Quantum channel learning.

IF 2.4 3区物理与天体物理 Q1 Mathematics

Physical review. E Pub Date : 2025-01-01 DOI:10.1103/PhysRevE.111.015302

Mikhail Gennadievich Belov, Victor Victorovich Dubov, Alexey Vladimirovich Filimonov, Vladislav Gennadievich Malyshkin

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引用次数: 0

Abstract

The problem of an optimal mapping between Hilbert spaces IN and OUT, based on a series of density matrix mapping measurements ρ^{(l)}→ϱ^{(l)}, l=1⋯M, is formulated as an optimization problem maximizing the total fidelity F=∑_{l=1}^{M}ω^{(l)}F(ϱ^{(l)},∑_{s}B_{s}ρ^{(l)}B_{s}^{†}) subject to probability preservation constraints on Kraus operators B_{s}. For F(ϱ,σ) in the form that total fidelity can be represented as a quadratic form with superoperator F=∑_{s}〈B_{s}|S|B_{s}〉 (either exactly or as an approximation) an iterative algorithm is developed. The work introduces two important generalizations of unitary learning: (1) IN/OUT states are represented as density matrices; (2) the mapping itself is formulated as a mixed unitary quantum channel A^{OUT}=∑_{s}|w_{s}|^{2}U_{s}A^{IN}U_{s}^{†} (no general quantum channel yet). This marks a crucial advancement from the commonly studied unitary mapping of pure states ϕ_{l}=Uψ_{l} to a quantum channel, which allows us to distinguish probabilistic mixture of states and their superposition. An application of the approach is demonstrated on unitary learning of density matrix mapping ϱ^{(l)}=Uρ^{(l)}U^{†}, in this case a quadratic on U fidelity can be constructed by considering sqrt[ρ^{(l)}]→sqrt[ϱ^{(l)}] mapping, and on a quantum channel, where quadratic on B_{s} fidelity is an approximation-a quantum channel is then obtained as a hierarchy of unitary mappings, a mixed unitary channel. The approach can be applied to studying quantum inverse problems, variational quantum algorithms, quantum tomography, and more. A software product implementing the algorithm is available from the authors.

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量子信道学习。

基于一系列密度矩阵映射测量ρ^{(l)}→ϱ^{(l)}, l=1⋯M的Hilbert空间IN和OUT之间的最优映射问题，被表示为一个优化问题，在Kraus算子B_{s}的概率保持约束下，最大化总保真度F=∑_{l=1}^{M}ω^{(l)}F(ϱ^{（l)},∑_{s}B_{s}ρ^{(l)}B_{s}^{†}）。对于F（ϱ，σ）的全保真度可表示为二次型的超算子F=∑_{s} < B_{s}| s |B_{s} >（精确或近似），提出了一种迭代算法。这项工作引入了两个重要的酉学习推广：(1)IN/OUT状态被表示为密度矩阵；(2)将映射本身表述为混合酉量子通道a ^{OUT}=∑_{s}|w_{s}|^{2}U_{s} a ^{IN}U_{s}^{†}（尚未有通用量子通道）。这标志着一个重要的进步，从通常研究的纯态的幺正映射（ _{l}=Uψ_{l}）到量子信道，它允许我们区分状态的概率混合和它们的叠加。在密度矩阵映射ϱ^{(l)}= ρ^{(l)}U^{†}的幺正学习上证明了该方法的应用，在这种情况下，可以通过考虑sqrt[ρ^{(l)}]→sqrt[ϱ^{(l)}]映射来构造U保真度上的二次元，并且在量子信道上，其中B_{s}保真度上的二次元是一个近似-然后得到一个量子信道作为幺正映射的层次，即混合幺正信道。该方法可以应用于研究量子逆问题、变分量子算法、量子层析成像等。实现该算法的软件产品可从作者处获得。

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

Physical review. E 物理-物理：流体与等离子体

CiteScore

4.60

自引率

16.70%

发文量

审稿时长

3.3 months

期刊介绍： Physical Review E (PRE), broad and interdisciplinary in scope, focuses on collective phenomena of many-body systems, with statistical physics and nonlinear dynamics as the central themes of the journal. Physical Review E publishes recent developments in biological and soft matter physics including granular materials, colloids, complex fluids, liquid crystals, and polymers. The journal covers fluid dynamics and plasma physics and includes sections on computational and interdisciplinary physics, for example, complex networks.