Object detection with deep learning for rare event search in the GADGET II TPC

Tyler Wheeler; S. Ravishankar; C. Wrede; A. Andalib; A. Anthony; Y. Ayyad; B. Jain; A. Jaros; R. Mahajan; L. Schaedig; A. Adams; S. Ahn; J. M. Allmond; D. Bardayan; D. Bazin; K. Bosmpotinis; T. Budner; S. R. Carmichael; S. M. Cha; A. Chen; K. A. Chipps; J. M. Christie; I. Cox; J. Dopfer; M. Friedman; J. Garcia-Duarte; E. Good; T. J. Gray; A. Green; R. Grzywacz; K. Hahn; R. Jain; E. A.M. Jensen; Toby King; S. N. Liddick; B. Longfellow; R. Lubna; C. Marshall; Y. Mishnayot; A. J. Mitchell; F. Montes; T. H. Ogunbeku; J. Owens-Fryar; Steven Pain; J. Pereira; E. Pollacco; A. M. Rogers; M. Z. Serikow; K. Setoodehnia; L. J. Sun; J. Surbrook; A. Tsantiri; L. E. Weghorn

doi:10.1016/j.nima.2025.170659

Object detection with deep learning for rare event search in the GADGET II TPC

Tyler Wheeler, S. Ravishankar, C. Wrede, A. Andalib, A. Anthony, Y. Ayyad, B. Jain, A. Jaros, R. Mahajan, L. Schaedig, A. Adams, S. Ahn, J. M. Allmond, D. Bardayan, D. Bazin, K. Bosmpotinis, T. Budner, S. R. Carmichael, S. M. Cha, A. ChenK. A. Chipps, J. M. Christie, I. Cox, J. Dopfer, M. Friedman, J. Garcia-Duarte, E. Good, T. J. Gray, A. Green, R. Grzywacz, K. Hahn, R. Jain, E. A.M. Jensen, Toby King, S. N. Liddick, B. Longfellow, R. Lubna, C. Marshall, Y. Mishnayot, A. J. Mitchell, F. Montes, T. H. Ogunbeku, J. Owens-Fryar, Steven Pain, J. Pereira, E. Pollacco, A. M. Rogers, M. Z. Serikow, K. Setoodehnia, L. J. Sun, J. Surbrook, A. Tsantiri, L. E. Weghorn

Nuclear Structure and Nuclear Astrophysi

Research output: Contribution to journal › Article › peer-review

Abstract

In the pursuit of identifying rare two-particle events within the GADGET II Time Projection Chamber (TPC), this paper presents a comprehensive approach for leveraging Convolutional Neural Networks (CNNs) and various data processing methods. To address the inherent complexities of 3D TPC track reconstructions, the data is expressed in 2D projections and 1D quantities. This approach capitalizes on the diverse data modalities of the TPC, allowing for the efficient representation of the distinct features of the 3D events, with no loss in topology uniqueness. Additionally, it leverages the computational efficiency of 2D CNNs and benefits from the extensive availability of pre-trained models. Given the scarcity of real training data for the rare events of interest, simulated events are used to train the models to detect real events. To account for potential distribution shifts when predominantly depending on simulations, significant perturbations are embedded within the simulations. This produces a broad parameter space that works to account for potential physics parameter and detector response variations and uncertainties. These parameter-varied simulations are used to train sensitive 2D CNN object detectors. When combined with 1D histogram peak detection algorithms, this multi-modal detection framework is highly adept at identifying rare, two-particle events in data taken during experiment 21072 at the Facility for Rare Isotope Beams (FRIB), demonstrating a 100% recall for events of interest. We present the methods and outcomes of our investigation and discuss the potential future applications of these techniques.

Original language	English
Article number	170659
Journal	Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment
Volume	1080
DOIs	https://doi.org/10.1016/j.nima.2025.170659
State	Published - Nov 2025

Funding

This work was supported by the U.S. National Science Foundation under Grants No. PHY-1102511 , PHY-1565546 , PHY-1913554 , PHY-1811855 , PHY-2209429 , PHY-2310059 , PHY-1848177 (CAREER) (Mississippi State), and CCF-2212065 , the Institute for Basic Science (IBS) of the Republic of Korea under Grant No. IBS-R031-D1 , the International Technology Centre Pacific (ITC-PAC) under Contract No. FA520919PA138 , the U.S. Department of Energy, Office of Science , under awards No. DE-SC0016052 , DE-SC0023529 , DE-SC0024587 , DE-SC0023633 , and DE-FG02-96ER40983 , and Office of Nuclear Physics under Contract No. DE-AC05-00OR22725 (ORNL), the National Nuclear Security Administration under contract No. DE-NA0003899 , and the Independent Research Fund Denmark under projects No. 9040-00076B and 2032-00066B . This material is based upon work supported by the U.S. Department of Energy, Office of Science, Office of Nuclear Physics and used resources of the Facility for Rare Isotope Beams (FRIB) Operations, which is a DOE Office of Science User Facility under Award No. DE-SC0023633 . We also thank Russ Werner and the DECS team for their computing support.

