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Main Authors: Scolati, Haley N., Loomis, Ryan A., Remijan, Anthony J., Lee, Kin Long Kelvin
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.15615
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author Scolati, Haley N.
Loomis, Ryan A.
Remijan, Anthony J.
Lee, Kin Long Kelvin
author_facet Scolati, Haley N.
Loomis, Ryan A.
Remijan, Anthony J.
Lee, Kin Long Kelvin
contents High-dimensional astronomical data cubes provide a wealth of spectral and structural information that can be used to study astrophysical and chemical processes. The complexity and sheer size of these datasets pose significant challenges in their efficient analysis, visualization, and interpretation. In specific astronomical use cases, a number of dimensionality reduction techniques, including traditional linear (e.g. principal component analysis) and modern nonlinear methods (e.g. convolutional autoencoders) have been used to tackle this high-dimensional problem. In this study, we assess the strengths, weaknesses, and nuances of various methods in their ability to capture and preserve astronomically-relevant features at lower dimensions. We provide recommendations to guide users in identifying and incorporating these treatments to their data, and provide insights into the computational scalability of these methods for observatory level data processing. This benchmark study uses publicly available archival ALMA data from a diverse sampling of source morphologies and observing setups to assess the performance and trade-offs between computational cost, image reconstruction accuracy, and scalability. Finally, we discuss the generalizability of these techniques in regard to data segmentation and labeling algorithms and how they can be exploited for advanced data product generation and streamlined archival analysis as we prepare to enter the era of the ALMA Wideband Sensitivity Upgrade.
format Preprint
id arxiv_https___arxiv_org_abs_2512_15615
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Benchmarking Dimensionality Reduction Methods for High-Dimensional ALMA Image Cubes
Scolati, Haley N.
Loomis, Ryan A.
Remijan, Anthony J.
Lee, Kin Long Kelvin
Instrumentation and Methods for Astrophysics
High-dimensional astronomical data cubes provide a wealth of spectral and structural information that can be used to study astrophysical and chemical processes. The complexity and sheer size of these datasets pose significant challenges in their efficient analysis, visualization, and interpretation. In specific astronomical use cases, a number of dimensionality reduction techniques, including traditional linear (e.g. principal component analysis) and modern nonlinear methods (e.g. convolutional autoencoders) have been used to tackle this high-dimensional problem. In this study, we assess the strengths, weaknesses, and nuances of various methods in their ability to capture and preserve astronomically-relevant features at lower dimensions. We provide recommendations to guide users in identifying and incorporating these treatments to their data, and provide insights into the computational scalability of these methods for observatory level data processing. This benchmark study uses publicly available archival ALMA data from a diverse sampling of source morphologies and observing setups to assess the performance and trade-offs between computational cost, image reconstruction accuracy, and scalability. Finally, we discuss the generalizability of these techniques in regard to data segmentation and labeling algorithms and how they can be exploited for advanced data product generation and streamlined archival analysis as we prepare to enter the era of the ALMA Wideband Sensitivity Upgrade.
title Benchmarking Dimensionality Reduction Methods for High-Dimensional ALMA Image Cubes
topic Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2512.15615