Enhanced multiparty quantum secret sharing of classical messages by using entanglement swapping

Y.-H. Chou; C.-Y. Chen; R.-K. Fan; H.-C. Chao; F.-J. Lin

Enhanced multiparty quantum secret sharing of classical messages by using entanglement swapping

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Enhanced multiparty quantum secret sharing of classical messages by using entanglement swapping

Author(s): Y.-H. Chou ; C.-Y. Chen ; R.-K. Fan ; H.-C. Chao ; F.-J. Lin
DOI: 10.1049/iet-ifs.2011.0233

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Author(s): Y.-H. Chou ¹ ; C.-Y. Chen ² ; R.-K. Fan ¹ ; H.-C. Chao ^{2, 3} ; F.-J. Lin ¹
- Affiliations: 1: Department of Computer Science and Information Engineering, National Chi Nan University, Taiwan
  2: Department of Electrical Engineering, National Dong Hwa University, Taiwan
  3: Department of Electronic Engineering, Institute of Computer Science & Information Engineering, National Ilan University, Taiwan
Source: Volume 6, Issue 2, June 2012, p. 84 – 92
DOI: 10.1049/iet-ifs.2011.0233 , Print ISSN 1751-8709, Online ISSN 1751-8717

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Based on the multiparty quantum secret sharing (QSS) protocol called Zhang–Man protocol, the authors proposed two schemes to enhance the transmission efficiency of whole protocol. In the proposed improved protocol, the dealer can transmit double amount of secret messages at a time securely instead of doing the original Zhang–Man protocol twice. Besides, the authors save a lot of cost of whole QSS system. When the amount of secret messages is large and the number of agents is more, the performance of our protocol is much better than the Zhang–Man protocol. The authors also proposed a reuse scheme, after the secret message had been deduced, the left qubits can be reused for a new round. All of the scheme the authors mentioned above could be extended to multiparty cases in practice.

References

1. 1)
  - C.H. Bennett , G. Brassard , C. Crépeau , R. Jozna , A. Peres , W.K. Wootters . Teleporting an unknown quantum state via dual classical and Einstein-Podolsky-Rosen channels. Phys. Rev. Lett. , 13 , 1895 - 1899
2. 2)
  - F.G. Deng , G.L. Long , X.S. Liu . Two-step quantum direct communication protocol using the Einstein–Podolsky–Rosen pair block. Phys. Rev. A.
3. 3)
  - Y.H. Chou , C.Y. Chen , H.C. Chao , J.H. Park , R.K. Fan . Quantum entanglement and non-locality based secure computation for future communication. IET Inf. Sec. , 1 , 69 - 79
4. 4)
  - Liu, W.J., Chen, H.W., Li, Z.Q., Liu, Z.h., Xiao, F.Y.: `Efficient quantum secure direct communication with authentication', Proc. IEEE Congress on Evolutionary Computation (CEC 2008), 2008, Hong Kong, p. 1764–1768.
5. 5)
  - E. Waks , A. Zeevi , Y. Yamamoto . Security of quantum key distribution with entangled photons against individual attacks. Phys. Rev. A
6. 6)
  - Z.J. Zhang , Z.X. Man . Multiparty quantum secret sharing of classical messages based on entanglement swapping. Phys. Rev. A
7. 7)
  - B. Schneier . (1996) Applied cryphotography.
8. 8)
  - M. Hillery , V. Buzek , A. Berthiaume . Quantum secret sharing. Phys. Rev. A
9. 9)
  - S. Lin , F. Gao , F.Z. Guo , Q.Y. Wen , F.C. Zhu . Comment on “Multiparty quantum secret sharing of classical messages based on entanglement swapping”. Phys. Rev. A
10. 10)
  - Bennett, C.H., Brassard, G.: `Quantum cryptography: public key distribution and coin tossing', Proc. IEEE Int. Conf. on Computers, Systems and Signal Processing, 1984, Bangalore, India, p. 175–179.
11. 11)
  - W. Tittel , H. Zbinden , N. Gisin . Experimental demonstration of quantum secret sharing. Phys. Rev. A
12. 12)
  - C.H. Bennett , G. Brassard , N.D. Mermin . Quantum cryptography without Bell's theorem. Phys. Rev. Lett.
13. 13)
  - M. Zukowski , A. Zeilinger , M.A. Horne , A.K. Ekert . “Event-ready-detectors” Bell experiment via entanglement swapping. Phys. Rev. Lett. , 4287 - 4290
14. 14)
  - C.-F. Hsu , Y. Liu , Q. Cheng , G.-H. Cui . New results on multipartite secret sharing matroids. J. Internet Technol. , 6 , 829 - 836
15. 15)
  - Chou, Y.H., Fan, R.K., Chen, S.M., Chen, C.Y., Chao, H.C.: `Enhanced multiparty quantum secret sharing of classical messages based on entanglement swapping', IET Int. Conf. on Frontier Computing – Theory, Technologies and Applications, 2010, Taiwan.
16. 16)
  - Z.J. Zhang , Y. Li , Z.X. Man . Multiparty quantum secret sharing. Phys. Rev. A
17. 17)
  - Z.J. Zhang , Z.X. Man . Reply to ‘Comment on “Multiparty quantum secret sharing of classical messages based on entanglement swapping”. Phys, Rev. A
18. 18)
  - G.L. Long , X.S. Liu . Theoretically efficient high-capacity quantum-key-distribution scheme. Phys. Rev. A , 032302/1 - 3.
19. 19)
  - D. Gottesman . Theory of quantum secret sharing. Phys. Rev. A
20. 20)
  - H. Inamori , L. Rallan , V. Verdral . Security of EPR-based quantum cryptography against incoherent symmetric attacks. J. Phys. A
21. 21)
  - Y. Sun , Q.Y. Wen , F. Gao , X.B. Chen , F.C. Zhu . Multiparty quantum secret sharing based on Bell measurement. Opt. Commun. , 3647 - 3651

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Enhanced multiparty quantum secret sharing of classical messages by using entanglement swapping

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