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Auteurs principaux: Marinho, Eraldo Pereira, Junior, Nelson Callegari, Breve, Fabricio Aparecido, Ranieri, Caetano Mazzoni
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2603.13177
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author Marinho, Eraldo Pereira
Junior, Nelson Callegari
Breve, Fabricio Aparecido
Ranieri, Caetano Mazzoni
author_facet Marinho, Eraldo Pereira
Junior, Nelson Callegari
Breve, Fabricio Aparecido
Ranieri, Caetano Mazzoni
contents The dynamics of Saturn's satellite system offer a rich framework for studying orbital stability and resonance interactions. Traditional methods for analysing such systems, including Fourier analysis and stability metrics, struggle with the scale and complexity of modern datasets. This study introduces a machine learning-based pipeline for clustering approximately 22,300 simulated satellite orbits, addressing these challenges with advanced feature extraction and dimensionality reduction techniques. The key to this approach is using MiniRocket, which efficiently transforms 400 timesteps into a 9,996-dimensional feature space, capturing intricate temporal patterns. Additional automated feature extraction and dimensionality reduction techniques refine the data, enabling robust clustering analysis. This pipeline reveals stability regions, resonance structures, and other key behaviours in Saturn's satellite system, providing new insights into their long-term dynamical evolution. By integrating computational tools with traditional celestial mechanics techniques, this study offers a scalable and interpretable methodology for analysing large-scale orbital datasets and advancing the exploration of planetary dynamics.
format Preprint
id arxiv_https___arxiv_org_abs_2603_13177
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Clustering Astronomical Orbital Synthetic Data Using Advanced Feature Extraction and Dimensionality Reduction Techniques
Marinho, Eraldo Pereira
Junior, Nelson Callegari
Breve, Fabricio Aparecido
Ranieri, Caetano Mazzoni
Earth and Planetary Astrophysics
Instrumentation and Methods for Astrophysics
Artificial Intelligence
The dynamics of Saturn's satellite system offer a rich framework for studying orbital stability and resonance interactions. Traditional methods for analysing such systems, including Fourier analysis and stability metrics, struggle with the scale and complexity of modern datasets. This study introduces a machine learning-based pipeline for clustering approximately 22,300 simulated satellite orbits, addressing these challenges with advanced feature extraction and dimensionality reduction techniques. The key to this approach is using MiniRocket, which efficiently transforms 400 timesteps into a 9,996-dimensional feature space, capturing intricate temporal patterns. Additional automated feature extraction and dimensionality reduction techniques refine the data, enabling robust clustering analysis. This pipeline reveals stability regions, resonance structures, and other key behaviours in Saturn's satellite system, providing new insights into their long-term dynamical evolution. By integrating computational tools with traditional celestial mechanics techniques, this study offers a scalable and interpretable methodology for analysing large-scale orbital datasets and advancing the exploration of planetary dynamics.
title Clustering Astronomical Orbital Synthetic Data Using Advanced Feature Extraction and Dimensionality Reduction Techniques
topic Earth and Planetary Astrophysics
Instrumentation and Methods for Astrophysics
Artificial Intelligence
url https://arxiv.org/abs/2603.13177