Application of Machine Learning Methods for Classification of Gamma and Hadron Signals in High Energy Particle Detection
Dublin Core
Title
Application of Machine Learning Methods for Classification of Gamma and Hadron Signals in High Energy Particle Detection
Subject
Gamma signal detection, particle physics classification, machine learning algorithms,monte carlo simulation, geometric parameter analysis
Description
A major challenge in particle physics is the binary classification of high-energy gamma signals against
a complex hadron background. Accurate dentification of these gamma signals is critical for particle detection, especially as the volume and complexity of data increases as technology advances. The research developed a machine learning-based classification model to efficiently and accurately distinguish gamma signals from hadrons. Logistic Regression, Decision Trees, Random Forests, and Artificial Neural Networks are used for classification. Principal Component Analysis (PCA) and correlation analysis identified dominant features, while Monte Carlo simulations validated the distribution of gamma and hadron spectra. This study focuses on geometric parameters such as fLength, fWidth, fAlpha, as well as photon distribution and distance effects (fDist) in gamma signal identification using K-Means clustering. The Random Forest algorithm achieved the highest accuracy of 87.96%, with an F1-score of 0.91, which defines its robustness in the classification task. PCA and correlation
analysis showed fSize, fLength, and fWidth as the most influential factorsin classification. Monte Carlo simulations successfully replicated the spectral distribution pattern with high experimental validation. The research presents a novel integration of geometric analysis, clustering techniques, and simulation validation in the classification of high-energy particles. Machine learning methods, in particular Random Forest, effectively distinguish the gamma signal from the hadron background. The combination of PCA and Monte Carlo simulations improves the understanding of data distribution patterns and key classification factors. This research contributes to the development of a more reliable astrophysical signal classification system with potential applications in large-scale astronomical data
management.
a complex hadron background. Accurate dentification of these gamma signals is critical for particle detection, especially as the volume and complexity of data increases as technology advances. The research developed a machine learning-based classification model to efficiently and accurately distinguish gamma signals from hadrons. Logistic Regression, Decision Trees, Random Forests, and Artificial Neural Networks are used for classification. Principal Component Analysis (PCA) and correlation analysis identified dominant features, while Monte Carlo simulations validated the distribution of gamma and hadron spectra. This study focuses on geometric parameters such as fLength, fWidth, fAlpha, as well as photon distribution and distance effects (fDist) in gamma signal identification using K-Means clustering. The Random Forest algorithm achieved the highest accuracy of 87.96%, with an F1-score of 0.91, which defines its robustness in the classification task. PCA and correlation
analysis showed fSize, fLength, and fWidth as the most influential factorsin classification. Monte Carlo simulations successfully replicated the spectral distribution pattern with high experimental validation. The research presents a novel integration of geometric analysis, clustering techniques, and simulation validation in the classification of high-energy particles. Machine learning methods, in particular Random Forest, effectively distinguish the gamma signal from the hadron background. The combination of PCA and Monte Carlo simulations improves the understanding of data distribution patterns and key classification factors. This research contributes to the development of a more reliable astrophysical signal classification system with potential applications in large-scale astronomical data
management.
Creator
Firdaus Andi Wibowo, Tomi Yulianto, Nicholaus Ola Malun, Rizqy Rionaldy, Verdi Yasin, Ruben Cornelius Siagian
Source
DOI: http://dx.doi.org/10.21609/jiki.v18i2.1489
Publisher
Faculty of Computer Science UI
Date
2025-06-26
Contributor
Sri Wahyuni
Rights
ISSN : 2502-9274
Format
PDF
Language
English
Type
Text
Files
Collection
Citation
Firdaus Andi Wibowo, Tomi Yulianto, Nicholaus Ola Malun, Rizqy Rionaldy, Verdi Yasin, Ruben Cornelius Siagian, “Application of Machine Learning Methods for Classification of Gamma and Hadron Signals in High Energy Particle Detection,” Repository Horizon University Indonesia, accessed February 3, 2026, https://repository.horizon.ac.id/items/show/9881.