作为量子核方法计算资源的相空间负性

IF 5.1 2区 物理与天体物理 Q1 PHYSICS, MULTIDISCIPLINARY Quantum Pub Date : 2024-11-07 DOI:10.22331/q-2024-11-07-1519
Ulysse Chabaud, Roohollah Ghobadi, Salman Beigi, Saleh Rahimi-Keshari
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引用次数: 0

摘要

量子核方法是在机器学习中实现量子计算优势的一种建议。量子核方法基于经典-量子混合计算,其中一个称为量子核的函数由量子设备估算,而计算的其余部分则以经典方式执行。只有当量子核函数无法在经典计算机上高效估算时,才能通过这种方法实现量子优势。在本文中,我们为玻色子系统量子核函数的高效经典估计提供了充分条件。这些条件基于与量子核相关的数据编码量子态的相空间特性:负体积、非经典深度和超范围,它们被证明是相空间负性的三个特征。我们考虑了涉及具有和不具有自适应非高斯测量的线性光学网络的量子光学示例,并研究了损耗对经典模拟效率的影响。我们的研究结果证明,相空间准概率分布中的负性是基于核方法的量子机器学习的重要资源。
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Phase-space negativity as a computational resource for quantum kernel methods
Quantum kernel methods are a proposal for achieving quantum computational advantage in machine learning. They are based on a hybrid classical-quantum computation where a function called the quantum kernel is estimated by a quantum device while the rest of computation is performed classically. Quantum advantages may be achieved through this method only if the quantum kernel function cannot be estimated efficiently on a classical computer. In this paper, we provide sufficient conditions for the efficient classical estimation of quantum kernel functions for bosonic systems. These conditions are based on phase-space properties of data-encoding quantum states associated with the quantum kernels: negative volume, non-classical depth, and excess range, which are shown to be three signatures of phase-space negativity. We consider quantum optical examples involving linear-optical networks with and without adaptive non-Gaussian measurements, and investigate the effects of loss on the efficiency of the classical simulation. Our results underpin the role of the negativity in phase-space quasi-probability distributions as an essential resource in quantum machine learning based on kernel methods.
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来源期刊
Quantum
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.
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