to a remote small-scale photon quantum computation processor. The protocol is secure without leaking any relevant information to the Eve. Any eavesdropper who attempts to intercept and disturb the learning process can be noticed. In principle, this protocol can be used to classify high dimensional vectors and may provide a new viewpoint and application for future ‘‘big data".

引用

页码：1025 / 1029

页数：5

共 53 条

[1]

Construction of a quantum repeater based on a quantum dot in an optical microcavity system. Wang C,Wang TJ,Zhang Y,et al. Laser Phys Lett . 2014

[2] An introduction to quantum machine learning [J].

Schuld, Maria ;

Sinayskiy, Ilya ;

Petruccione, Francesco .

CONTEMPORARY PHYSICS, 2015, 56 (02) :172-185

[3]

Quantum repeaters: the role of imperfect local operations in quantum communication. Briegel, H.-J.,Dur, W.,Cirac, J.I.,Zoller, P. Physical Review . 1998

[4]

A quantum speedup in machine learning: finding an N -bit Boolean function for a classification[J] . Seokwon Yoo,Jeongho Bang,Changhyoup Lee,Jinhyoung Lee. &nbspNew Journal of Physics . 2014 (10)

[5]

A strategy for quantum algorithm design assisted by machine learning[J] . Jeongho Bang,Junghee Ryu,Seokwon Yoo,Marcin Paw?owski,Jinhyoung Lee. &nbspNew Journal of Physics . 2014 (7)

[6]

Quantum loop topography for machine learning. Zhang Y,Kim EA. Physical Review Letters . 2017

[7]

Inductive supervised quantum learning. Monras A,Sentis G,Wittek P. Physical Review Letters . 2017

[8]

Detection of nonlocal atomic entanglement assisted by single photons. Zhou L,Sheng YB. Physical Review A Atomic Molecular and Optical Physics . 2014

[9]

Implementations of two-photon four-qubit Toffoli and Fredkin gates assisted by nitrogen-vacancy centers. Wei HR,Zhu PJ. Science Reports . 2016

[10]

Quantum hyperentanglement and its applications in quantum information processing[J]. Fu-Guo Deng,Bao-Cang Ren,Xi-Han Li. Science Bulletin. 2017(01)

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