Geometry-aware Autoregressive Models for Calorimeter Shower Simulations
Instrumentation and Detectors2022-12-19v1Machine LearningHigh Energy Physics - ExperimentHigh Energy Physics - PhenomenologyData Analysis, Statistics and Probability
Calorimeter shower simulations are often the bottleneck in simulation time for particle physics detectors. A lot of effort is currently spent on optimizing generative architectures for specific detector geometries, which generalize poorly. We develop a geometry-aware autoregressive model on a range of calorimeter geometries such that the model learns to adapt its energy deposition depending on the size and position of the cells. This is a key proof-of-concept step towards building a model that can generalize to new unseen calorimeter geometries with little to no additional training. Such a model can replace the hundreds of generative models used for calorimeter simulation in a Large Hadron Collider experiment. For the study of future detectors, such a model will dramatically reduce the large upfront investment usually needed to generate simulations.
@article{arxiv.2212.08233,
title = {Geometry-aware Autoregressive Models for Calorimeter Shower Simulations},
author = {Junze Liu and Aishik Ghosh and Dylan Smith and Pierre Baldi and Daniel Whiteson},
journal= {arXiv preprint arXiv:2212.08233},
year = {2022}
}
Comments
This paper was submitted to NeurIPS Machine Learning and the Physical Sciences Workshop 2022