Keywords

Convolutional neural network
GADGET
Machine learning
Object detection
Rare event detection
Time projection chamber

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10.1016/j.nima.2025.170659

Cite this

Wheeler, T., Ravishankar, S., Wrede, C., Andalib, A., Anthony, A., Ayyad, Y., Jain, B., Jaros, A., Mahajan, R., Schaedig, L., Adams, A., Ahn, S., Allmond, J. M., Bardayan, D., Bazin, D., Bosmpotinis, K., Budner, T., Carmichael, S. R., Cha, S. M., ... Weghorn, L. E. (2025). Object detection with deep learning for rare event search in the GADGET II TPC. Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, 1080, Article 170659. https://doi.org/10.1016/j.nima.2025.170659

@article{cfb7faca68e44294bc9b20ea5f086ac7,

title = "Object detection with deep learning for rare event search in the GADGET II TPC",

abstract = "In the pursuit of identifying rare two-particle events within the GADGET II Time Projection Chamber (TPC), this paper presents a comprehensive approach for leveraging Convolutional Neural Networks (CNNs) and various data processing methods. To address the inherent complexities of 3D TPC track reconstructions, the data is expressed in 2D projections and 1D quantities. This approach capitalizes on the diverse data modalities of the TPC, allowing for the efficient representation of the distinct features of the 3D events, with no loss in topology uniqueness. Additionally, it leverages the computational efficiency of 2D CNNs and benefits from the extensive availability of pre-trained models. Given the scarcity of real training data for the rare events of interest, simulated events are used to train the models to detect real events. To account for potential distribution shifts when predominantly depending on simulations, significant perturbations are embedded within the simulations. This produces a broad parameter space that works to account for potential physics parameter and detector response variations and uncertainties. These parameter-varied simulations are used to train sensitive 2D CNN object detectors. When combined with 1D histogram peak detection algorithms, this multi-modal detection framework is highly adept at identifying rare, two-particle events in data taken during experiment 21072 at the Facility for Rare Isotope Beams (FRIB), demonstrating a 100\% recall for events of interest. We present the methods and outcomes of our investigation and discuss the potential future applications of these techniques.",

keywords = "Convolutional neural network, GADGET, Machine learning, Object detection, Rare event detection, Time projection chamber",

author = "Tyler Wheeler and S. Ravishankar and C. Wrede and A. Andalib and A. Anthony and Y. Ayyad and B. Jain and A. Jaros and R. Mahajan and L. Schaedig and A. Adams and S. Ahn and Allmond, \{J. M.\} and D. Bardayan and D. Bazin and K. Bosmpotinis and T. Budner and Carmichael, \{S. R.\} and Cha, \{S. M.\} and A. Chen and Chipps, \{K. A.\} and Christie, \{J. M.\} and I. Cox and J. Dopfer and M. Friedman and J. Garcia-Duarte and E. Good and Gray, \{T. J.\} and A. Green and R. Grzywacz and K. Hahn and R. Jain and Jensen, \{E. A.M.\} and Toby King and Liddick, \{S. N.\} and B. Longfellow and R. Lubna and C. Marshall and Y. Mishnayot and Mitchell, \{A. J.\} and F. Montes and Ogunbeku, \{T. H.\} and J. Owens-Fryar and Steven Pain and J. Pereira and E. Pollacco and Rogers, \{A. M.\} and Serikow, \{M. Z.\} and K. Setoodehnia and Sun, \{L. J.\} and J. Surbrook and A. Tsantiri and Weghorn, \{L. E.\}",

note = "Publisher Copyright: {\textcopyright} 2025 Elsevier B.V.",

year = "2025",

month = nov,

doi = "10.1016/j.nima.2025.170659",

language = "English",

volume = "1080",

journal = "Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment",

issn = "0168-9002",

publisher = "Elsevier",

}

Wheeler, T, Ravishankar, S, Wrede, C, Andalib, A, Anthony, A, Ayyad, Y, Jain, B, Jaros, A, Mahajan, R, Schaedig, L, Adams, A, Ahn, S, Allmond, JM, Bardayan, D, Bazin, D, Bosmpotinis, K, Budner, T, Carmichael, SR, Cha, SM, Chen, A, Chipps, KA, Christie, JM, Cox, I, Dopfer, J, Friedman, M, Garcia-Duarte, J, Good, E, Gray, TJ, Green, A, Grzywacz, R, Hahn, K, Jain, R, Jensen, EAM, King, T, Liddick, SN, Longfellow, B, Lubna, R, Marshall, C, Mishnayot, Y, Mitchell, AJ, Montes, F, Ogunbeku, TH, Owens-Fryar, J, Pain, S, Pereira, J, Pollacco, E, Rogers, AM, Serikow, MZ, Setoodehnia, K, Sun, LJ, Surbrook, J, Tsantiri, A & Weghorn, LE 2025, 'Object detection with deep learning for rare event search in the GADGET II TPC', Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment, vol. 1080, 170659. https://doi.org/10.1016/j.nima.2025.170659

TY - JOUR

T1 - Object detection with deep learning for rare event search in the GADGET II TPC

AU - Wheeler, Tyler

AU - Ravishankar, S.

