Algorithm for evaluating distance-based entanglement measures

Yixuan Hu; Ye Chao Liu; Jiangwei Shang

doi:10.1088/1674-1056/acd5c5

Algorithm for evaluating distance-based entanglement measures

Yixuan Hu, Ye Chao Liu, Jiangwei Shang

School of Physics

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

Abstract

Quantifying entanglement in quantum systems is an important yet challenging task due to its NP-hard nature. In this work, we propose an efficient algorithm for evaluating distance-based entanglement measures. Our approach builds on Gilbert's algorithm for convex optimization, providing a reliable upper bound on the entanglement of a given arbitrary state. We demonstrate the effectiveness of our algorithm by applying it to various examples, such as calculating the squared Bures metric of entanglement as well as the relative entropy of entanglement for GHZ states, W states, Horodecki states, and chessboard states. These results demonstrate that our algorithm is a versatile and accurate tool that can quickly provide reliable upper bounds for entanglement measures.

Original language	English
Article number	080307
Journal	Chinese Physics B
Volume	32
Issue number	8
DOIs	https://doi.org/10.1088/1674-1056/acd5c5
Publication status	Published - 1 Aug 2023

Keywords

convex optimization
entanglement measurement
quantum information

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10.1088/1674-1056/acd5c5

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title = "Algorithm for evaluating distance-based entanglement measures",

abstract = "Quantifying entanglement in quantum systems is an important yet challenging task due to its NP-hard nature. In this work, we propose an efficient algorithm for evaluating distance-based entanglement measures. Our approach builds on Gilbert's algorithm for convex optimization, providing a reliable upper bound on the entanglement of a given arbitrary state. We demonstrate the effectiveness of our algorithm by applying it to various examples, such as calculating the squared Bures metric of entanglement as well as the relative entropy of entanglement for GHZ states, W states, Horodecki states, and chessboard states. These results demonstrate that our algorithm is a versatile and accurate tool that can quickly provide reliable upper bounds for entanglement measures.",

keywords = "convex optimization, entanglement measurement, quantum information",

author = "Yixuan Hu and Liu, {Ye Chao} and Jiangwei Shang",

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AU - Shang, Jiangwei

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Y1 - 2023/8/1

N2 - Quantifying entanglement in quantum systems is an important yet challenging task due to its NP-hard nature. In this work, we propose an efficient algorithm for evaluating distance-based entanglement measures. Our approach builds on Gilbert's algorithm for convex optimization, providing a reliable upper bound on the entanglement of a given arbitrary state. We demonstrate the effectiveness of our algorithm by applying it to various examples, such as calculating the squared Bures metric of entanglement as well as the relative entropy of entanglement for GHZ states, W states, Horodecki states, and chessboard states. These results demonstrate that our algorithm is a versatile and accurate tool that can quickly provide reliable upper bounds for entanglement measures.

AB - Quantifying entanglement in quantum systems is an important yet challenging task due to its NP-hard nature. In this work, we propose an efficient algorithm for evaluating distance-based entanglement measures. Our approach builds on Gilbert's algorithm for convex optimization, providing a reliable upper bound on the entanglement of a given arbitrary state. We demonstrate the effectiveness of our algorithm by applying it to various examples, such as calculating the squared Bures metric of entanglement as well as the relative entropy of entanglement for GHZ states, W states, Horodecki states, and chessboard states. These results demonstrate that our algorithm is a versatile and accurate tool that can quickly provide reliable upper bounds for entanglement measures.

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KW - quantum information

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JO - Chinese Physics B

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Algorithm for evaluating distance-based entanglement measures

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