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Main Authors: Builtjes, Luc, Caron, Sascha, Moskvitina, Polina, Nellist, Clara, de Austri, Roberto Ruiz, Verheyen, Rob, Zhang, Zhongyi
Format: Preprint
Published: 2022
Subjects:
Online Access:https://arxiv.org/abs/2211.05143
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author Builtjes, Luc
Caron, Sascha
Moskvitina, Polina
Nellist, Clara
de Austri, Roberto Ruiz
Verheyen, Rob
Zhang, Zhongyi
author_facet Builtjes, Luc
Caron, Sascha
Moskvitina, Polina
Nellist, Clara
de Austri, Roberto Ruiz
Verheyen, Rob
Zhang, Zhongyi
contents A major task in particle physics is the measurement of rare signal processes. Even modest improvements in background rejection, at a fixed signal efficiency, can significantly enhance the measurement sensitivity. Building on prior research by others that incorporated physical symmetries into neural networks, this work extends those ideas to include additional physics-motivated features. Specifically, we introduce energy-dependent particle interaction strengths, derived from leading-order SM predictions, into modern deep learning architectures, including Transformer Architectures (Particle Transformer), and Graph Neural Networks (Particle Net). These interaction strengths, represented as the SM interaction matrix, are incorporated into the attention matrix (transformers) and edges (graphs). Our results in event classification show that the integration of all physics-motivated features improves background rejection by $10\%-40\%$ over baseline models, with an additional gain of up to $9\%$ due to the SM interaction matrix. This study also provides one of the broadest comparisons of event classifiers to date, demonstrating how various architectures perform across this task. A simplified statistical analysis demonstrates that these enhanced architectures yield significant improvements in signal significance compared to a graph network baseline.
format Preprint
id arxiv_https___arxiv_org_abs_2211_05143
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Attention to the strengths of physical interactions: Transformer and graph-based event classification for particle physics experiments
Builtjes, Luc
Caron, Sascha
Moskvitina, Polina
Nellist, Clara
de Austri, Roberto Ruiz
Verheyen, Rob
Zhang, Zhongyi
High Energy Physics - Phenomenology
High Energy Physics - Experiment
A major task in particle physics is the measurement of rare signal processes. Even modest improvements in background rejection, at a fixed signal efficiency, can significantly enhance the measurement sensitivity. Building on prior research by others that incorporated physical symmetries into neural networks, this work extends those ideas to include additional physics-motivated features. Specifically, we introduce energy-dependent particle interaction strengths, derived from leading-order SM predictions, into modern deep learning architectures, including Transformer Architectures (Particle Transformer), and Graph Neural Networks (Particle Net). These interaction strengths, represented as the SM interaction matrix, are incorporated into the attention matrix (transformers) and edges (graphs). Our results in event classification show that the integration of all physics-motivated features improves background rejection by $10\%-40\%$ over baseline models, with an additional gain of up to $9\%$ due to the SM interaction matrix. This study also provides one of the broadest comparisons of event classifiers to date, demonstrating how various architectures perform across this task. A simplified statistical analysis demonstrates that these enhanced architectures yield significant improvements in signal significance compared to a graph network baseline.
title Attention to the strengths of physical interactions: Transformer and graph-based event classification for particle physics experiments
topic High Energy Physics - Phenomenology
High Energy Physics - Experiment
url https://arxiv.org/abs/2211.05143