[4] [4] Ma S Y, Chen X B, Luo M X, et al. Remote preparation of a four-particle entangled cluster-type state [J]. Optics Communications, 2011, 284(16-17): 4088-4093.

[5] [5] Wei J H, Dai H Y, Zhang M. Two efficient schemes for probabilistic remote state preparation and the combination of both schemes [J]. Quantum Information Processing, 2014, 13(9): 2115-2125.

[6] [6] Nguyen B A, Cao T B. Perfect controlled joint remote state preparation independent of entanglement degree of the quantum channel [J]. Physics Letters A, 2014, 378(48): 3582-3585.

[7] [7] Liu L L, Hwang T. Controlled remote state preparation protocols via AKLT states [J]. Quantum Information Processing, 2014, 13(7): 1639-1650.

[8] [8] Wang C, Zeng Z, Li X H. Controlled remote state preparation via partially entangled quantum channel [J]. Quantum Information Processing, 2015, 14(3): 1077-1089.

[9] [9] Nguyen B A. Joint remote state preparation via W and W-type states [J]. Optics Communications, 2010, 283(20): 4113-4117.

[10] [10] Liu H H, Cheng L Y, Shao X Q, et al. Joint remote state preparation of arbitrary two- and three-particle states [J]. International Journal of Theoretical Physics, 2011, 50(10): 3023-3032.

[11] [11] Wang D, Liu Y. Multiparty-controlled joint remote state preparation [J]. Quantum Information Processing, 2013, 12(10): 3223-3237.

[12] [12] Chang L W, Zheng S H, Gu L Z, et al. Joint remote preparation of an arbitrary five-qubit Brown state via non-maximally entangled channels [J]. Chinese Physics B, 2014, 23(9): 91-99.

[13] [13] Peng J Y, Luo M X, 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.

[14] [14] Li X H, Ghose S. Optimal joint remote state preparation of equatorial states [J]. Quantum Information Processing, 2015, 14(12): 4585-4592.

[15] [15] Yu R F, Lin Y J, Zhou P. Joint remote preparation of arbitrary two- and three-photon state with linear-optical elements [J]. Quantum Information Processing, 2016, 15(11): 4785-4803.

[16] [16] Wei Z H, Zha X W, Yu Y. Efficient schemes of joint remote state preparation for two-qubit equatorial states [J]. International Journal of Theoretical Physics, 2016, 55(11): 5046-5054.

[17] [17] Wu W, Liu W T, Chen P X, et al. Deterministic remote preparation of pure and mixed polarization states [J]. Physical Review A, 2010, 81(4): 042301.

[18] [18] Luo M X, Chen X B, Ma S Y, et al. Deterministic remote preparation of an arbitrary W-class state with multiparty [J]. Journal of Physics B: Atomic, Molecular and Optical Physics, 2010, 43(6): 065501.

[19] [19] Zhan Y B, Ma P C. Deterministic joint remote preparation of arbitrary two- and three-qubit entangled states [J]. Quantum Information Processing, 2013, 12(2): 997-1009.

[20] [20] Li J F, Liu J M, Feng X L, et al. Deterministic remote two-qubit state preparation in dissipative environments [J]. Quantum Information Processing, 2016, 15(5): 2155-2168.

[21] [21] Cao T B, Nguyen B A. Deterministic controlled bidirectional remote state preparation [J]. Advances in Natural Sciences: Nanoscience and Nanotechnology, 2013, 5(1): 015003.

[22] [22] He Y H, Lu Q C, Liao Y M, et al. Bidirectional controlled remote implementation of an arbitrary single qubit unitary operation with EPR and cluster states [J]. International Journal of Theoretical Physics, 2015, 54(5): 1726-1736.

[23] [23] Peng J Y, Bai M Q, Mo Z W. Bidirectional controlled joint remote state preparation [J]. Quantum Information Processing, 2015, 14(11): 4263-4278.

[24] [24] Vishal S, Chitra S, Subhashish B, et al. Controlled bidirectional remote state preparation in noisy environment: A generalized view [J]. Quantum Information Processing, 2015, 14(9): 3441-3464.

[25] [25] Zhang D, Zha X W, Duan Y J, et al. Deterministic controlled bidirectional remote state preparation via a six-qubit entangled state [J]. Quantum Information Processing, 2016, 15(5): 2169-2179.

[26] [26] Zhang D, Zha X W, Duan Y J, et al. Deterministic controlled bidirectional remote state preparation via a six-qubit maximally entangled state [J]. International Journal of Theoretical Physics, 2016, 55(1): 440-446.

[27] [27] Song Y, Ni J L, Wang Z Y, et al. Deterministic bidirectional remote state preparation of a- and symmetric quantum states with a proper quantum channel [J]. International Journal of Theoretical Physics, 2017, 5(10): 3175-3187.

[28] [28] Wu H, Zha X W, Yang Y Q. Controlled bidirectional hybrid of remote state preparation and quantum teleportation via seven-qubit entangled state [J]. International Journal of Theoretical Physics, 2017, 57(1): 28-35.

[29] [29] Fang S H, Jiang M. A novel scheme for bidirectional and hybrid quantum information transmission via a seven-qubit state [J]. International Journal of Theoretical Physics, 2017, 57(2): 523-532.

[30] [30] Shi J, Zhan Y B. Scheme for asymmetric and deterministic controlled bidirectional joint remote state preparation [J]. Communications in Theoretical Physics, 2018, 70(5): 515-520.

[31] [31] Ma P C, Chen G B, Li X W, et al. Asymmetric bidirectional controlled remote preparation of an arbitrary four-qubit cluster-type state and a single-qubit state [J]. Quantum Information Processing, 2017, 1(12): 308-319.

[32] [32] Chen X B, Sun Y R, Xu G, et al. Controlled bidirectional remote preparation of three-qubit state [J]. Quantum Information Processing, 2017, 1(10): 244-272.

[33] [33] Wang D, Zha X W, Qi J X, et al. Remote state preparation of arbitrary three-qubit state via cluster state and Bell state [J]. Acta Photonica Sinica, 2012, 41(3): 335-338.

[34] [34] 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.