Continuous-variable quantum kernel method on a programmable photonic quantum processor

IF 2.9 2区物理与天体物理 Q2 Physics and Astronomy

Physical Review A Pub Date : 2024-08-02 DOI:10.1103/physreva.110.022404

Keitaro Anai, Shion Ikehara, Yoshichika Yano, Daichi Okuno, Shuntaro Takeda

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Abstract

Among various quantum machine learning (QML) algorithms, the quantum kernel method has especially attracted attention due to its compatibility with noisy intermediate-scale quantum devices and its potential to achieve quantum advantage. This method performs classification and regression by nonlinearly mapping data into quantum states in a higher-dimensional Hilbert space. Thus far, the quantum kernel method has been implemented only on qubit-based systems, but continuous-variable (CV) systems can potentially offer superior computational power by utilizing its infinite-dimensional Hilbert space. Here, we demonstrate the implementation of the classification task with the CV quantum kernel method on a programmable photonic quantum processor. We experimentally prove that the CV quantum kernel method successfully classifies several datasets robustly even under the experimental imperfections, with high accuracies comparable to the classical kernel. This demonstration sheds light on the utility of CV quantum systems for QML and should stimulate further study in other CV QML algorithms.

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可编程光子量子处理器上的连续可变量子核方法

在各种量子机器学习（QML）算法中，量子核方法因其与噪声中等规模量子设备的兼容性及其实现量子优势的潜力而尤其受到关注。这种方法通过将数据非线性地映射到高维希尔伯特空间中的量子态来执行分类和回归。迄今为止，量子核方法只在基于量子比特的系统上实现过，但连续可变（CV）系统利用其无限维希尔伯特空间，有可能提供更强的计算能力。在这里，我们演示了在可编程光子量子处理器上利用 CV 量子核方法实现分类任务。我们通过实验证明，即使在实验不完善的情况下，CV 量子核方法也能成功地对多个数据集进行稳健分类，其高精度可与经典核相媲美。这一演示揭示了 CV 量子系统在 QML 中的实用性，并将促进对其他 CV QML 算法的进一步研究。

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来源期刊

Physical Review A 物理-光学

CiteScore

5.40

自引率

24.10%

发文量

审稿时长

2.2 months

期刊介绍： Physical Review A (PRA) publishes important developments in the rapidly evolving areas of atomic, molecular, and optical (AMO) physics, quantum information, and related fundamental concepts. PRA covers atomic, molecular, and optical physics, foundations of quantum mechanics, and quantum information, including: -Fundamental concepts -Quantum information -Atomic and molecular structure and dynamics; high-precision measurement -Atomic and molecular collisions and interactions -Atomic and molecular processes in external fields, including interactions with strong fields and short pulses -Matter waves and collective properties of cold atoms and molecules -Quantum optics, physics of lasers, nonlinear optics, and classical optics