用于反中子重建的视觉热量计:基线

Hongtian Yu, Yangu Li, Mingrui Wu, Letian Shen, Yue Liu, Yunxuan Song, Qixiang Ye, Xiaorui Lyu, Yajun Mao, Yangheng Zheng, Yunfan Liu
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引用次数: 0

摘要

在高能物理中,反中子($\bar{n}$)是经常作为终态粒子出现的基本粒子,重建它们的运动学特性为理解其支配原理提供了一个重要的探针。然而,电磁量热仪(EMC)作为一种典型的实验传感器,却无法充分恢复入射$\bar{n}$的信息,这在仪器上面临着巨大的挑战。在这项研究中,我们引入了Vision Calorimeter(ViC),这是一种反中子重构的基准方法,它利用深度学习检测器来分析电磁量热计响应与入射$\bar{n}$特征之间的隐含关系。我们的动机在于,沉积在 EMC 单元阵列中的 $\bar{n}$ 样品的能量分布包含了丰富的上下文信息。转换成二维图像后,这种上下文能量分布可以通过深度学习检测器、伪包围盒和指定的训练目标来预测$\bar{n}$的状态(即$\bar{n}$的事件位置和动量)。实验结果表明,ViC大大优于传统的重构方法,入射位置的预测误差降低了42.81%(从17.31$^{\circ}$降至9.90$^{\circ}$)。更重要的是,这项研究首次实现了对入射$\bar{n}$动量的测量,凸显了深度学习探测器在粒子重构方面的潜力。代码见 https://github.com/yuhongtian17/ViC。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Vision Calorimeter for Anti-neutron Reconstruction: A Baseline
In high-energy physics, anti-neutrons ($\bar{n}$) are fundamental particles that frequently appear as final-state particles, and the reconstruction of their kinematic properties provides an important probe for understanding the governing principles. However, this confronts significant challenges instrumentally with the electromagnetic calorimeter (EMC), a typical experimental sensor but recovering the information of incident $\bar{n}$ insufficiently. In this study, we introduce Vision Calorimeter (ViC), a baseline method for anti-neutron reconstruction that leverages deep learning detectors to analyze the implicit relationships between EMC responses and incident $\bar{n}$ characteristics. Our motivation lies in that energy distributions of $\bar{n}$ samples deposited in the EMC cell arrays embody rich contextual information. Converted to 2-D images, such contextual energy distributions can be used to predict the status of $\bar{n}$ ($i.e.$, incident position and momentum) through a deep learning detector along with pseudo bounding boxes and a specified training objective. Experimental results demonstrate that ViC substantially outperforms the conventional reconstruction approach, reducing the prediction error of incident position by 42.81% (from 17.31$^{\circ}$ to 9.90$^{\circ}$). More importantly, this study for the first time realizes the measurement of incident $\bar{n}$ momentum, underscoring the potential of deep learning detectors for particle reconstruction. Code is available at https://github.com/yuhongtian17/ViC.
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