GPU-Accelerated Analytic Simulation of Sparse Signals in Pixelated Time Projection Detector

Abstract

This paper presents a GPU-accelerated simulation package, TRED, for next-generation neutrino detectors with pixelated charge readout, leveraging community-driven software ecosystems to ensure sustainability and extensibility. We introduce two generic contributions: (i) an effective-charge calculation based on Gaussian quadrature rules for numerical integration, and (ii) a sparse, block-binned tensor representation that enables efficient FFT-based computation of induced signals on readout electrodes for sparsely activated detector volumes. The former captures sub-grid structure without requiring dense sampling, while the latter achieves low memory usage and scalable runtime, as demonstrated in benchmark studies. The underlying data representation is applicable to large-scale detectors and to other computational problems involving sparse activity.