Passive decoy-state quantum key distribution with imperfect source

Abstract Passive generation is a sophisticated way of state preparation in quantum key distribution (QKD) systems which is designed to exploit some internal physical process as a source of randomness. It can be profitable in a wide range of scenarios. However, the original analysis of the passive scheme implies an ideal interference which is almost impossible to assure in practice, therefore utilizing such method potentially compromises the security of the system. Here we develop a general technique to estimate decoy-state parameters for a passive protocol with an arbitrary experimental distribution of intensity. We compare this analysis with the original method and show that the proposed technique can provide higher key generation rates.

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DECOY STATE QUANTUM KEY DISTRIBUTION

International Journal of Quantum Information ◽

10.1142/s0219749905001328 ◽

2005 ◽

Vol 03 (supp01) ◽

pp. 143-143 ◽

Cited By ~ 4

Author(s):

HOI-KWONG LO

Keyword(s):

Quantum Key Distribution ◽

Secure Communication ◽

Key Distribution ◽

Generation Rate ◽

Key Generation ◽

Long Distance ◽

Decoy State ◽

Bb84 Protocol ◽

High Loss ◽

Statistical Fluctuations

Quantum key distribution (QKD) allows two parties to communicate in absolute security based on the fundamental laws of physics. Up till now, it is widely believed that unconditionally secure QKD based on standard Bennett-Brassard (BB84) protocol is limited in both key generation rate and distance because of imperfect devices. Here, we solve these two problems directly by presenting new protocols that are feasible with only current technology. Surprisingly, our new protocols can make fiber-based QKD unconditionally secure at distances over 100km (for some experiments, such as GYS) and increase the key generation rate from O(η2) in prior art to O(η) where η is the overall transmittance. Our method is to develop the decoy state idea (first proposed by W.-Y. Hwang in "Quantum Key Distribution with High Loss: Toward Global Secure Communication", Phys. Rev. Lett. 91, 057901 (2003)) and consider simple extensions of the BB84 protocol. This part of work is published in "Decoy State Quantum Key Distribution", . We present a general theory of the decoy state protocol and propose a decoy method based on only one signal state and two decoy states. We perform optimization on the choice of intensities of the signal state and the two decoy states. Our result shows that a decoy state protocol with only two types of decoy states—a vacuum and a weak decoy state—asymptotically approaches the theoretical limit of the most general type of decoy state protocols (with an infinite number of decoy states). We also present a one-decoy-state protocol as a special case of Vacuum+Weak decoy method. Moreover, we provide estimations on the effects of statistical fluctuations and suggest that, even for long distance (larger than 100km) QKD, our two-decoy-state protocol can be implemented with only a few hours of experimental data. In conclusion, decoy state quantum key distribution is highly practical. This part of work is published in "Practical Decoy State for Quantum Key Distribution", . We also have done the first experimental demonstration of decoy state quantum key distribution, over 15km of Telecom fibers. This part of work is published in "Experimental Decoy State Quantum Key Distribution Over 15km", .

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The enhanced measurement-device-independent quantum key distribution with heralded pair coherent state

Modern Physics Letters B ◽

10.1142/s0217984920500633 ◽

2019 ◽

Vol 34 (04) ◽

pp. 2050063

Author(s):

Yefeng He ◽

Wenping Ma

Keyword(s):

Light Source ◽

Error Rate ◽

Quantum Key Distribution ◽

Key Distribution ◽

Generation Rate ◽

Key Generation ◽

Measurement Device ◽

Decoy State ◽

Communication Distance ◽

Measurement Device Independent

With heralded pair coherent states (HPCS), orbital angular momentum (OAM) states and pulse position modulation (PPM) technology, a decoy-state measurement-device-independent quantum key distribution (MDI-QKD) protocol is proposed. OAM states and PPM technology are used to realize the coding of the signal states in the HPCS light source. The use of HPCS light source, OAM coding and PPM coding cannot only reduce the error rate but also improve the key generation rate and communication distance. The new MDI-QKD protocol also employs three-intensity decoy states to avoid the attacks against the light source. By calculating the error rate and key generation rate, the performance of the MDI-QKD protocol is analyzed. Numerical simulation shows that the protocol has very low error rate and very high key generation rate. Moreover, the maximum communication distance can reach 455 km.

