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Main Authors: Kang, Zhengjie, Li, Hao, Wang, Shuo, Li, Jiaojiao, Zhang, Yuanjie, Luo, Zhihuang
Format: Preprint
Published: 2025
Subjects:
Quantum Physics
Online Access:https://arxiv.org/abs/2503.07356
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author Kang, Zhengjie
Li, Hao
Wang, Shuo
Li, Jiaojiao
Zhang, Yuanjie
Luo, Zhihuang
author_facet Kang, Zhengjie
Li, Hao
Wang, Shuo
Li, Jiaojiao
Zhang, Yuanjie
Luo, Zhihuang
contents Learning quantum Hamiltonians with high precision is important for quantum physics and quantum information science. We propose a multi-stage neural network framework that significantly enhances Hamiltonian learning precision through successive network optimization of residual errors. Our approach utilizes time-series data from single-qubit Pauli measurements of random initial states, enabling the estimation of unknown Hamiltonian parameters without prior structural assumptions. We demonstrate the framework on two-qubit systems, achieving orders-of-magnitude improvement in parameter accuracy, and further extend the method to larger systems by integrating dynamical decoupling techniques. Additionally, the protocol exhibits robustness against experimental noise. This work bridges the gap between scalable Hamiltonian learning and high-precision requirements, offering a practical tool for precise quantum control and metrology.
format Preprint
id arxiv_https___arxiv_org_abs_2503_07356
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Enhanced Hamiltonian Learning Precision with Multi-Stage Neural Networks
Kang, Zhengjie
Li, Hao
Wang, Shuo
Li, Jiaojiao
Zhang, Yuanjie
Luo, Zhihuang
Quantum Physics
Learning quantum Hamiltonians with high precision is important for quantum physics and quantum information science. We propose a multi-stage neural network framework that significantly enhances Hamiltonian learning precision through successive network optimization of residual errors. Our approach utilizes time-series data from single-qubit Pauli measurements of random initial states, enabling the estimation of unknown Hamiltonian parameters without prior structural assumptions. We demonstrate the framework on two-qubit systems, achieving orders-of-magnitude improvement in parameter accuracy, and further extend the method to larger systems by integrating dynamical decoupling techniques. Additionally, the protocol exhibits robustness against experimental noise. This work bridges the gap between scalable Hamiltonian learning and high-precision requirements, offering a practical tool for precise quantum control and metrology.
title Enhanced Hamiltonian Learning Precision with Multi-Stage Neural Networks
topic Quantum Physics
url https://arxiv.org/abs/2503.07356

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