New Deep Learning Data Analysis Method for PROSPECT using GAPE: Genetic Algorithm Powered Evolution

M Adriamirado; A. B Balantekin; C Bass; O. Benevides Rodrigues; E. P Bernard; N. S Bowden; C. D Bryan; T Classen; A. J Conant; N Craft; A Delgado; G Deichert; M. J Dolinski; A Erickson; M Fuller; A Galindo-Uribarri; S Ghosh; S Gokhale; C Grant; S Hans; A. B Hansell; T. E Haugen; K. M Heeger; B Heffron; A Irani; J Koblanski; C. E Lane; B. R Littlejohn; A. Lozano Sanchez; J Maricic; F Machado; M. P Mendenhall; A. M Meyer; R Milincic; P. E Mueller; H. P Mumm; R Neilson; C Roca; R Rosero; D Venegas-Vargas; J Wilhelmi; M Yeh; X Zhang

doi:10.48550/arxiv.2604.08814

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New Deep Learning Data Analysis Method for PROSPECT using GAPE: Genetic Algorithm Powered Evolution

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New Deep Learning Data Analysis Method for PROSPECT using GAPE: Genetic Algorithm Powered Evolution

M Adriamirado, A. B Balantekin, C Bass, O. Benevides Rodrigues, E. P Bernard, N. S Bowden, C. D Bryan, T Classen, A. J Conant, N Craft, …

ArXiv.org

09 Apr 2026

DOI: https://doi.org/10.48550/arxiv.2604.08814

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Abstract

Physics - Data Analysis, Statistics and Probability

Physics - High Energy Physics - Experiment

We propose a genetic algorithm powered evolution (GAPE) method to create deep learning solutions for energy and position estimation for reactor antineutrino interactions in the Precision Reactor Oscillation and Spectrum Experiment (PROSPECT) at the highly enriched High Flux Isotope Reactor (HFIR) at Oak Ridge National Laboratory. We also apply GAPE to create classification models to distinguish signatures of inverse beta decay (IBD) interactions of reactor antineutrinos from common background types. The GAPE method can also be adopted for optimization of other types of problems that utilize machine learning (ML) models for particle physics applications. When applied in the PROSPECT context, we find that the models selected by GAPE can, in some cases, outperform the traditional models previously used for PROSPECT data analysis. In particular, when benchmarked against conventional PROSPECT neutrino identification pathways using the same underlying information, the classifier offers the promise of improving the signal-to-background ratio by nearly 2.8 times. Performance biases uncovered during initial IBD classifier validation were primarily caused by differences in time-dependent response between background and signal training datasets. Biases were effectively mitigated through a data-period-specific training regimen, offering a pathway towards realizing an unbiased IBD signal classifier for future reactor neutrino datasets.

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Title: New Deep Learning Data Analysis Method for PROSPECT using GAPE: Genetic Algorithm Powered Evolution
Creators: M Adriamirado
A. B Balantekin
C Bass
O. Benevides Rodrigues
E. P Bernard
N. S Bowden
C. D Bryan
T Classen
A. J Conant
N Craft
A Delgado
G Deichert
M. J Dolinski
A Erickson
M Fuller
A Galindo-Uribarri
S Ghosh
S Gokhale
C Grant
S Hans
A. B Hansell
T. E Haugen
K. M Heeger
B Heffron
A Irani
J Koblanski
C. E Lane
B. R Littlejohn
A. Lozano Sanchez
J Maricic
F Machado
M. P Mendenhall
A. M Meyer
R Milincic
P. E Mueller
H. P Mumm
R Neilson
C Roca
R Rosero
D Venegas-Vargas
J Wilhelmi
M Yeh
X Zhang
Publication Details: ArXiv.org
Resource Type: Preprint
Language: English
Academic Unit: Accelerated Career Entry Bachelor of Science in Nursing (BSN); Physics
Other Identifier: 991022172656404721

New Deep Learning Data Analysis Method for PROSPECT using GAPE: Genetic Algorithm Powered Evolution

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