<p>Precise modeling of detector energy response is crucial for next-generation neutrino experiments, which present computational challenges due to the lack of analytical likelihoods. We propose a solution using neural likelihood estimation within the simulation-based inference framework. We develop two complementary neural density estimators that model likelihoods of calibration data: conditional normalizing flows and a transformer-based regressor. We adopt JUNO — a large neutrino experiment — as a case study. The energy response of JUNO depends on several parameters, all of which should be tuned, given their non-linear behavior and strong correlations in the calibration data. To this end, we integrate the modeled likelihoods with Bayesian nested sampling for parameter inference, achieving uncertainties limited only by statistics with near-zero systematic biases. The normalizing flows model enables unbinned likelihood analysis, while the transformer provides an efficient binned alternative. By providing both options, our framework offers flexibility to choose the most appropriate method for specific needs. Finally, our approach establishes a template for similar applications across experimental neutrino and broader particle physics.</p><p></p>

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Simulation-based inference for precision neutrino physics through neural Monte Carlo tuning

  • Arsenii Gavrikov,
  • Andrea Serafini,
  • Dmitry Dolzhikov,
  • Alberto Garfagnini,
  • Maxim Gonchar,
  • Marco Grassi,
  • Giuseppe Andronico,
  • Vito Antonelli,
  • Andrea Barresi,
  • Davide Basilico,
  • Marco Beretta,
  • Antonio Bergnoli,
  • Matteo Borghesi,
  • Augusto Brigatti,
  • Riccardo Brugnera,
  • Riccardo Bruno,
  • Antonio Budano,
  • Barbara Caccianiga,
  • Antonio Cammi,
  • Rossella Caruso,
  • Vanessa Cerrone,
  • Davide Chiesa,
  • Catia Clementi,
  • Claudio Coletta,
  • Lorenzo V. D’Auria,
  • Stefano Dusini,
  • Andrea Fabbri,
  • Elia S. Farilla,
  • Giulietto Felici,
  • Giovanni Ferrante,
  • Marco G. Giammarchi,
  • Nunzio Giudice,
  • Nunzio Guardone,
  • Rosa Maria Guizzetti,
  • Fatima Houria,
  • Cecilia Landini,
  • Lorenzo Lastrucci,
  • Ivano Lippi,
  • Lorenzo Loi,
  • Paolo Lombardi,
  • Fabio Mantovani,
  • Stefano M. Mari,
  • Agnese Martini,
  • Lino Miramonti,
  • Michele Montuschi,
  • Massimiliano Nastasi,
  • Domizia Orestano,
  • Fausto Ortica,
  • Alessandro Paoloni,
  • Luca Pelicci,
  • Elisa Percalli,
  • Fabrizio Petrucci,
  • Ezio Previtali,
  • Gioacchino Ranucci,
  • Alessandra C. Re,
  • Barbara Ricci,
  • Aldo Romani,
  • Chiara Sirignano,
  • Monica Sisti,
  • Luca Stanco,
  • Virginia Strati,
  • Marco D. C. Torri,
  • Cristina Tuvè,
  • Carlo Venettacci,
  • Giuseppe Verde,
  • Lucia Votano

摘要

Precise modeling of detector energy response is crucial for next-generation neutrino experiments, which present computational challenges due to the lack of analytical likelihoods. We propose a solution using neural likelihood estimation within the simulation-based inference framework. We develop two complementary neural density estimators that model likelihoods of calibration data: conditional normalizing flows and a transformer-based regressor. We adopt JUNO — a large neutrino experiment — as a case study. The energy response of JUNO depends on several parameters, all of which should be tuned, given their non-linear behavior and strong correlations in the calibration data. To this end, we integrate the modeled likelihoods with Bayesian nested sampling for parameter inference, achieving uncertainties limited only by statistics with near-zero systematic biases. The normalizing flows model enables unbinned likelihood analysis, while the transformer provides an efficient binned alternative. By providing both options, our framework offers flexibility to choose the most appropriate method for specific needs. Finally, our approach establishes a template for similar applications across experimental neutrino and broader particle physics.