Modeling charged-particle multiplicity distributions at LHC

Amr Radi

doi:10.1142/S0217732320503022

Modeling charged-particle multiplicity distributions at LHC

Amr Radi^*

^*المؤلف المقابل لهذا العمل

Physics

نتاج البحث: المساهمة في مجلة › Article › مراجعة النظراء

2 اقتباسات (Scopus)

ملخص

With many applications in high-energy physics, Deep Learning or Deep Neural Network (DNN) has become noticeable and practical in recent years. In this article, a new technique is presented for modeling the charged particles multiplicity distribution Pn of Proton-Proton (PP) collisions using an efficient DNN model. The charged particles multiplicity n, the total center of mass energy s, and the pseudorapidity η used as input in DNN model and the desired output is Pn. DNN was trained to build a function, which studies the relationship between Pn n,s,η. The DNN model showed a high degree of consistency in matching the data distributions. The DNN model is used to predict with Pn not included in the training set. The expected Pn had effectively merged the experimental data and the values expected indicate a strong agreement with Large Hadron Collider (LHC) for ATLAS measurement at s = 0.9, 7 and 8 TeV.

اللغة الأصلية	English
رقم المقال	2050302
دورية	Modern Physics Letters A
مستوى الصوت	35
رقم الإصدار	36
المعرِّفات الرقمية للأشياء	https://doi.org/10.1142/S0217732320503022
حالة النشر	Published - نوفمبر 30 2020

ASJC Scopus subject areas

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10.1142/S0217732320503022

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قم بذكر هذا

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title = "Modeling charged-particle multiplicity distributions at LHC",

abstract = "With many applications in high-energy physics, Deep Learning or Deep Neural Network (DNN) has become noticeable and practical in recent years. In this article, a new technique is presented for modeling the charged particles multiplicity distribution Pn of Proton-Proton (PP) collisions using an efficient DNN model. The charged particles multiplicity n, the total center of mass energy s, and the pseudorapidity η used as input in DNN model and the desired output is Pn. DNN was trained to build a function, which studies the relationship between Pn n,s,η. The DNN model showed a high degree of consistency in matching the data distributions. The DNN model is used to predict with Pn not included in the training set. The expected Pn had effectively merged the experimental data and the values expected indicate a strong agreement with Large Hadron Collider (LHC) for ATLAS measurement at s = 0.9, 7 and 8 TeV.",

keywords = "Charged particles multiplicity distribution, charged particles multiplicity, deep neural network, the total center of mass energy, and the pseudorapidity",

author = "Amr Radi",

note = "Publisher Copyright: {\textcopyright} 2020 World Scientific Publishing Company.",

year = "2020",

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doi = "10.1142/S0217732320503022",

language = "English",

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T1 - Modeling charged-particle multiplicity distributions at LHC

AU - Radi, Amr

PY - 2020/11/30

Y1 - 2020/11/30

N2 - With many applications in high-energy physics, Deep Learning or Deep Neural Network (DNN) has become noticeable and practical in recent years. In this article, a new technique is presented for modeling the charged particles multiplicity distribution Pn of Proton-Proton (PP) collisions using an efficient DNN model. The charged particles multiplicity n, the total center of mass energy s, and the pseudorapidity η used as input in DNN model and the desired output is Pn. DNN was trained to build a function, which studies the relationship between Pn n,s,η. The DNN model showed a high degree of consistency in matching the data distributions. The DNN model is used to predict with Pn not included in the training set. The expected Pn had effectively merged the experimental data and the values expected indicate a strong agreement with Large Hadron Collider (LHC) for ATLAS measurement at s = 0.9, 7 and 8 TeV.

AB - With many applications in high-energy physics, Deep Learning or Deep Neural Network (DNN) has become noticeable and practical in recent years. In this article, a new technique is presented for modeling the charged particles multiplicity distribution Pn of Proton-Proton (PP) collisions using an efficient DNN model. The charged particles multiplicity n, the total center of mass energy s, and the pseudorapidity η used as input in DNN model and the desired output is Pn. DNN was trained to build a function, which studies the relationship between Pn n,s,η. The DNN model showed a high degree of consistency in matching the data distributions. The DNN model is used to predict with Pn not included in the training set. The expected Pn had effectively merged the experimental data and the values expected indicate a strong agreement with Large Hadron Collider (LHC) for ATLAS measurement at s = 0.9, 7 and 8 TeV.

KW - Charged particles multiplicity distribution

KW - charged particles multiplicity

KW - deep neural network

KW - the total center of mass energy, and the pseudorapidity

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Modeling charged-particle multiplicity distributions at LHC

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ASJC Scopus subject areas

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