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| Format: | Preprint |
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2025
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| Online-Zugang: | https://arxiv.org/abs/2503.21584 |
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| _version_ | 1866917969161879552 |
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| author | Canducci, Marco Awad, Petra Taghribi, Abolfazl Mohammadi, Mohammad Mastropietro, Michele De Rijcke, Sven Peletier, Reynier Smith, Rory Bunte, Kerstin Tino, Peter |
| author_facet | Canducci, Marco Awad, Petra Taghribi, Abolfazl Mohammadi, Mohammad Mastropietro, Michele De Rijcke, Sven Peletier, Reynier Smith, Rory Bunte, Kerstin Tino, Peter |
| contents | Filaments are ubiquitous in astronomical data sets. Be it in particle simulations or observations, filaments are always tracers of a perturbation in the equilibrium of the studied system and hold essential information on its history and future evolution. However, the recovery of such structures is often complicated by the presence of a large amount of background and transverse noise in the observation space. While the former is generally detrimental to the analysis, the latter can be attributed to measurement errors and it can hold essential information about the structure. To further complicate the scenario, 1D manifolds (filaments) are generally non-linear and their geometry difficult to extract and model. In order to study hidden manifolds within the dataset, particular care has to be devoted to background noise removal and transverse noise modelling, while still maintaining accuracy in the recovery of their geometrical structure. We propose 1-DREAM: a toolbox composed of five main Machine Learning methodologies whose aim is to facilitate manifold extraction in such cases. Each methodology has been designed to address issues when dealing with complicated low-dimensional structures convoluted with noise and it has been extensively tested in previously published works. In this work all methodologies are presented in detail, joint within a cohesive framework and demonstrated for three interesting astronomical cases: a simulated jellyfish galaxy, a filament extracted from a simulated cosmic web and the stellar stream of Omega-Centauri as observed with the GAIA DR2. Two newly developed visualization techniques are also proposed, that take full advantage of the results obtained with 1-DREAM. The code is made publicly available to benefit the community. The controlled experiments on a purposefully built data set prove the accuracy of the pipeline in recovering the hidden structures. |
| format | Preprint |
| id |
arxiv_https___arxiv_org_abs_2503_21584 |
| institution | arXiv |
| publishDate | 2025 |
| record_format | arxiv |
| spellingShingle | 1-DREAM: 1D Recovery, Extraction and Analysis of Manifolds in noisy environments Canducci, Marco Awad, Petra Taghribi, Abolfazl Mohammadi, Mohammad Mastropietro, Michele De Rijcke, Sven Peletier, Reynier Smith, Rory Bunte, Kerstin Tino, Peter Instrumentation and Methods for Astrophysics G.3; I.2; I.5; J.2 Filaments are ubiquitous in astronomical data sets. Be it in particle simulations or observations, filaments are always tracers of a perturbation in the equilibrium of the studied system and hold essential information on its history and future evolution. However, the recovery of such structures is often complicated by the presence of a large amount of background and transverse noise in the observation space. While the former is generally detrimental to the analysis, the latter can be attributed to measurement errors and it can hold essential information about the structure. To further complicate the scenario, 1D manifolds (filaments) are generally non-linear and their geometry difficult to extract and model. In order to study hidden manifolds within the dataset, particular care has to be devoted to background noise removal and transverse noise modelling, while still maintaining accuracy in the recovery of their geometrical structure. We propose 1-DREAM: a toolbox composed of five main Machine Learning methodologies whose aim is to facilitate manifold extraction in such cases. Each methodology has been designed to address issues when dealing with complicated low-dimensional structures convoluted with noise and it has been extensively tested in previously published works. In this work all methodologies are presented in detail, joint within a cohesive framework and demonstrated for three interesting astronomical cases: a simulated jellyfish galaxy, a filament extracted from a simulated cosmic web and the stellar stream of Omega-Centauri as observed with the GAIA DR2. Two newly developed visualization techniques are also proposed, that take full advantage of the results obtained with 1-DREAM. The code is made publicly available to benefit the community. The controlled experiments on a purposefully built data set prove the accuracy of the pipeline in recovering the hidden structures. |
| title | 1-DREAM: 1D Recovery, Extraction and Analysis of Manifolds in noisy environments |
| topic | Instrumentation and Methods for Astrophysics G.3; I.2; I.5; J.2 |
| url | https://arxiv.org/abs/2503.21584 |