[1] [1] Bennett C H, Brassard G. Quantum cryptography: Public key distribution and coin tossing [J]. Theoretical Computer Science, 2014, 560: 7-11.

[2] [2] Liu Z H, Chen H W. Cryptanalysis and improvement in controlled quantum dialogue using cluster states [J]. Quantum Information Processing, 2019, 18: 98-99.

[3] [3] Bennett C H, Brassard G, Crepeau C, et al. Teleporting an unknown quantum state via classical and Einstein-Podolsky-Rosen channels [J]. Physical Review Letters, 1993, 70(13): 1895-1899.

[4] [4] Peng J Y, Mo Z W. Several teleportation schemes of an arbitrary unknown multi-particle state via different quantum channels [J]. Chinese Physics B, 2013, 22(5): 160-167.

[5] [5] Peng J Y, Bei M Q, Mo Z W. Deterministic multi-hop controlled teleportation of arbitrary single-qubit state [J]. International Journal of Theoretical Physics, 2017, 5(10): 3348-3358.

[6] [6] Lo H K. Classical-communication cost in distributed quantum-information processing: A generalization of quantum-communication complexity [J]. Physical Review A, 2000, 62(1): 012313.

[7] [7] Peng J Y, Bai M Q, Mo Z W. Bidirectional controlled joint remote state preparation [J]. Quantum Information Processing, 2015, 14(11): 4263-4278.

[8] [8] Peng J Y, Luo M X, Mo Z W, et al. Flexible deterministic joint remote state preparation of some states [J]. International Journal of Quantum Information, 2013, 11(4): 1350044.

[9] [9] Pati A K. Minimum classical bit for remote preparation and measurement of a qubit [J]. Physical Review A, 2001, 63: 014302.

[10] [10] Peng J Y, Bai M Q, Mo Z W. Joint remote state preparation of arbitrary two-particle states via GHZ-type states [J]. Quantum Information Processing, 2013, 12(7): 2325-2342.

[11] [11] Peng J Y, Bai M Q, Mo Z W. Joint remote state preparation of a four-dimensional quantum state [J]. Chinese Physics Letters, 2014, 31(1): 010301.

[12] [12] Hillery M, Buzek V, Berthiaume A. Quantum secret sharing [J]. Physical Review A, 1990, 59(3): 1829-1834.

[13] [13] Peng J Y, Mo Z W. Quantum sharing an unknown multi-particle state via POVM [J]. International Journal of Theoretical Physics, 2013, 52(2): 620-633.

[14] [14] Peng J Y. Bei M G, Mo Z W. Bidirectional quantum states sharing [J]. International Journal of Theoretical Physics, 2016, 55(5): 2481-2489.

[15] [15] Peng J Y, Bai M Q, Mo Z W. Remote information concentration via four-particle cluster state and by positive operator-value measurement [J]. International Journal of Modern Physics B, 2013, 27(18): 50091.

[16] [16] Leung D W, Shor P W. Oblivious remote state preparation [J]. Physical Review Letters, 2003, 90(12): 127905.

[17] [17] Zeng B, Zhang P. Remote-state preparation in higher dimension and the parallelizable manifold sn-1 [J]. Physical Review A, 2001, 65(2): 130-132.

[18] [18] Kurucz Z, Adam P, Kis Z, et al. Continuous variable remote state preparation [J]. Physical Review A, 2005, 72(5): 052315.

[19] [19] Xia Y, Song J, Song H S. Multiparty remote state preparation [J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 2007, 40(18): 3719-3724.

[20] [20] Wang Z Y. Controlled remote preparation of a two-qubit state via an asymmetric quantum channel [J]. Communications in Theoretical Physics, 2011, 55(2): 244-250.

[21] [21] Briegel H J, Raussendorf R. Persistent entanglement in arrays of interacting particles [J]. Physical Review Letters, 2001, 8(5): 910-913.

[22] [22] Dong P, Zhang G, Cao Z L. Generation and transfer of quantum entangled state via spin-parity measurements [J]. International Journal of Theoretical Physics, 2010, 49(7): 1641-1647.

[23] [23] Tonchev V D. Error-correcting codes from graphs [J]. Discrete Mathematics, 2002, 257(2): 549-557.

[24] [24] Walther P, Resch K J, Rudolph T, et al. Experimental one-way quantum computting [J]. Nature, 2005, 434(7030): 169-176.

[25] [25] Muralidharan S, Panigrahi P K. Quantum information splitting using multi-partite cluster states [J]. Physical Review A, 2008, 78(6): 5175-5179.

[26] [26] Nie Y Y, Li Y H, Liu J C, et al. Quantum information splitting of an arbitrary three-qubit state by using two four-qubit cluster states [J]. Quantum Information Processing, 2011, 10(3): 297-305.

[27] [27] Lu C Y, Zhou X Q, Gühne O, et al. Experimental entanglement of six photons in graph states [J]. Nature Physics, 2007, 3(2): 91-95.

[28] [28] Paul N, Menon J V, Karumanchi S, et al. Quantum tasks using six qubit cluster states [J]. Quantum Information Processing, 2009, 10(5): 619-632.

[29] [29] Zhan Y B, Fu H, Li X W, et al. Deterministic remote preparation of a four-qubit cluster-type entangled state [J]. International Journal of Theoretical Physics, 2013, 52(8): 2615-2622.

[30] [30] Zhao S Y, Fu H, Li X W, et al. Efficient and economic schemes for remotely preparing a four-qubit cluster-type entangled state [J]. International Journal of Theoretical Physics, 2014, 53(7): 2485-2491.

[31] [31] Ma S Y, Chen W L, Qu Z G, et al. Controlled remote preparation of an arbitrary fou-qubit-state via partially entangled channel [J]. International Journal of Theoretical Physics, 2017, 5(3): 1653-1664.

[32] [32] Choudhury B S, Samanta S. An optional remote state preparation protocol for a four-qubit entangled state [J]. Quantum Information Processing, 2019, 18(4): 118-123.

[33] [33] Yuan H, Liu Y M, Zhang W, et al. Optimizing resource consumption, operation complexity and efficiency in quantum-state sharing [J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 2008, 41(14): 145506.