Optimal estimates of trace distance between bosonic Gaussian states and applications to learning

IF 5.1 2区物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY

Quantum Pub Date : 2025-06-12 DOI:10.22331/q-2025-06-12-1769

Lennart Bittel, Francesco Anna Mele, Antonio Anna Mele, Salvatore Tirone, Ludovico Lami

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Abstract

Gaussian states of bosonic quantum systems enjoy numerous technological applications and are ubiquitous in nature. Their significance lies in their simplicity, which in turn rests on the fact that they are uniquely determined by two experimentally accessible quantities, their first and second moments. But what if these moments are only known approximately, as is inevitable in any realistic experiment? What is the resulting error on the Gaussian state itself, as measured by the most operationally meaningful metric for distinguishing quantum states, namely, the trace distance? In this work, we fully resolve this question by demonstrating that if the first and second moments are known up to an error $\varepsilon$, the trace distance error on the state also scales as $\varepsilon$, and this functional dependence is optimal. To prove this, we establish tight bounds on the trace distance between two Gaussian states in terms of the norm distance of their first and second moments. As an application, we improve existing bounds on the sample complexity of tomography of Gaussian states.

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玻色子高斯态间迹距的最优估计及其在学习中的应用

玻色子量子系统的高斯态具有许多技术应用，并且在自然界中无处不在。它们的意义在于它们的简单性，而简单性又依赖于这样一个事实，即它们是由两个实验上可获得的量——它们的第一阶矩和第二阶矩——唯一地决定的。但是，如果这些时刻只是大致已知的，就像任何现实实验中不可避免的那样呢？高斯态本身的结果误差是什么，用最有意义的度量来区分量子态，即跟踪距离来测量？在这项工作中，我们通过证明如果第一和第二矩已知到误差$\varepsilon$，则状态上的跟踪距离误差也缩放为$\varepsilon$，并且这种函数依赖性是最优的，从而完全解决了这个问题。为了证明这一点，我们根据两个高斯态的第一阶矩和第二阶矩的范数距离建立了它们之间的迹距的紧界。作为一个应用，我们改进了高斯态层析成像的样本复杂度的现有界限。

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

Quantum Physics and Astronomy-Physics and Astronomy (miscellaneous)

CiteScore

9.20

自引率

10.90%

发文量

241

审稿时长

16 weeks

期刊介绍： Quantum is an open-access peer-reviewed journal for quantum science and related fields. Quantum is non-profit and community-run: an effort by researchers and for researchers to make science more open and publishing more transparent and efficient.