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Main Authors: Huang, Jiaxin, Zhu, Yan, Chiribella, Giulio, Wu, Ya-Dong
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2507.09891
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author Huang, Jiaxin
Zhu, Yan
Chiribella, Giulio
Wu, Ya-Dong
author_facet Huang, Jiaxin
Zhu, Yan
Chiribella, Giulio
Wu, Ya-Dong
contents Characterization of quantum systems from experimental data is a central problem in quantum science and technology. But which measurements should be used to gather data in the first place? While optimal measurement choices can be worked out for small quantum systems, the optimization becomes intractable as the system size grows large. To address this problem, we introduce a deep neural network with a sequence model architecture that searches for efficient measurement choices in a data-driven, adaptive manner. The model can be applied to a variety of tasks, including the prediction of linear and nonlinear properties of quantum states, as well as state clustering and state tomography tasks. In all these tasks, we find that the measurement choices identified by our neural network consistently outperform the uniformly random choice. Intriguingly, for topological quantum systems, our model tends to recommend measurements at the system's boundaries, even when the task is to predict bulk properties. This behavior suggests that the neural network may have independently discovered a connection between boundaries and bulk, without having been provided any built-in knowledge of quantum physics.
format Preprint
id arxiv_https___arxiv_org_abs_2507_09891
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sequence-Model-Guided Measurement Selection for Quantum State Learning
Huang, Jiaxin
Zhu, Yan
Chiribella, Giulio
Wu, Ya-Dong
Quantum Physics
Artificial Intelligence
Machine Learning
Characterization of quantum systems from experimental data is a central problem in quantum science and technology. But which measurements should be used to gather data in the first place? While optimal measurement choices can be worked out for small quantum systems, the optimization becomes intractable as the system size grows large. To address this problem, we introduce a deep neural network with a sequence model architecture that searches for efficient measurement choices in a data-driven, adaptive manner. The model can be applied to a variety of tasks, including the prediction of linear and nonlinear properties of quantum states, as well as state clustering and state tomography tasks. In all these tasks, we find that the measurement choices identified by our neural network consistently outperform the uniformly random choice. Intriguingly, for topological quantum systems, our model tends to recommend measurements at the system's boundaries, even when the task is to predict bulk properties. This behavior suggests that the neural network may have independently discovered a connection between boundaries and bulk, without having been provided any built-in knowledge of quantum physics.
title Sequence-Model-Guided Measurement Selection for Quantum State Learning
topic Quantum Physics
Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2507.09891