Non-Gaussian cloning of quantum coherent states is optimal

N. J. Cerf; O. Krüger; P. Navez; R. F. Werner; M. M. Wolf

doi:10.1103/PhysRevLett.95.070501

Non-Gaussian cloning of quantum coherent states is optimal

N. J. Cerf
, O. Krüger
, P. Navez
, R. F. Werner
, M. M. Wolf

Research output: Contribution to journal › Article › peer-review

143 Scopus citations

Abstract

We consider the optimal cloning of quantum coherent states with single-clone and joint fidelity as figures of merit. While the latter is maximized by a Gaussian cloner, the former is not: the optimal single-clone fidelity for a symmetric 1-to-2 cloner is 0.6826, compared to 2/3 in a Gaussian setting. This cloner can be realized with an optical parametric amplifier and certain non-Gaussian bimodal states. Finally, we show that the single-clone fidelity of the optimal 1-to-2 cloner is 1/2. It is achieved by a Gaussian scheme and cannot be surpassed even with supplemental bound entangled states.

Original language	English
Article number	070501
Journal	Physical Review Letters
Volume	95
Issue number	7
DOIs	https://doi.org/10.1103/PhysRevLett.95.070501
State	Published - 12 Aug 2005
Externally published	Yes

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10.1103/PhysRevLett.95.070501

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title = "Non-Gaussian cloning of quantum coherent states is optimal",

abstract = "We consider the optimal cloning of quantum coherent states with single-clone and joint fidelity as figures of merit. While the latter is maximized by a Gaussian cloner, the former is not: the optimal single-clone fidelity for a symmetric 1-to-2 cloner is 0.6826, compared to 2/3 in a Gaussian setting. This cloner can be realized with an optical parametric amplifier and certain non-Gaussian bimodal states. Finally, we show that the single-clone fidelity of the optimal 1-to-2 cloner is 1/2. It is achieved by a Gaussian scheme and cannot be surpassed even with supplemental bound entangled states.",

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AU - Cerf, N. J.

AU - Krüger, O.

AU - Navez, P.

AU - Werner, R. F.

AU - Wolf, M. M.

PY - 2005/8/12

Y1 - 2005/8/12

N2 - We consider the optimal cloning of quantum coherent states with single-clone and joint fidelity as figures of merit. While the latter is maximized by a Gaussian cloner, the former is not: the optimal single-clone fidelity for a symmetric 1-to-2 cloner is 0.6826, compared to 2/3 in a Gaussian setting. This cloner can be realized with an optical parametric amplifier and certain non-Gaussian bimodal states. Finally, we show that the single-clone fidelity of the optimal 1-to-2 cloner is 1/2. It is achieved by a Gaussian scheme and cannot be surpassed even with supplemental bound entangled states.

AB - We consider the optimal cloning of quantum coherent states with single-clone and joint fidelity as figures of merit. While the latter is maximized by a Gaussian cloner, the former is not: the optimal single-clone fidelity for a symmetric 1-to-2 cloner is 0.6826, compared to 2/3 in a Gaussian setting. This cloner can be realized with an optical parametric amplifier and certain non-Gaussian bimodal states. Finally, we show that the single-clone fidelity of the optimal 1-to-2 cloner is 1/2. It is achieved by a Gaussian scheme and cannot be surpassed even with supplemental bound entangled states.

UR - https://www.scopus.com/pages/publications/27144453298

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JO - Physical Review Letters

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Non-Gaussian cloning of quantum coherent states is optimal

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