Quantum similarity learning for anomaly detection

IF 5.5 1区物理与天体物理 Q1 Physics and Astronomy Journal of High Energy Physics Pub Date : 2025-02-12 DOI:10.1007/JHEP02(2025)081

A. Hammad, Mihoko M. Nojiri, Masahito Yamazaki

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Abstract

Anomaly detection is a vital technique for exploring signatures of new physics Beyond the Standard Model (BSM) at the Large Hadron Collider (LHC). The vast number of collisions generated by the LHC demands sophisticated deep learning techniques. Similarity learning, a self-supervised machine learning, detects anomalous signals by estimating their similarity to background events. In this paper, we explore the potential of quantum computers for anomaly detection through similarity learning, leveraging the power of quantum computing to enhance the known similarity learning method. In the realm of noisy intermediate-scale quantum (NISQ) devices, we employ a hybrid classical-quantum network to search for heavy scalar resonances in the di-Higgs production channel. In the absence of quantum noise, the hybrid network demonstrates improvement over the known similarity learning method. Moreover, we employ a clustering algorithm to reduce measurement noise from limited shot counts, resulting in 9% improvement in the hybrid network performance. Our analysis highlights the applicability of quantum algorithms for LHC data analysis, where improvements are anticipated with the advent of fault-tolerant quantum computers.

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用于异常检测的量子相似性学习

异常检测是在大型强子对撞机（LHC）上探索超越标准模型（BSM）的新物理特征的一项重要技术。大型强子对撞机产生的大量碰撞需要复杂的深度学习技术。相似学习是一种自监督机器学习，通过估计异常信号与背景事件的相似度来检测异常信号。在本文中，我们探索了量子计算机通过相似学习进行异常检测的潜力，利用量子计算的力量来增强已知的相似学习方法。在有噪声的中尺度量子（NISQ）器件领域，我们采用混合经典量子网络来搜索双希格斯产生通道中的重标量共振。在没有量子噪声的情况下，混合网络比已知的相似学习方法有了改进。此外，我们采用了一种聚类算法来减少有限射击计数的测量噪声，从而使混合网络的性能提高了9%。我们的分析强调了量子算法在大型强子对撞机数据分析中的适用性，随着容错量子计算机的出现，预计量子算法将得到改进。

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来源期刊

Journal of High Energy Physics 物理-物理：粒子与场物理

CiteScore

10.30

自引率

46.30%

发文量

2107

审稿时长

1.5 months

期刊介绍： The aim of the Journal of High Energy Physics (JHEP) is to ensure fast and efficient online publication tools to the scientific community, while keeping that community in charge of every aspect of the peer-review and publication process in order to ensure the highest quality standards in the journal. Consequently, the Advisory and Editorial Boards, composed of distinguished, active scientists in the field, jointly establish with the Scientific Director the journal''s scientific policy and ensure the scientific quality of accepted articles. JHEP presently encompasses the following areas of theoretical and experimental physics: Collider Physics Underground and Large Array Physics Quantum Field Theory Gauge Field Theories Symmetries String and Brane Theory General Relativity and Gravitation Supersymmetry Mathematical Methods of Physics Mostly Solvable Models Astroparticles Statistical Field Theories Mostly Weak Interactions Mostly Strong Interactions Quantum Field Theory (phenomenology) Strings and Branes Phenomenological Aspects of Supersymmetry Mostly Strong Interactions (phenomenology).

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