Experimentally enhancing high-dimensional subchannel discrimination via optimal local filtering

Yen An Shih; Wan Guan Chang; Gelo Noel M. Tabia; Hao Cheng Weng; Tsung Ying Tsai; Chih Sung Chuu; Huan Yu Ku; Costantino Budroni

doi:10.1103/PhysRevResearch.7.L032035

Experimentally enhancing high-dimensional subchannel discrimination via optimal local filtering

Yen An Shih
, Wan Guan Chang
, Gelo Noel M. Tabia^*
, Hao Cheng Weng
, Tsung Ying Tsai
, Chih Sung Chuu^*
, Huan Yu Ku^*
, Costantino Budroni

^*Corresponding author for this work

Department of Physics

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

Abstract

The subchannel discrimination task involves distinguishing between different branches of a quantum evolution. The guessing probability of this task can be enhanced using quantum resources such as entanglement and steerability. In this study, we explore how to optimize the task's guessing probability within the one-sided device-independent quantum information processing framework, which is naturally associated with steering, and restricted to one-way local operations and classical communication. From a theoretical standpoint, we demonstrate how to separately optimize local filters and measurements, and provide an optimality condition that directly links the enhancement of guessing probability to the maximum steerability achievable through local filters. We then experimentally demonstrate the enhancement of the discrimination task on a two-ququart photonic system by implementing the optimal local filters.

Original language	English
Article number	L032035
Journal	Physical Review Research
Volume	7
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevResearch.7.L032035
Publication status	Published - 2025 Jul

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevResearch.7.L032035

Cite this

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title = "Experimentally enhancing high-dimensional subchannel discrimination via optimal local filtering",

abstract = "The subchannel discrimination task involves distinguishing between different branches of a quantum evolution. The guessing probability of this task can be enhanced using quantum resources such as entanglement and steerability. In this study, we explore how to optimize the task's guessing probability within the one-sided device-independent quantum information processing framework, which is naturally associated with steering, and restricted to one-way local operations and classical communication. From a theoretical standpoint, we demonstrate how to separately optimize local filters and measurements, and provide an optimality condition that directly links the enhancement of guessing probability to the maximum steerability achievable through local filters. We then experimentally demonstrate the enhancement of the discrimination task on a two-ququart photonic system by implementing the optimal local filters.",

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AU - Shih, Yen An

AU - Chang, Wan Guan

AU - Tabia, Gelo Noel M.

AU - Weng, Hao Cheng

AU - Tsai, Tsung Ying

AU - Chuu, Chih Sung

AU - Ku, Huan Yu

AU - Budroni, Costantino

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AB - The subchannel discrimination task involves distinguishing between different branches of a quantum evolution. The guessing probability of this task can be enhanced using quantum resources such as entanglement and steerability. In this study, we explore how to optimize the task's guessing probability within the one-sided device-independent quantum information processing framework, which is naturally associated with steering, and restricted to one-way local operations and classical communication. From a theoretical standpoint, we demonstrate how to separately optimize local filters and measurements, and provide an optimality condition that directly links the enhancement of guessing probability to the maximum steerability achievable through local filters. We then experimentally demonstrate the enhancement of the discrimination task on a two-ququart photonic system by implementing the optimal local filters.

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Experimentally enhancing high-dimensional subchannel discrimination via optimal local filtering

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