Access the full text.
Sign up today, get DeepDyve free for 14 days.
Fuguo Deng, G. Long, Xiao-Shu Liu (2003)
Two-step quantum direct communication protocol using the Einstein-Podolsky-Rosen pair blockPhysical Review A, 68
Run-hua Shi, Liusheng Huang, Wei Yang, Hong Zhong (2011)
Asymmetric multi-party quantum state sharing of an arbitrary m-qubit stateQuantum Information Processing, 10
T. Tyc, B. Sanders (2001)
How to share a continuous-variable quantum secret by optical interferometryPhysical Review A, 65
Z.X. Man, Y.J. Xia, N.B. An (2007)
Quantum state sharing of an arbitrary multiqubit state using nonmaximally entangled GHZ statesEur. Phys. J. D, 42
D. Dong (2008)
Quantum reinforcement learningIEEE Trans. Syst. Man Cyber. Part B: Cyber., 38
Wen-Kui Dong, Xue-Ni He, Jin-Kui Zhong, X. Chen, Tian-zhi Yu (2008)
2,2′-[1,1′-(Propane-1,3-diyldioxydinitrilo)diethylidyne]diphenolActa Crystallographica Section E: Structure Reports Online, 64
Sreraman Muralidharan, P. Panigrahi (2008)
Quantum-information splitting using multipartite cluster statesPhysical Review A, 78
H. Heydari (2007)
Topological quantum gate entanglers for a multi-qubit stateJournal of Physics A: Mathematical and Theoretical, 40
R.F. Dong (2008)
Experimental entanglement distillation of mesoscopic quantum statesNat. Phys., 4
A. Shamir (1979)
How to share a secretCommun. ACM, 22
F.G. Deng (2005)
Multiparty quantum-state sharing of an arbitrary two-particle state with Einstein-Podolsky-Rosen pairsPhys. Rev. A, 72
A. Yip, Xi Wang, N. Zeldovich, M. Kaashoek (2009)
Improving application security with data flow assertions
Chuiping Yang, G. Guo (1999)
DISENTANGLEMENT-FREE STATE OF TWO PAIRS OF TWO-LEVEL ATOMSPhysical Review A, 59
B. Hage, A. Samblowski, J. Diguglielmo, A. Franzen, J. Fiurášek, R. Schnabel (2008)
Preparation of distilled and purified continuous-variable entangled statesNature Physics, 4
Xihan Li, P. Zhou, Chun-Yan Li, Hong-Yu Zhou, Fuguo Deng (2005)
Efficient symmetric multiparty quantum state sharing of an arbitrary m-qubit stateJournal of Physics B: Atomic, Molecular and Optical Physics, 39
Lin Chen, A. Xu, Huangjun Zhu (2010)
Computation of the geometric measure of entanglement for pure multiqubit statesPhysical Review A, 82
S. Michael, F.S. Fritzsche (2010)
Evolution equation for entanglement of multiqubit systemsPhys. Rev. A, 82
K. Hou, G. Liu, Xue-Yong Zhang, Shou-Qi Sheng (2011)
An efficient scheme for five-party quantum state sharing of an arbitrary m-qubit state using multiqubit cluster statesQuantum Information Processing, 10
M. Abadi, M. Budiu, Ú. Erlingsson, Jay Ligatti (2009)
Control-flow integrity principles, implementations, and applicationsACM Trans. Inf. Syst. Secur., 13
W. Tittel, H. Zbinden, N. Gisin (2001)
Experimental demonstration of quantum secret sharingPhysical Review A, 63
Tie-jun Wang, Hong-Yu Zhou, Fuguo Deng (2008)
Quantum state sharing of an arbitrary m-qudit state with two-qudit entanglements and generalized Bell-state measurementsPhysica A-statistical Mechanics and Its Applications, 387
H. Aschauer, H. Briegel (2001)
Security proof of quantum cryptography based entirely on entanglement purificationPhysical Review A, 66
D. Dong, I. Petersen (2009)
Sliding mode control of quantum systemsNew Journal of Physics, 11
R. Cleve, D. Gottesman, H. Lo (1999)
HOW TO SHARE A QUANTUM SECRETPhysical Review Letters, 83
Yu-Bo Sheng, Fuguo Deng, Hong-Yu Zhou (2008)
Efficient and economic five-party quantum state sharing of an arbitrary m-qubit stateThe European Physical Journal D, 48
W. Dür, H. Briegel (2007)
Entanglement purification and quantum error correctionReports on Progress in Physics, 70
Z. Man, Y. Xia, N. An (2007)
Quantum state sharing of an arbitrary multiqubit state using nonmaximally entangled GHZ statesThe European Physical Journal D, 42
Shi-Biao Zheng (2006)
Splitting quantum information via W statesPhysical Review A, 74
A. Karlsson, M. Koashi, N. Imoto (1999)
Quantum entanglement for secret sharing and secret splittingPhysical Review A, 59
G. Gordon, G. Rigolin (2006)
Generalized quantum-state sharingPhysical Review A, 73
F.G. Deng (2006)
Quantum state sharing of an arbitrary two-qubit state with two-photon entanglements and Bell-state measurementsEur. Phys. J. D, 39
Fuguo Deng, Xihan Li, Chun-Yan Li, P. Zhou, Hong-Yu Zhou (2005)
Quantum state sharing of an arbitrary two-qubit state with two-photon entanglements and Bell-state measurementsThe European Physical Journal D - Atomic, Molecular, Optical and Plasma Physics, 39
Chuiping Yang, S. Chu, Siyuan Han (2004)
