Abstract
The precise simulation of particle transport through detectors remains a key element for the successful interpretation of high energy physics results. However, Monte Carlo based simulation is extremely demanding in terms of computing resources. This challenge motivates investigations of faster, alternative approaches for replacing the standard Monte Carlo technique.We apply Generative Adversarial Networks (GANs), a deep learning technique, to replace the calorimeter detector simulations and speeding up the simulation time by orders of magnitude. We follow a previous approach which used three-dimensional convolutional neural networks and develop new two-dimensional convolutional networks to solve the same 3D image generation problem faster. Additionally, we increased the number of parameters and the neural networks representational power, obtaining a higher accuracy. We compare our best convolutional 2D neural network architecture and evaluate it versus the previous 3D architecture and Geant4 data. Our results demonstrate a high physics accuracy and further consolidate the use of GANs for fast detector simulations.
Highlights
Accurate Simulations of elementary particles in High Energy Physics (HEP) detectors are fundamental to correctly reproduce and interpret the experimental results
Detector simulations rely on Monte Carlo-based methods, such as implemented in the Geant4 toolkit [1] which suffer from high computational costs: currently more than half of the Worldwide Large Hadron Collider (LHC) Grid resources are used for the generation and processing of simulated data [2]
The operational requirements related to the future High Luminosity phase of the LHC will exceed the expected available computational resources drastically even if taking technological improvements into account [3]
Summary
Accurate Simulations of elementary particles in High Energy Physics (HEP) detectors are fundamental to correctly reproduce and interpret the experimental results. Detector simulations rely on Monte Carlo-based methods, such as implemented in the Geant toolkit [1] which suffer from high computational costs: currently more than half of the Worldwide Large Hadron Collider (LHC) Grid resources are used for the generation and processing of simulated data [2]. Generative Adversarial Networks (GANs) represent one promising alternative approach which have been employed primarily for simulating calorimeter detectors [9]. In this paper we introduce three novel GAN architectures which use Convolutional Neural Networks. In the end we select the best among our new Conv2D architectures and make a detailed physics comparison to the baseline Conv3D model and to Geant data.
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