Determinate joint remote preparation of an arbitrary W-class quantum state

  • A novel determinate joint remote preparation scheme of an arbitrary W-class quantum state is proposed to improve the probability of successful preparation. The presented scheme is realized through orthogonal projective measurement of the Hadamard transferred basis, which converts a global measurement to several local measurements. Thus orthogonal projective measurement of the Hadamard transferred basis enables quantum information to be transmitted from different sources simultaneously, which is a breakthrough for quantum network node processing. Finally, analysis shows the feasibility and validity of the proposed method, with a 100% probability of successful preparation.
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LI Jian and ZHENG Huan-Yang. Determinate joint remote preparation of an arbitrary W-class quantum state[J]. Chinese Physics C, 2012, 36(7): 597-600. doi: 10.1088/1674-1137/36/7/005
LI Jian and ZHENG Huan-Yang. Determinate joint remote preparation of an arbitrary W-class quantum state[J]. Chinese Physics C, 2012, 36(7): 597-600.  doi: 10.1088/1674-1137/36/7/005 shu
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Received: 2011-12-06
Revised: 2012-02-03
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Determinate joint remote preparation of an arbitrary W-class quantum state

    Corresponding author: LI Jian,
    Corresponding author: ZHENG Huan-Yang,

Abstract: A novel determinate joint remote preparation scheme of an arbitrary W-class quantum state is proposed to improve the probability of successful preparation. The presented scheme is realized through orthogonal projective measurement of the Hadamard transferred basis, which converts a global measurement to several local measurements. Thus orthogonal projective measurement of the Hadamard transferred basis enables quantum information to be transmitted from different sources simultaneously, which is a breakthrough for quantum network node processing. Finally, analysis shows the feasibility and validity of the proposed method, with a 100% probability of successful preparation.

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