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Main Authors: Polsterer, Kai L., Doser, Bernd, Fehlner, Andreas, Trujillo-Gomez, Sebastian
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2406.03810
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author Polsterer, Kai L.
Doser, Bernd
Fehlner, Andreas
Trujillo-Gomez, Sebastian
author_facet Polsterer, Kai L.
Doser, Bernd
Fehlner, Andreas
Trujillo-Gomez, Sebastian
contents Simulations are the best approximation to experimental laboratories in astrophysics and cosmology. However, the complexity, richness, and large size of their outputs severely limit the interpretability of their predictions. We describe a new, unbiased, and machine learning based approach to obtaining useful scientific insights from a broad range of simulations. The method can be used on today's largest simulations and will be essential to solve the extreme data exploration and analysis challenges posed by the Exascale era. Furthermore, this concept is so flexible, that it will also enable explorative access to observed data. Our concept is based on applying nonlinear dimensionality reduction to learn compact representations of the data in a low-dimensional space. The simulation data is projected onto this space for interactive inspection, visual interpretation, sample selection, and local analysis. We present a prototype using a rotational invariant hyperspherical variational convolutional autoencoder, utilizing a power distribution in the latent space, and trained on galaxies from IllustrisTNG simulation. Thereby, we obtain a natural Hubble tuning fork like similarity space that can be visualized interactively on the surface of a sphere by exploiting the power of HiPS tilings in Aladin Lite.
format Preprint
id arxiv_https___arxiv_org_abs_2406_03810
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Spherinator and HiPSter: Representation Learning for Unbiased Knowledge Discovery from Simulations
Polsterer, Kai L.
Doser, Bernd
Fehlner, Andreas
Trujillo-Gomez, Sebastian
Instrumentation and Methods for Astrophysics
Machine Learning
Simulations are the best approximation to experimental laboratories in astrophysics and cosmology. However, the complexity, richness, and large size of their outputs severely limit the interpretability of their predictions. We describe a new, unbiased, and machine learning based approach to obtaining useful scientific insights from a broad range of simulations. The method can be used on today's largest simulations and will be essential to solve the extreme data exploration and analysis challenges posed by the Exascale era. Furthermore, this concept is so flexible, that it will also enable explorative access to observed data. Our concept is based on applying nonlinear dimensionality reduction to learn compact representations of the data in a low-dimensional space. The simulation data is projected onto this space for interactive inspection, visual interpretation, sample selection, and local analysis. We present a prototype using a rotational invariant hyperspherical variational convolutional autoencoder, utilizing a power distribution in the latent space, and trained on galaxies from IllustrisTNG simulation. Thereby, we obtain a natural Hubble tuning fork like similarity space that can be visualized interactively on the surface of a sphere by exploiting the power of HiPS tilings in Aladin Lite.
title Spherinator and HiPSter: Representation Learning for Unbiased Knowledge Discovery from Simulations
topic Instrumentation and Methods for Astrophysics
Machine Learning
url https://arxiv.org/abs/2406.03810