Reducing model bias in a deep learning classifier using domain adversarial neural networks in the MINERvA experiment

G.N. Perdue; A. Ghosh; M. Wospakrik; F. Akbar; D.A. Andrade; M. Ascencio; L. Bellantoni; A. Bercellie; M. Betancourt; G. F. R. Caceres Vera; T. Cai; M.F. Carneiro; J. Chaves; D. Coplowe; H. da Motta; G.A. Díaz; J. Felix; L. Fields; R. Fine; A. M. Gago; R. Galindo; T. Golan; R. Gran; J. Y. Han; D. A. Harris; D. Jena; J. Kleykamp; M. Kordosky; X.-G. Lu; E. Maher; W. A. Mann; C. M. Marshall; K.S. McFarland; A. M. McGowan; B. Messerly; J. Miller; J. K. Nelson; C. Nguyen; A. Norrick; Nuruzzaman Nuruzzaman; A. Olivier; R. Patton; M.A. Ramírez; R. D. Ransome; H. Ray; L. Ren; D. Rimal; D. Ruterbories; H. Schellman; C. J. Solano Salinas; H. Su; S. Upadhyay; E. Valencia; J. Wolcott; B. Yaeggy; S. Young

doi:10.1088/1748-0221/13/11/P11020

Journal of Instrumentation

Reducing model bias in a deep learning classifier using domain adversarial neural networks in the MINERvA experiment

G.N. Perdue^1,2, A. Ghosh^3,4, M. Wospakrik⁵, F. Akbar⁶, D.A. Andrade⁷, M. Ascencio⁸, L. Bellantoni¹, A. Bercellie², M. Betancourt¹, G. F. R. Caceres Vera⁴, T. Cai², M.F. Carneiro⁹, J. Chaves¹⁰, D. Coplowe¹¹, H. da Motta⁴, G.A. Díaz^2,8, J. Felix⁷, L. Fields^1,12, R. Fine², A. M. Gago⁸, R. Galindo³, T. Golan^2,13, R. Gran¹⁴, J. Y. Han¹⁵, D. A. Harris¹, D. Jena¹, J. Kleykamp², M. Kordosky¹⁶, X.-G. Lu¹¹, E. Maher¹⁷, W. A. Mann¹⁸, C. M. Marshall², K.S. McFarland^1,2, A. M. McGowan², B. Messerly¹⁵, J. Miller³, J. K. Nelson¹⁶, C. Nguyen⁵, A. Norrick¹⁶, Nuruzzaman Nuruzzaman^3,19, A. Olivier², R. Patton²⁰, M.A. Ramírez⁷, R. D. Ransome¹⁹, H. Ray⁵, L. Ren¹⁵, D. Rimal⁵, D. Ruterbories², H. Schellman^9,12, C. J. Solano Salinas²¹, H. Su¹⁵, S. Upadhyay²², E. Valencia^7,16, J. Wolcott², B. Yaeggy³ and S. Young²⁰

Published 26 November 2018 • © 2018 IOP Publishing Ltd and Sissa Medialab
Journal of Instrumentation, Volume 13, November 2018 Citation G.N. Perdue et al 2018 JINST 13 P11020 DOI 10.1088/1748-0221/13/11/P11020

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¹ Fermi National Accelerator Laboratory, Batavia, Illinois 60510, U.S.A.

² University of Rochester, Rochester, New York 14627 U.S.A.

³ Departamento de Física, Universidad Técnica Federico Santa María, Avenida España 1680 Casilla 110-V, Valparaíso, Chile

⁴ Centro Brasileiro de Pesquisas Físicas, Rua Dr. Xavier Sigaud 150, Urca, Rio de Janeiro, Rio de Janeiro, 22290-180, Brazil

⁵ University of Florida, Department of Physics, Gainesville, FL 32611

⁶ AMU Campus, Aligarh, Uttar Pradesh 202001, India

⁷ Campus León y Campus Guanajuato, Universidad de Guanajuato, Lascurain de Retana No. 5, Colonia Centro, Guanajuato 36000, Guanajuato México.

⁸ Sección Física, Departamento de Ciencias, Pontificia Universidad Católica del Perú, Apartado 1761, Lima, Perú

⁹ Department of Physics, Oregon State University, Corvallis, Oregon 97331, U.S.A.

¹⁰ Department of Physics and Astronomy, University of Pennsylvania, Philadelphia, PA 19104

¹¹ Department of Physics, University of Oxford, Oxford OX1 3PU, U.K.

¹² Northwestern University, Evanston, Illinois 60208

¹³ University of Wroclaw, plac Uniwersytecki 1, 50-137 Wrocław, Poland

¹⁴ Department of Physics, University of Minnesota-Duluth, Duluth, Minnesota 55812, U.S.A.

¹⁵ Department of Physics and Astronomy, University of Pittsburgh, Pittsburgh, Pennsylvania 15260, U.S.A.

¹⁶ Department of Physics, College of William & Mary, Williamsburg, Virginia 23187, U.S.A.

¹⁷ Massachusetts College of Liberal Arts, 375 Church Street, North Adams, MA 01247

¹⁸ Physics Department, Tufts University, Medford, Massachusetts 02155, U.S.A.

¹⁹ Rutgers, The State University of New Jersey, Piscataway, New Jersey 08854, U.S.A.

²⁰ Oak Ridge National Laboratory, Oak Ridge, Tennessee 37831, U.S.A.

²¹ Universidad Nacional de Ingeniería, Apartado 31139, Lima, Perú

²² University of Chicago, Department of Statistics, Chicago, Illinois 60637, U.S.A.

Dates

Received 30 August 2018
Accepted 8 November 2018
Published 26 November 2018

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Abstract

We present a simulation-based study using deep convolutional neural networks (DCNNs) to identify neutrino interaction vertices in the MINERvA passive targets region, and illustrate the application of domain adversarial neural networks (DANNs) in this context. DANNs are designed to be trained in one domain (simulated data) but tested in a second domain (physics data) and utilize unlabeled data from the second domain so that during training only features which are unable to discriminate between the domains are promoted. MINERvA is a neutrino-nucleus scattering experiment using the NuMI beamline at Fermilab. A-dependent cross sections are an important part of the physics program, and these measurements require vertex finding in complicated events. To illustrate the impact of the DANN we used a modified set of simulation in place of physics data during the training of the DANN and then used the label of the modified simulation during the evaluation of the DANN. We find that deep learning based methods offer significant advantages over our prior track-based reconstruction for the task of vertex finding, and that DANNs are able to improve the performance of deep networks by leveraging available unlabeled data and by mitigating network performance degradation rooted in biases in the physics models used for training.

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