用于粒子跟踪和重建的图神经网络

Javier Mauricio Duarte, J. Vlimant
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引用次数: 42

摘要

机器学习方法在高能物理(HEP)中有着悠久的应用历史。最近,人们对利用这些方法从原始探测器数据中重建粒子特征越来越感兴趣。为了从最初为计算机视觉或自然语言处理任务设计的现代深度学习算法中受益,将HEP数据转换为图像或序列是常见的做法。相反,图神经网络(gnn)对具有一组特征及其成对连接的元素组成的图数据进行操作,提供了一种结合权重共享、局部连接和专业领域知识的替代方法。粒子物理数据,例如跟踪检测器中的命中,通常可以用图形表示,使gnn的使用变得自然。在本章中,我们概述了gnn的数学形式,并强调了在为HEP数据设计这些网络时需要考虑的方面,包括图构建、模型架构、学习目标和图池化。我们还回顾了gnn在HEP中粒子跟踪和重建方面的应用前景,并总结了它们在当前和未来实验中的应用前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Graph Neural Networks for Particle Tracking and Reconstruction
Machine learning methods have a long history of applications in high energy physics (HEP). Recently, there is a growing interest in exploiting these methods to reconstruct particle signatures from raw detector data. In order to benefit from modern deep learning algorithms that were initially designed for computer vision or natural language processing tasks, it is common practice to transform HEP data into images or sequences. Conversely, graph neural networks (GNNs), which operate on graph data composed of elements with a set of features and their pairwise connections, provide an alternative way of incorporating weight sharing, local connectivity, and specialized domain knowledge. Particle physics data, such as the hits in a tracking detector, can generally be represented as graphs, making the use of GNNs natural. In this chapter, we recapitulate the mathematical formalism of GNNs and highlight aspects to consider when designing these networks for HEP data, including graph construction, model architectures, learning objectives, and graph pooling. We also review promising applications of GNNs for particle tracking and reconstruction in HEP and summarize the outlook for their deployment in current and future experiments.
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