粒子物理学中的无监督和轻监督学习

Jai Bardhan, Tanumoy Mandal, Subhadip Mitra, Cyrin Neeraj, Monalisa Patra
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摘要

我们回顾了非完全监督的机器学习模型在粒子物理中的主要应用,即聚类、异常检测、探测器模拟和展开。无监督方法是异常检测任务的理想选择--如果我们对背景数据进行精确建模,机器学习模型可以在背景数据上进行训练,从而识别偏差。如果我们能提供一些数据层面的异常信息,那么学习也可以是部分无监督的。生成模型在加速探测器模拟方面非常有用--它们可以在不需要大量资源的情况下模拟计算密集型任务。它们还能有效地将探测器级数据映射到粒子级数据(即数据展开)。在这篇综述中,我们将重点讨论有趣的想法和联系,并在必要时简要概述基础技术。
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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Unsupervised and lightly supervised learning in particle physics

We review the main applications of machine learning models that are not fully supervised in particle physics, i.e., clustering, anomaly detection, detector simulation, and unfolding. Unsupervised methods are ideal for anomaly detection tasks—machine learning models can be trained on background data to identify deviations if we model the background data precisely. The learning can also be partially unsupervised when we can provide some information about the anomalies at the data level. Generative models are useful in speeding up detector simulations—they can mimic the computationally intensive task without large resources. They can also efficiently map detector-level data to parton-level data (i.e., data unfolding). In this review, we focus on interesting ideas and connections and briefly overview the underlying techniques wherever necessary.

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