Implementation of quantum permutation algorithm with classical light

Shihao Zhang; Pengyun Li; Bo Wang; Qiang Zeng; Xiangdong Zhang

doi:10.1088/2399-6528/aafc1c

Implementation of quantum permutation algorithm with classical light

Shihao Zhang^*, Pengyun Li, Bo Wang, Qiang Zeng, Xiangdong Zhang

^*Corresponding author for this work

School of Physics

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

7 Citations (Scopus)

Abstract

We report the experimental implementation of quantum permutation algorithm using polarization and orbital angular momentum of the classical optical beam. The easy-handling optical setup to realize all eight cyclic permutation transformations for an input four-dimensional system has been constructed. The two-to-one speed-up ratio to determine the parity of each permutation has been demonstrated. Moreover, we have theoretically discussed the extension to the case with eight elements, and the limitations on the generalization of our proposal to higher-dimensional cases. Our scheme exhibits outstanding stability and demonstrates that optical quantum computation is possible using classical states of light.

Original language	English
Article number	015008
Journal	Journal of Physics Communications
Volume	3
Issue number	1
DOIs	https://doi.org/10.1088/2399-6528/aafc1c
Publication status	Published - Jan 2019

Keywords

Classical light
Orbital angular momentum
Polarization
Quantum permutation algorithm

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10.1088/2399-6528/aafc1c

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title = "Implementation of quantum permutation algorithm with classical light",

abstract = "We report the experimental implementation of quantum permutation algorithm using polarization and orbital angular momentum of the classical optical beam. The easy-handling optical setup to realize all eight cyclic permutation transformations for an input four-dimensional system has been constructed. The two-to-one speed-up ratio to determine the parity of each permutation has been demonstrated. Moreover, we have theoretically discussed the extension to the case with eight elements, and the limitations on the generalization of our proposal to higher-dimensional cases. Our scheme exhibits outstanding stability and demonstrates that optical quantum computation is possible using classical states of light.",

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AU - Li, Pengyun

AU - Wang, Bo

AU - Zeng, Qiang

AU - Zhang, Xiangdong

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N2 - We report the experimental implementation of quantum permutation algorithm using polarization and orbital angular momentum of the classical optical beam. The easy-handling optical setup to realize all eight cyclic permutation transformations for an input four-dimensional system has been constructed. The two-to-one speed-up ratio to determine the parity of each permutation has been demonstrated. Moreover, we have theoretically discussed the extension to the case with eight elements, and the limitations on the generalization of our proposal to higher-dimensional cases. Our scheme exhibits outstanding stability and demonstrates that optical quantum computation is possible using classical states of light.

AB - We report the experimental implementation of quantum permutation algorithm using polarization and orbital angular momentum of the classical optical beam. The easy-handling optical setup to realize all eight cyclic permutation transformations for an input four-dimensional system has been constructed. The two-to-one speed-up ratio to determine the parity of each permutation has been demonstrated. Moreover, we have theoretically discussed the extension to the case with eight elements, and the limitations on the generalization of our proposal to higher-dimensional cases. Our scheme exhibits outstanding stability and demonstrates that optical quantum computation is possible using classical states of light.

KW - Classical light

KW - Orbital angular momentum

KW - Polarization

KW - Quantum permutation algorithm

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Implementation of quantum permutation algorithm with classical light

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Keywords

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