Reconstructing a quantum state with a variational autoencoder

IF 0.7 4区 物理与天体物理 Q3 COMPUTER SCIENCE, THEORY & METHODS
Chuangtao Chen, Zhimin He, Zhiming Huang, Haozhen Situ
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引用次数: 1

Abstract

Quantum state tomography (QST) is an important and challenging task in the field of quantum information, which has attracted a lot of attentions in recent years. Machine learning models can provide a classical representation of the quantum state after trained on the measurement outcomes, which are part of effective techniques to solve QST problem. In this work, we use a variational autoencoder (VAE) to learn the measurement distribution of two quantum states generated by MPS circuits. We first consider the Greenberger–Horne–Zeilinger (GHZ) state which can be generated by a simple MPS circuit. Simulation results show that a VAE can reconstruct 3- to 8-qubit GHZ states with a high fidelity, i.e., 0.99, and is robust to depolarizing noise. The minimum number ([Formula: see text]) of training samples required to reconstruct the GHZ state up to 0.99 fidelity scales approximately linearly with the number of qubits ([Formula: see text]). However, for the quantum state generated by a complex MPS circuit, [Formula: see text] increases exponentially with [Formula: see text], especially for the quantum state with high entanglement entropy.
用变分自动编码器重构量子态
量子态层析成像(QST)是量子信息领域的一项重要而富有挑战性的任务,近年来引起了人们的广泛关注。机器学习模型在对测量结果进行训练后,可以提供量子状态的经典表示,这是解决QST问题的有效技术的一部分。在这项工作中,我们使用变分自动编码器(VAE)来学习MPS电路产生的两个量子态的测量分布。我们首先考虑可以由简单的MPS电路产生的Greenberger–Horne–Zeilinger(GHZ)态。仿真结果表明,VAE可以以0.99的高保真度重建3到8量子比特的GHZ状态,并且对去极化噪声具有鲁棒性。重建高达0.99保真度的GHZ状态所需的训练样本的最小数量([公式:见正文])与量子位的数量近似线性([公式,见正文]])。然而,对于复杂MPS电路产生的量子态,[公式:见正文]随[公式:参见正文]呈指数增长,尤其是对于具有高纠缠熵的量子态。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
International Journal of Quantum Information
International Journal of Quantum Information 物理-计算机:理论方法
CiteScore
2.20
自引率
8.30%
发文量
36
审稿时长
10 months
期刊介绍: The International Journal of Quantum Information (IJQI) provides a forum for the interdisciplinary field of Quantum Information Science. In particular, we welcome contributions in these areas of experimental and theoretical research: Quantum Cryptography Quantum Computation Quantum Communication Fundamentals of Quantum Mechanics Authors are welcome to submit quality research and review papers as well as short correspondences in both theoretical and experimental areas. Submitted articles will be refereed prior to acceptance for publication in the Journal.
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