Enhancing Event Reconstruction in Hyper-Kamiokande with Machine Learning: A ResNet Implementation

Abstract

The forthcoming Hyper-Kamiokande experiment requires substantially larger Monte Carlo datasets than previous experiments to satisfy stringent systematic-uncertainty requirements. While traditional maximum-likelihood reconstruction provides high-quality results, its per-event computational cost makes processing these large samples increasingly impractical. We demonstrate a neural-network-based reconstruction approach for the Hyper-Kamiokande far detector using simulated data. Single-particle events with kinetic energies from the Cherenkov threshold up to 2 GeV are propagated through the detector, with PMT charge and timing information mapped to 190×189 two-channel images serving as inputs to ResNet models in the WatChMaL framework. These models (i) classify events into four particle hypotheses (e, μ, γ, π0) and (ii) regress the vertex, direction, and momentum of electrons and muons. Averaged over the full kinematic range, the regression models achieve momentum resolutions of 1.35\% and 2.39\%, angular resolutions of 1.25 and 1.94, and vertex resolutions of 28.2 cm and 25.4 cm, for muons and electrons respectively, broadly consistent with traditional methods. The classifier improves e-μ, e-γ, and e-π0 separation, with ROC curve areas of 0.9999992, 0.633, and 0.9526. Crucially, our networks achieve inference times of 1-2 ms per event on a single GPU, yielding speed-ups of 3.2×104-5.2×104 relative to likelihood-based reconstruction, highlighting deep learning as a scalable alternative for Hyper-Kamiokande event reconstruction.