Point Proposal Network for Reconstructing 3D Particle Positions with Sub-Pixel Precision in Liquid Argon Time Projection Chambers.

Liquid Argon Time Projection Chambers (LArTPC) are particle imaging detectors recording 2D or 3D images of numerous complex trajectories of charged particles. Identifying points of interest in these images, such as the starting and ending points of particles trajectories, is a crucial step of identifying and analyzing these particles and impacts inference of physics signals such as neutrino interaction. The Point Proposal Network is designed to discover specific points of interest, namely the starting and ending points of track-like particle trajectories such as muons and protons, and the starting points of electromagnetic shower-like particle trajectories such as electrons and gamma rays. The algorithm predicts with a sub-voxel precision their spatial location, and also determines the category of the identified points of interest. Using the PILArNet public LArTPC data sample as a benchmark, our algorithm successfully predicted 96.8%, 97.8%, and 98.1% of 3D points within the voxel distance of 3, 10, and 20 from the provided true point locations respectively. For the predicted 3D points within 3 voxels of the closest true point locations, the median distance is found to be 0.25 voxels, achieving the sub-voxel level precision. We report that the majority of predicted points that are more than 10 voxels away from the closest true point locations are legitimate mistakes, and our algorithm achieved high enough accuracy to identify issues associated with a small fraction of true point locations provided in the dataset. Further, using those predicted points, we demonstrate a set of simple algorithms to cluster 3D voxels into individual track-like particle trajectories at the clustering efficiency, purity, and Adjusted Rand Index of 83.2%, 96.7%, and 94.7% respectively.