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Auteurs principaux: Zambrano, Leonardo, Farina, Donato, Pagliaro, Egle, Taddei, Marcio M., Acin, Antonio
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2311.06094
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author Zambrano, Leonardo
Farina, Donato
Pagliaro, Egle
Taddei, Marcio M.
Acin, Antonio
author_facet Zambrano, Leonardo
Farina, Donato
Pagliaro, Egle
Taddei, Marcio M.
Acin, Antonio
contents Convex functions of quantum states play a key role in quantum physics, with examples ranging from Bell inequalities to von Neumann entropy. However, in experimental scenarios, direct measurements of these functions are often impractical. We address this issue by introducing two methods for determining rigorous confidence bounds for convex functions based on informationally incomplete measurements. Our approach outperforms existing protocols by providing tighter bounds for a fixed confidence level and number of measurements. We evaluate the performance of our methods using both numerical and experimental data. Our findings demonstrate the efficacy of our approach, paving the way for improved quantum state certification in real-world applications.
format Preprint
id arxiv_https___arxiv_org_abs_2311_06094
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Certification of quantum state functions under partial information
Zambrano, Leonardo
Farina, Donato
Pagliaro, Egle
Taddei, Marcio M.
Acin, Antonio
Quantum Physics
Convex functions of quantum states play a key role in quantum physics, with examples ranging from Bell inequalities to von Neumann entropy. However, in experimental scenarios, direct measurements of these functions are often impractical. We address this issue by introducing two methods for determining rigorous confidence bounds for convex functions based on informationally incomplete measurements. Our approach outperforms existing protocols by providing tighter bounds for a fixed confidence level and number of measurements. We evaluate the performance of our methods using both numerical and experimental data. Our findings demonstrate the efficacy of our approach, paving the way for improved quantum state certification in real-world applications.
title Certification of quantum state functions under partial information
topic Quantum Physics
url https://arxiv.org/abs/2311.06094