Experimental demonstration of quantum digital signatures over 43 dB channel loss using differential phase shift quantum key distribution

Collins, Robert J.; Amiri, Rahebeh; Fujiwara, Mikio; Honjo, Toshimori; Shimizu, Kazuo; Tamaki, Kiyoshi; Takeoka, Masahiro; Sasaki, Masahide; Andersson, Erika; Buller, Gerald S.

doi:10.1038/s41598-017-03401-9

Cited by 51 publications

(29 citation statements)

References 31 publications

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“…Figure 2(c, f) is useful for interference between the signal and idler photons from one SPDC source. The highly pure single photon sources at telecom wavelengths are very important for practical applications which require long-distance transmission in low-loss and low-cost optical fibers, for example, for quantum key distribution [60], quantum digital signature [61], quantum direct communication [62], quantum teleportation [63], quantum networks [64], etc.…”

Section: Discussionmentioning

confidence: 99%

Theoretical Investigation of a Spectrally Pure-State Generation from Isomorphs of KDP Crystal at Near-Infrared and Telecom Wavelengths

et al. 2019

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Spectrally uncorrelated biphoton state generated from the spontaneous nonlinear optical process is an important resource for quantum information. Currently such spectrally uncorrelated biphoton state can only be prepared from limited kinds of nonlinear media, thus limiting their wavelengths. In order to explore wider wavelength range, here we theoretically study the generation of spectrally uncorrelated biphoton state from 14 isomorphs of potassium dihydrogen phosphate (KDP) crystal. We find that 11 crystals from the 'KDP family' still maintain similar nonlinear optical properties of KDP, such as KDP, DKDP, ADP, DADP, ADA, DADA, RDA, DRDA, RDP, DRDP and KDA, which satisfy 3 kinds of the group-velocity matching conditions for spectrally uncorrelated biphoton state generation from near-infrared to telecom wavelengths. Based on the uncorrelated biphoton state, we investigate the generation of heralded pure-state single photon by detecting one member of the biphoton state to herald the output of the other. The purity of the heralded single photon is as high as 0.98 without using a narrow-band filter; the Hong-Ou-Mandel interference from independent sources can also achieve a visibility of 98%. This study may provide more and better single-photon sources for quantum information processing at near-infrared and telecom wavelengths.

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Section: Discussionmentioning

confidence: 99%

Theoretical Investigation of a Spectrally Pure-State Generation from Isomorphs of KDP Crystal at Near-Infrared and Telecom Wavelengths

et al. 2019

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“…After performing heterodyne measurement on mode C and receiving outcome c ∈ C, the state ρ j B|c (n) = c|Ψ Ψ|c can be used to calculate the Holevo information as before via Eqs. (12), (17). The states |Ψ B ′ 1 B2C and ρ j B|c (n) are derived in Appendix C. Finally, we note that Charlie's probability of measuring c ∈ C when Alice sends state |α k through the channel with transmission T and thermal noise input ρ th (n) is [25]…”

Section: Entangling Cloner Attackmentioning

confidence: 99%

“…6, we can securely sign a 1 bit message with only L ∼ O 10 5 coherent states. Combined with fast sending rates typical to the CV platform, this opens up the possiblity of signing a message in times competitive with the O 10 −1 seconds found in DV schemes ( [17], and see Fig. 7 of [21]).…”

Section: Performance Of the Protocolmentioning

confidence: 99%

“…DV QDS relies on photon-number detection of either weak coherent pulses [13,14,[17][18][19] or single photons [16,20]. The relatively low dimensional Hilbert space required for these schemes allows for an advanced level of security analysis, and their high resilience to loss allows for long distances to be bridged securely, with O 10 −1 seconds required to sign a 1-bit message [17,21,22]. The first QDS scheme over insecure channels required a signature length of 7.7 × 10 5 to sign a 1 bit message, in a scheme similar to decoy-state QKD [13].…”

Section: Introductionmentioning

confidence: 99%

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Continuous-variable quantum digital signatures over insecure channels

et al. 2019

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Digital signatures ensure the integrity of a classical message and the authenticity of its sender. Despite their far-reaching use in modern communication, currently used signature schemes rely on computational assumptions and will be rendered insecure by a quantum computer. We present a quantum digital signatures (QDS) scheme whose security is instead based on the impossibility of perfectly and deterministically distinguishing between quantum states. Our continuous-variable (CV) scheme relies on phase measurement of a distributed alphabet of coherent states, and allows for secure message authentication against a quantum adversary performing collective beamsplitter and entangling-cloner attacks. Crucially, for the first time in the CV setting we allow for an eavesdropper on the quantum channels and yet retain shorter signature lengths than previous protocols with no eavesdropper. This opens up the possibility to implement CV QDS alongside existing CV quantum key distribution (QKD) platforms with minimal modification.

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“…This allows these conventional optical signals to be transmitted over intercontinental distances. The same deterministic amplification methods used in conventional optical communications cannot simply be applied usefully to low-photon-number quantum states, such as those transmitted in quantum key distribution (QKD) [1,2] or quantum digital signatures [3,4], due to the addition of amplifier noise which will render ineffective any measurement of the quantum properties of the state [5].…”

Section: Introductionmentioning

confidence: 99%

Quantum state correction using a measurement-based feedforward mechanism

et al. 2019

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One of the weaknesses of quantum optical state postselection schemes is the low success probability. Typically there is a trade-off between amplifier properties such as success probability and output state fidelity. However, here we present a state comparison amplifier for optical coherent states, which features an active measurement and feedforward mechanism to correct for errors made during the initial amplification. The simple and relatively low latency mechanism allows us to correct for a binary phase alphabet. We demonstrate a significant simultaneous improvement in the amplifier characteristic parameters: output state fidelity, correct state fraction, and success probability. This demonstrates that nondeterministic quantum amplification can be enhanced significantly by measurement and feedforward.

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Experimental demonstration of quantum digital signatures over 43 dB channel loss using differential phase shift quantum key distribution

Cited by 51 publications

References 31 publications

Theoretical Investigation of a Spectrally Pure-State Generation from Isomorphs of KDP Crystal at Near-Infrared and Telecom Wavelengths

Theoretical Investigation of a Spectrally Pure-State Generation from Isomorphs of KDP Crystal at Near-Infrared and Telecom Wavelengths

Continuous-variable quantum digital signatures over insecure channels

Quantum state correction using a measurement-based feedforward mechanism

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