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引用次数: 0
摘要
将粒子分布函数(PDF,或粒子密度)的性质与产生这些性质的 QCD 分析中的理论假设定量地联系起来,一直是 HEP 现象学中一个长期存在的问题。为了应对这一挑战,我们引入了一个基于 ML 的可解释性框架 XAI4PDF,利用类似 ResNet 的神经网络(NNs),按照粒子味道或基础理论模型对 PDF 进行分类。通过利用 ResNet 模型的可微分性,这种方法部署了引导反向传播来剖析拟合 PDF 的相关特征,从而识别对 ML 模型分类非常重要的 PDF x 依赖性特征。通过应用我们的框架,我们能够根据产生 PDF 的分析对 PDF 进行分类,同时构建定量的、人类可读的地图,定位受每个分析的内部理论假设影响最大的 x 区域。这项技术扩展了用于 PDF 分析和邻近粒子现象学的工具包,同时指出了前景广阔的一般化方法。
Explainable AI classification for parton density theory
Quantitatively connecting properties of parton distribution functions (PDFs, or parton densities) to the theoretical assumptions made within the QCD analyses which produce them has been a longstanding problem in HEP phenomenology. To confront this challenge, we introduce an ML-based explainability framework, XAI4PDF, to classify PDFs by parton flavor or underlying theoretical model using ResNet-like neural networks (NNs). By leveraging the differentiable nature of ResNet models, this approach deploys guided backpropagation to dissect relevant features of fitted PDFs, identifying x-dependent signatures of PDFs important to the ML model classifications. By applying our framework, we are able to sort PDFs according to the analysis which produced them while constructing quantitative, human-readable maps locating the x regions most affected by the internal theory assumptions going into each analysis. This technique expands the toolkit available to PDF analysis and adjacent particle phenomenology while pointing to promising generalizations.
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).