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Quantum Information Processing
Erschienen in: Quantum Information Processing 5/2019

01.05.2019

Analysis of polarization coding for subcarrier multiplexing quantum key distribution

verfasst von: Hailin Xiao, Shan Ouyang, Anthony Theodore Chronopoulos

Erschienen in: Quantum Information Processing | Ausgabe 5/2019

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Abstract

In this paper, a polarization-coding scheme for subcarrier multiplexing quantum key distribution (SCM-QKD) is proposed, in which the overall QKD can be substantially increased by relying on parallel sideband channels. The polarization state of each sideband can be randomly and independently synthesized by controlling the phase difference of subcarriers. We derive the mathematical formulas of quantum bit error rate (QBER). Both the theoretical analysis and the numerical results show that an efficient implementation of BB84 protocol is feasible. By the proposed polarization coding in a parallel QKD system, without relying on dispersion compensation, a 6% performance gain in terms of correct bit rate over the conventional BB84 protocol (i.e., without polarization coding) is obtained. More importantly, the proposed polarization-coding-aided SCM-QKD can help achieve a long-distance QKD with a low QBER.
Vorheriger Artikel Chau–Wang–Wong17 scheme is experimentally more feasible than the six-state scheme
Nächster Artikel Quantum identity authentication in the orthogonal-state-encoding QKD system

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Fußnoten
1
Here, we assume that the proposed system encodes the bits and forms a pair of conjugated bases required for implementing the BB84 protocol.
 