Efficient many-party controlled teleportation of multiqubit quantum information via entanglementPhysical Review A, 70
G. Blakley (1899)
Safeguarding cryptographic keys1979 International Workshop on Managing Requirements Knowledge (MARK)
Xuewen Wang, Zhao-Hui Peng, C. Jia, Yanhui Wang, Xiao-Juan Liu (2009)
Scheme for implementing controlled teleportation and dense coding with genuine pentaqubit entangled state in cavity QEDOptics Communications, 282
A. Chudnov, D. Naumann (2010)
Information Flow Monitor Inlining2010 23rd IEEE Computer Security Foundations Symposium
X. Xiu, L. Dong, Ya-Jun Gao, Feng Chi (2009)
Quantum key distribution protocols with six-photon states against collective noiseOptics Communications, 282
Run-hua Shi, Liusheng Huang, Wei Yang, Hong Zhong (2011)
Multi-party quantum state sharing of an arbitrary two-qubit state with Bell statesQuantum Information Processing, 10
Iain Brown, S. Stepney, A. Sudbery, S. Braunstein (2005)
Searching for highly entangled multi-qubit statesJournal of Physics A, 38
Min Jiang, Hui Li, Zengke Zhang, Jia Zeng (2011)
Faithful teleportation of multi-particle states involving multi spatially remote agents via probabilistic channelsPhysica A-statistical Mechanics and Its Applications, 390
Y. Xia, Jie Song, He-Shan Song (2008)
Quantum state sharing using linear optical elementsOptics Communications, 281
J. Smolin, F. Verstraete, A. Winter (2005)
Entanglement of assistance and multipartite state distillationPhysical Review A, 72
Wen Zhang, Yi-min Liu, Xue-qin Zuo, Zhan-jun Zhang (2009)
Generalized Scheme for Splitting Arbitrary 2-Qubit State with Three 2-Qubit Entangled StatesInternational Journal of Theoretical Physics, 48
Run-hua Shi, Liusheng Huang, Wei Yang, Hong Zhong (2010)
Asymmetric five-party quantum state sharing of an arbitrary m-qubit stateThe European Physical Journal D, 57
Jun Liu, Yi-min Liu, Zhan-jun Zhang (2008)
Generalized Multiparty Quantum Single-Qutrit-State SharingInternational Journal of Theoretical Physics, 47
Hao Yuan, Yi-min Liu, Wen Zhang, Zhan-jun Zhang (2008)
Optimizing resource consumption, operation complexity and efficiency in quantum-state sharingJournal of Physics B: Atomic, Molecular and Optical Physics, 41
M. Hillery, V. Bužek, A. Berthiaume (1998)
Quantum secret sharingPhysical Review A, 59
Y. Nie, Yuan-hua Li, Jun-chang Liu, Ming-huang Sang (2011)
Quantum information splitting of an arbitrary three-qubit state by using two four-qubit cluster statesQuantum Information Processing, 10
Sreraman Muralidharan, P. Panigrahi (2007)
Perfect teleportation, quantum-state sharing, and superdense coding through a genuinely entangled five-qubit statePhysical Review A, 77
P. Zhou, Xihan Li, Yu-Jie Liang, Fuguo Deng, Hong-Yu Zhou (2007)
Multiparty quantum secret sharing with pure entangled states and decoy photonsPhysica A-statistical Mechanics and Its Applications, 381
Z. Zhang, Z. Man (2004)
Multiparty quantum secret sharing of classical messages based on entanglement swappingPhysical Review A, 72
S. Qin, F. Gao, Q. Wen, F. Zhu (2007)
Cryptanalysis of the Hillery-Buzek-Berthiaume quantum secret-sharing protocolPhysical Review A, 76
This paper presents a systematic approach for implementing arbitrary unknown multi-qubit state sharing by multiple agents and its generalization to independent state joint sharing collaborated with multi control agents in quantum deterministic and probabilistic networks. To supervise all independent processes of quantum state sharing, each control agent needs to hold and measure only one particle. This scheme can be used in multi-layer quantum networks to monitor the data flow in secured communication. The performance analysis shows that less qubit resources and less amount of classical communication information are required compared with existing schemes.
Quantum Information Processing – Springer Journals
Published: Nov 30, 2011
Read and print from thousands of top scholarly journals.
Already have an account? Log in
Bookmark this article. You can see your Bookmarks on your DeepDyve Library.
To save an article, log in first, or sign up for a DeepDyve account if you don’t already have one.
Copy and paste the desired citation format or use the link below to download a file formatted for EndNote
Access the full text.
Sign up today, get DeepDyve free for 14 days.
All DeepDyve websites use cookies to improve your online experience. They were placed on your computer when you launched this website. You can change your cookie settings through your browser.