Saved in:
Bibliographic Details
Main Authors: Frediani, Nikolas, Krämer, Michael, Mertsch, Philipp, Nippel, Kathrin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.06011
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916884579876864
author Frediani, Nikolas
Krämer, Michael
Mertsch, Philipp
Nippel, Kathrin
author_facet Frediani, Nikolas
Krämer, Michael
Mertsch, Philipp
Nippel, Kathrin
contents The spectrum of cosmic-ray electrons depends sensitively on the history and spatial distribution of nearby sources. Given our limited observational handle on cosmic-ray sources, any model remains necessarily probabilistic. Previously, predictions were performed in a Monte Carlo fashion, summing the contributions from individual, simulated sources to generate samples from the statistical ensemble of possible electron spectra. Such simulations need to be re-run if the cosmic-ray transport parameters (e.g. diffusion coefficient, maximum energy) are changed, rendering any parameter study computationally expensive. In addition, a proper statistical analysis of observations and comparison with such probabilistic models requires the joint probability distribution of the full spectrum instead of only samples. Note that parametrising this joint distribution is rendered difficult by the non-Gaussian statistics of the cosmic-ray fluxes. Here, we employ machine learning to compute the joint probability distribution of cosmic-ray electron fluxes. Specifically, we employ masked autoregressive density estimation (MADE) for a representation of the high-dimensional joint probability distribution. In a first step, we train the network on a Monte Carlo simulation for a fixed set of transport parameters, thus significantly accelerating the generation of samples. In a second step, we extend this setup to SECRET (Stochasticity Emulator for Cosmic Ray Electrons), allowing to reliably interpolate over the space of transport parameters. We make the MADE and SECRET codes available at https://git.rwth-aachen.de/pmertsch/secret .
format Preprint
id arxiv_https___arxiv_org_abs_2501_06011
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle SECRET: Stochasticity Emulator for Cosmic Ray Electrons
Frediani, Nikolas
Krämer, Michael
Mertsch, Philipp
Nippel, Kathrin
High Energy Astrophysical Phenomena
Astrophysics of Galaxies
Computational Physics
The spectrum of cosmic-ray electrons depends sensitively on the history and spatial distribution of nearby sources. Given our limited observational handle on cosmic-ray sources, any model remains necessarily probabilistic. Previously, predictions were performed in a Monte Carlo fashion, summing the contributions from individual, simulated sources to generate samples from the statistical ensemble of possible electron spectra. Such simulations need to be re-run if the cosmic-ray transport parameters (e.g. diffusion coefficient, maximum energy) are changed, rendering any parameter study computationally expensive. In addition, a proper statistical analysis of observations and comparison with such probabilistic models requires the joint probability distribution of the full spectrum instead of only samples. Note that parametrising this joint distribution is rendered difficult by the non-Gaussian statistics of the cosmic-ray fluxes. Here, we employ machine learning to compute the joint probability distribution of cosmic-ray electron fluxes. Specifically, we employ masked autoregressive density estimation (MADE) for a representation of the high-dimensional joint probability distribution. In a first step, we train the network on a Monte Carlo simulation for a fixed set of transport parameters, thus significantly accelerating the generation of samples. In a second step, we extend this setup to SECRET (Stochasticity Emulator for Cosmic Ray Electrons), allowing to reliably interpolate over the space of transport parameters. We make the MADE and SECRET codes available at https://git.rwth-aachen.de/pmertsch/secret .
title SECRET: Stochasticity Emulator for Cosmic Ray Electrons
topic High Energy Astrophysical Phenomena
Astrophysics of Galaxies
Computational Physics
url https://arxiv.org/abs/2501.06011