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DECOY STATE QUANTUM KEY DISTRIBUTION

IIUM Engineering Journal ◽

10.31436/iiumej.v10i2.8 ◽

2010 ◽

Vol 10 (2) ◽

pp. 81-86

Author(s):

Sellami Ali

Keyword(s):

Distribution System ◽

Quantum Key Distribution ◽

Fiber Length ◽

Key Distribution ◽

Generation Rate ◽

Key Generation ◽

Decoy State ◽

Set Up

Experimental weak + vacuum protocol has been demonstrated using commercial QKD system based on a standard bi-directional ‘Plug & Play’ set-up. By making simple modifications to a commercial quantum key distribution system, decoy state QKD allows us to achieve much better performance than QKD system without decoy state in terms of key generation rate and distance. We demonstrate an unconditionally secure key rate of 6.2931 x 10-4per pulse for a 25 km fiber length.

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Security of quantum key distribution with intensity correlations

Quantum ◽

10.22331/q-2021-12-07-602 ◽

2021 ◽

Vol 5 ◽

pp. 602

Author(s):

Víctor Zapatero ◽

Álvaro Navarrete ◽

Kiyoshi Tamaki ◽

Marcos Curty

Keyword(s):

Quantum Key Distribution ◽

High Speed ◽

Single Photon ◽

Security Analysis ◽

Key Distribution ◽

Necessary Condition ◽

Secret Key ◽

General Technique ◽

Decoy State ◽

Maximum Relative Deviation

The decoy-state method in quantum key distribution (QKD) is a popular technique to approximately achieve the performance of ideal single-photon sources by means of simpler and practical laser sources. In high-speed decoy-state QKD systems, however, intensity correlations between succeeding pulses leak information about the users' intensity settings, thus invalidating a key assumption of this approach. Here, we solve this pressing problem by developing a general technique to incorporate arbitrary intensity correlations to the security analysis of decoy-state QKD. This technique only requires to experimentally quantify two main parameters: the correlation range and the maximum relative deviation between the selected and the actually emitted intensities. As a side contribution, we provide a non-standard derivation of the asymptotic secret key rate formula from the non-asymptotic one, in so revealing a necessary condition for the significance of the former.

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Measurement-device-independent quantum key distribution with leaky sources

Scientific Reports ◽

10.1038/s41598-021-81003-2 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Weilong Wang ◽

Kiyoshi Tamaki ◽

Marcos Curty

Keyword(s):

Quantum Key Distribution ◽

Communication Systems ◽

Signal Transmission ◽

Information Leakage ◽

Key Distribution ◽

Time Frame ◽

Measurement Device ◽

Decoy State ◽

Unrealistic Assumption ◽

Measurement Device Independent

AbstractMeasurement-device-independent quantum key distribution (MDI-QKD) can remove all detection side-channels from quantum communication systems. The security proofs require, however, that certain assumptions on the sources are satisfied. This includes, for instance, the requirement that there is no information leakage from the transmitters of the senders, which unfortunately is very difficult to guarantee in practice. In this paper we relax this unrealistic assumption by presenting a general formalism to prove the security of MDI-QKD with leaky sources. With this formalism, we analyze the finite-key security of two prominent MDI-QKD schemes—a symmetric three-intensity decoy-state MDI-QKD protocol and a four-intensity decoy-state MDI-QKD protocol—and determine their robustness against information leakage from both the intensity modulator and the phase modulator of the transmitters. Our work shows that MDI-QKD is feasible within a reasonable time frame of signal transmission given that the sources are sufficiently isolated. Thus, it provides an essential reference for experimentalists to ensure the security of implementations of MDI-QKD in the presence of information leakage.

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