Literatur
1.
Capmany, J., Fernandez-Pousa, C.R.: Impact of third-order intermodulation on the performance of subcarrier multiplexed quantum key distribution. J. Lightwave Technol. 29(20), 3061–3069 (2011)ADSCrossRef
2.
Gabay, M., Arnon, S.: Quantum key distribution by a free-space MIMO system. J. Lightwave Technol. 24(8), 3114–3120 (2006)ADSCrossRef
3.
Zhao, G., Zhao, S., Yao, Z., Hao, C., Meng, W., Wang, X., Zhu, Z., liu, F.: Analysis of polarization state in quantum key distribution via single-photon two-qubit states. Optik 125, 1522–1525 (2014)ADSCrossRef
4.
Djordjevic, I.B.: Integrated optics modules based proposal for quantum information processing, teleportation, QKD, and quantum error correction employing photon angular momentum. IEEE Photonics J. 8(1), 6600212-1–6600212-13 (2016)MathSciNetCrossRef
5.
Zhao, G., Zhao, S., Yao, Z., Meng, W., Wang, X., Zhu, Z., Liu, F.: Forward spectral filtering parallel quantum key distribution system. Opt. Commun. 298–299, 254–259 (2013)ADSCrossRef
6.
Fang, J., Huang, P., Zeng, G.H.: Multichannel parallel continuous-variable quantum key distribution with Gaussian modulation. Phys. Rev. A 89(2), 022315-1–022315-9 (2014)ADSCrossRef
7.
Nguyen, H.V., Trinh, P.V., Pham, A.T., Babar, Z., Alanis, D., Botsinis, P., Chandra, D., Ng, S.X., Hanzo, L.: Network coding aided cooperative quantum key distribution over free-space optical channels. IEEE Access 5, 12301–12317 (2017)CrossRef
8.
Xiao, H., Zhang, Z.: Subcarrier multiplexing multiple-input multiple-output quantum key distribution scheme with orthogonal quantum states. Quantum Inf. Process. 16(13), 1–18 (2017)ADSMATH
9.
Tang, Z., Wei, K., Bedroya, O., Qian, L., Lo, H.-K.: Experimental measurement-device-independent quantum key distribution with imperfect sources. Phys. Rev. A 93(4), 042308-1–042308-13 (2016)ADSCrossRef
10.
Capmany, J., Ortigosa-Blanch, A., Mora, J., Ruiz-Alba, A., Amaya, W., Martinez, A.: Analysis of subcarrier multiplexed quantum key distribution systems: signal, intermodulation, and quantum bit error rate. IEEE J. Sel. Top. Quantum Electron. 15(6), 1607–1621 (2009)ADSCrossRef
11.
Mora, J., Ruiz-Alba, A., Amaya, W., Capmany, J.: Dispersion supported BB84 quantum key distribution using phase modulated light. IEEE Photonics J. 3(3), 433–440 (2011)ADSCrossRef
12.
Merolla, J.M., Mazurenko, Y., Goedgebuer, J.P., Rhodes, W.T.: Single-photon interference in sidebands of phase-modulated light for quantum cryptography. Phys. Rev. Lett. 82, 1656–1659 (1999)ADSCrossRef
13.
Zueco, D., Mazo, J.J., Solano, E., Garcia-Ripoll, J.J.: Microwave photonics with Josephson junction arrays: negative refraction index and entanglement through disorder. Phys. Rev. B 86, 024503-1–024503-11 (2014)ADS
14.
Fang, J., Huang, P., Zeng, G.: Multichannel parallel continuous-variable quantum key distribution with Gaussian modulation. Phys. Rev. A 89, 022315-1–022315-9 (2014)ADSCrossRef
15.
Erkilinc, M.S., Li, Z., Pachnicke, S., Griesser, H., Thomsen, B.C., Bayvel, P., Killey, R.I.: Spectrally efficient WDM nyquist pulse-shaped 16-QAM subcarrier modulation transmission with direct detection. J. Lightwave Technol. 33(15), 3147–3155 (2015)ADSCrossRef
16.
Muga, N.J., Ferreira, M.F.S., Pinto, A.N.: QBER estimation in QKD systems with polarization encoding. J. Lightwave Technol. 29(3), 355–361 (2011)ADSCrossRef
17.
Lupo, C., Giovannetti, V., Pirandola, S., Mancini, S., Lloyd, S.: Single-photon interference in sidebands of phase-modulated light for quantum cryptography. Phys. Rev. A 84, 010303-1–010303-6 (2011)ADSCrossRef
18.
Zhu, Z., Zhao, S., Yao, Z., Tan, Q., Li, Y., Chu, X., Wang, X., Zhao, G.: Nonlinearly modeling of an on-board microwave photonics system based on Mach–Zehnder modulator. Optoelectron. Lett. 8(6), 441–444 (2012)ADSCrossRef
19.
Huang, L., Wang, P., Xiang, P., Chen, D., Zhang, Y., Tao, J., Pu, T., Chen, X.: Photonic generation of microwave frequency shift keying signals. IEEE Photonics Technol. Lett. 28(8), 1928–1931 (2016)ADSCrossRef
20.
Lutkenhaus, N.: Security against individual attacks for realistic quantum key distribution. Phys. Rev. A 61(5), 052304-1–052304-10 (2000)ADSMathSciNetCrossRef
21.
Sun, X., Djordjevic, I.B., Neifeld, M.A.: Secret key rates and optimization of BB84 and decoy state protocols over time-varying free-space optical channels. IEEE Photonics J. 8(3), 7904713-1–7904713-14 (2016)
22.
Shen, J.T., Povinelli, M.L., Sandhu, S., Fan, S.: Stopping single photons in one-dimensional circuit quantum electrodynamics systems. Phys. Rev. B 75, 035320-1–035320-5 (2007)ADS
23.
Bachor, H.A., Ralph, T.C.: A Guide to Experiments in Quantum Optics, 2nd edn. Wiley, New York (2003)
24.
Shapiro, J.H.: Near-field turbulence effects on quantum key distribution. Phys. Rev. A 67, 022309-1–022309-7 (2003)ADS
25.
Lo, H.K., Chau, H.F.: Unconditional security of quantum key distribution over arbitrarily long distances. Science 283, 2050–2056 (1999)ADSCrossRef
26.
Lo, H.K., Curty, M., Qi, B.: Measurement device independent quantum key distribution. Phys. Rev. Lett. 108, 130503-1–130503-5 (2012)ADSCrossRef
27.
Lo, H.K., Chau, H.F., Ardehali, M.: Efficient quantum key distribution scheme and a proof of its unconditional security. J. Cryptol. 18, 133–165 (2005)MathSciNetCrossRef
28.
Gottesman, D., Lo, H.K., Tkenhaus, N.L., Preskill, J.: Security of quantum key distribution with imperfect devices. Quantum Inf. Comput. 4(5), 325–360 (2002)MathSciNetMATH
29.
Hong, C.K., Ou, Z.Y., Mandel, L.: Measurement of subpicosecond time intervals between two photons by interference. Phys. Rev. Lett. 59(18), 2044–2046 (1987)ADSCrossRef
Metadaten
Titel
Analysis of polarization coding for subcarrier multiplexing quantum key distribution
verfasst von
Hailin Xiao
Shan Ouyang
Anthony Theodore Chronopoulos
Publikationsdatum
01.05.2019
Verlag
Springer US
Erschienen in
Quantum Information Processing / Ausgabe 5/2019
Print ISSN: 1570-0755
Elektronische ISSN: 1573-1332
DOI
https://doi.org/10.1007/s11128-019-2245-2

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