Insights into Dark Matter Direct Detection Experiments: Decision Trees versus Deep Learning

arXiv - PHYS - Data Analysis, Statistics and Probability Pub Date : 2024-06-14 DOI:arxiv-2406.10372

Daniel E. Lopez-Fogliani, Andres D. Perez, Roberto Ruiz de Austri

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Abstract

The detection of Dark Matter (DM) remains a significant challenge in particle physics. This study exploits advanced machine learning models to improve detection capabilities of liquid xenon time projection chamber experiments, utilizing state-of-the-art transformers alongside traditional methods like Multilayer Perceptrons and Convolutional Neural Networks. We evaluate various data representations and find that simplified feature representations, particularly corrected S1 and S2 signals, retain critical information for classification. Our results show that while transformers offer promising performance, simpler models like XGBoost can achieve comparable results with optimal data representations. We also derive exclusion limits in the cross-section versus DM mass parameter space, showing minimal differences between XGBoost and the best performing deep learning models. The comparative analysis of different machine learning approaches provides a valuable reference for future experiments by guiding the choice of models and data representations to maximize detection capabilities.

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暗物质直接探测实验的启示：决策树与深度学习

暗物质（DM）的探测仍然是粒子物理学中的一项重大挑战。本研究利用先进的机器学习模型来提高液态氙时间投影室实验的探测能力，在使用多层感知器和卷积神经网络等传统方法的同时，还使用了最先进的变压器。我们对各种数据表示进行了评估，发现简化的特征表示，尤其是校正后的 S1 和 S2 信号，保留了分类的关键信息。我们的结果表明，虽然变换器的性能很有前途，但 XGBoost 等更简单的模型也能通过最佳数据表示获得与之相当的结果。我们还得出了横截面与 DM 质量参数空间的排除限制，显示 XGBoost 与表现最佳的深度学习模型之间的差异极小。不同机器学习方法的比较分析为未来的实验提供了有价值的参考，指导了模型和数据表示的选择，从而最大限度地提高了探测能力。

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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arXiv - PHYS - Data Analysis, Statistics and Probability

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