AU - Wrede, C.

AU - Andalib, A.

AU - Anthony, A.

AU - Ayyad, Y.

AU - Jain, B.

AU - Jaros, A.

AU - Mahajan, R.

AU - Schaedig, L.

AU - Adams, A.

AU - Ahn, S.

AU - Allmond, J. M.

AU - Bardayan, D.

AU - Bazin, D.

AU - Bosmpotinis, K.

AU - Budner, T.

AU - Carmichael, S. R.

AU - Cha, S. M.

AU - Chen, A.

AU - Chipps, K. A.

AU - Christie, J. M.

AU - Cox, I.

AU - Dopfer, J.

AU - Friedman, M.

AU - Garcia-Duarte, J.

AU - Good, E.

AU - Gray, T. J.

AU - Green, A.

AU - Grzywacz, R.

AU - Hahn, K.

AU - Jain, R.

AU - Jensen, E. A.M.

AU - King, Toby

AU - Liddick, S. N.

AU - Longfellow, B.

AU - Lubna, R.

AU - Marshall, C.

AU - Mishnayot, Y.

AU - Mitchell, A. J.

AU - Montes, F.

AU - Ogunbeku, T. H.

AU - Owens-Fryar, J.

AU - Pain, Steven

AU - Pereira, J.

AU - Pollacco, E.

AU - Rogers, A. M.

AU - Serikow, M. Z.

AU - Setoodehnia, K.

AU - Sun, L. J.

AU - Surbrook, J.

AU - Tsantiri, A.

AU - Weghorn, L. E.

PY - 2025/11

Y1 - 2025/11

N2 - In the pursuit of identifying rare two-particle events within the GADGET II Time Projection Chamber (TPC), this paper presents a comprehensive approach for leveraging Convolutional Neural Networks (CNNs) and various data processing methods. To address the inherent complexities of 3D TPC track reconstructions, the data is expressed in 2D projections and 1D quantities. This approach capitalizes on the diverse data modalities of the TPC, allowing for the efficient representation of the distinct features of the 3D events, with no loss in topology uniqueness. Additionally, it leverages the computational efficiency of 2D CNNs and benefits from the extensive availability of pre-trained models. Given the scarcity of real training data for the rare events of interest, simulated events are used to train the models to detect real events. To account for potential distribution shifts when predominantly depending on simulations, significant perturbations are embedded within the simulations. This produces a broad parameter space that works to account for potential physics parameter and detector response variations and uncertainties. These parameter-varied simulations are used to train sensitive 2D CNN object detectors. When combined with 1D histogram peak detection algorithms, this multi-modal detection framework is highly adept at identifying rare, two-particle events in data taken during experiment 21072 at the Facility for Rare Isotope Beams (FRIB), demonstrating a 100% recall for events of interest. We present the methods and outcomes of our investigation and discuss the potential future applications of these techniques.

AB - In the pursuit of identifying rare two-particle events within the GADGET II Time Projection Chamber (TPC), this paper presents a comprehensive approach for leveraging Convolutional Neural Networks (CNNs) and various data processing methods. To address the inherent complexities of 3D TPC track reconstructions, the data is expressed in 2D projections and 1D quantities. This approach capitalizes on the diverse data modalities of the TPC, allowing for the efficient representation of the distinct features of the 3D events, with no loss in topology uniqueness. Additionally, it leverages the computational efficiency of 2D CNNs and benefits from the extensive availability of pre-trained models. Given the scarcity of real training data for the rare events of interest, simulated events are used to train the models to detect real events. To account for potential distribution shifts when predominantly depending on simulations, significant perturbations are embedded within the simulations. This produces a broad parameter space that works to account for potential physics parameter and detector response variations and uncertainties. These parameter-varied simulations are used to train sensitive 2D CNN object detectors. When combined with 1D histogram peak detection algorithms, this multi-modal detection framework is highly adept at identifying rare, two-particle events in data taken during experiment 21072 at the Facility for Rare Isotope Beams (FRIB), demonstrating a 100% recall for events of interest. We present the methods and outcomes of our investigation and discuss the potential future applications of these techniques.

KW - Convolutional neural network

KW - GADGET

KW - Machine learning

KW - Object detection

KW - Rare event detection

KW - Time projection chamber

UR - https://www.scopus.com/pages/publications/105007309209

U2 - 10.1016/j.nima.2025.170659

DO - 10.1016/j.nima.2025.170659

M3 - Article

AN - SCOPUS:105007309209

SN - 0168-9002

VL - 1080

JO - Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

JF - Nuclear Instruments and Methods in Physics Research, Section A: Accelerators, Spectrometers, Detectors and Associated Equipment

M1 - 170659

ER -

Object detection with deep learning for rare event search in the GADGET II TPC

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