JetLOV: enhancing jet tree tagging through neural network learning of optimal LundNet variables
JetLOV: enhancing jet tree tagging through neural network learning of optimal LundNet variables
Machine learning has played a pivotal role in advancing physics, with deep learning notably contributing to solving complex classification problems such as jet tagging in the field of jet physics. In this experiment, we aim to harness the full potential of neural networks while acknowledging that, at times, we may lose sight of the underlying physics governing these models. Nevertheless, we demonstrate that we can achieve remarkable results obscuring physics knowledge and relying completely on the model's outcome. We introduce JetLOV, a composite comprising two models: a straightforward multilayer perceptron (MLP) and the well-established LundNet. Our study reveals that we can attain comparable jet tagging performance without relying on the pre-computed LundNet variables. Instead, we allow the network to autonomously learn an entirely new set of variables, devoid of a priori knowledge of the underlying physics. These findings hold promise, particularly in addressing the issue of model dependence, which can be mitigated through generalization and training on diverse data sets.
hep-ph, cs.LG
Diaz, Mauricio A.
b929a911-11c3-43c8-bd8a-eb2173a4b14e
Cerro, Giorgio
c4363eb0-a9d8-4456-b749-6d4380898b25
Chaplais, Jacan
a0134d97-a233-4f7b-8b1f-3a4156ae5a4c
Dasmahapatra, Srinandan
280ced34-652c-4dbb-80c3-0b19bdd33dd5
Moretti, Stefano
b57cf0f0-4bc3-4e02-96e3-071255366614
Diaz, Mauricio A.
b929a911-11c3-43c8-bd8a-eb2173a4b14e
Cerro, Giorgio
c4363eb0-a9d8-4456-b749-6d4380898b25
Chaplais, Jacan
a0134d97-a233-4f7b-8b1f-3a4156ae5a4c
Dasmahapatra, Srinandan
280ced34-652c-4dbb-80c3-0b19bdd33dd5
Moretti, Stefano
b57cf0f0-4bc3-4e02-96e3-071255366614
[Unknown type: UNSPECIFIED]
Abstract
Machine learning has played a pivotal role in advancing physics, with deep learning notably contributing to solving complex classification problems such as jet tagging in the field of jet physics. In this experiment, we aim to harness the full potential of neural networks while acknowledging that, at times, we may lose sight of the underlying physics governing these models. Nevertheless, we demonstrate that we can achieve remarkable results obscuring physics knowledge and relying completely on the model's outcome. We introduce JetLOV, a composite comprising two models: a straightforward multilayer perceptron (MLP) and the well-established LundNet. Our study reveals that we can attain comparable jet tagging performance without relying on the pre-computed LundNet variables. Instead, we allow the network to autonomously learn an entirely new set of variables, devoid of a priori knowledge of the underlying physics. These findings hold promise, particularly in addressing the issue of model dependence, which can be mitigated through generalization and training on diverse data sets.
Text
2311.14654v1
- Author's Original
Available under License Other.
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Accepted/In Press date: 24 November 2023
Additional Information:
Accepted at the NeurIPS 2023 workshop: Machine Learning and the Physical Sciences
Keywords:
hep-ph, cs.LG
Identifiers
Local EPrints ID: 485088
URI: http://eprints.soton.ac.uk/id/eprint/485088
PURE UUID: beee2c10-b8ac-4064-9407-381011176965
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Date deposited: 29 Nov 2023 17:34
Last modified: 18 Mar 2024 02:57
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Contributors
Author:
Mauricio A. Diaz
Author:
Jacan Chaplais
Author:
Srinandan Dasmahapatra
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