Search for mono-Higgs signals in bb final states using deep neural networks
Search for mono-Higgs signals in bb final states using deep neural networks
We study mono-Higgs signatures emerging in an illustrative new physics scenario involving Standard Model Higgs boson decays to bottom quark pairs using Hybrid Deep Neural Networks. We use a Multi-Layer Perceptron to analyze the kinematic observables and optimize the signal-to-background discrimination. The global color flow structure of hard jets emerging from the decay of heavy particles with different color charges is crucial to single out the mono-Higgs signature. Upon embedding the different color flow structures for signal and backgrounds into constructed images, we use a Convolution Neural Network to analyze the latter. Specifically, the approach takes initially a mono-type data as input, frittering away invaluable multi-source and multi-scale information. We then discuss a general architecture of Hybrid Deep Neural Networks that supports instead mixed input data. In comparison with single input Deep Neural Networks, like MultiLayers Perceptron or Convolution Neural Network, the Hybrid Deep Neural Networks provide higher capacity in feature extraction and thus in signal vs background classification performance. We provide reference results for the case of the High-Luminosity Large Hadron Collider.
hep-ph
Hammad, A.
08f4a260-b5e7-404f-aa33-131cb5097394
Khalil, S.
6021465e-2f5d-4677-846d-05aebc4499f6
Moretti, S.
b57cf0f0-4bc3-4e02-96e3-071255366614
24 April 2023
Hammad, A.
08f4a260-b5e7-404f-aa33-131cb5097394
Khalil, S.
6021465e-2f5d-4677-846d-05aebc4499f6
Moretti, S.
b57cf0f0-4bc3-4e02-96e3-071255366614
Hammad, A., Khalil, S. and Moretti, S.
(2023)
Search for mono-Higgs signals in bb final states using deep neural networks.
Physical Review D, 107 (7), [075027].
(doi:10.48550/arXiv.2208.10133).
Abstract
We study mono-Higgs signatures emerging in an illustrative new physics scenario involving Standard Model Higgs boson decays to bottom quark pairs using Hybrid Deep Neural Networks. We use a Multi-Layer Perceptron to analyze the kinematic observables and optimize the signal-to-background discrimination. The global color flow structure of hard jets emerging from the decay of heavy particles with different color charges is crucial to single out the mono-Higgs signature. Upon embedding the different color flow structures for signal and backgrounds into constructed images, we use a Convolution Neural Network to analyze the latter. Specifically, the approach takes initially a mono-type data as input, frittering away invaluable multi-source and multi-scale information. We then discuss a general architecture of Hybrid Deep Neural Networks that supports instead mixed input data. In comparison with single input Deep Neural Networks, like MultiLayers Perceptron or Convolution Neural Network, the Hybrid Deep Neural Networks provide higher capacity in feature extraction and thus in signal vs background classification performance. We provide reference results for the case of the High-Luminosity Large Hadron Collider.
Text
PhysRevD.107.075027
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More information
Accepted/In Press date: 6 April 2023
Published date: 24 April 2023
Additional Information:
Funding: A. H. is funded by the Grant No. NRF 2021R1A2C4002551. S. M. is supported in part through the NExT Institute and the STFC Consolidated Grant
No. ST/L000296/1.
Keywords:
hep-ph
Identifiers
Local EPrints ID: 472298
URI: http://eprints.soton.ac.uk/id/eprint/472298
ISSN: 2470-0010
PURE UUID: 1578e4ea-bfc4-4c67-92a4-2a82f6320a2c
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Date deposited: 30 Nov 2022 17:49
Last modified: 17 Mar 2024 02:58
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Author:
A. Hammad
Author:
S. Khalil
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