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Main Authors: Truong, Tuan, Sudharsan, Rithwik, Yang, Yibo, Ma, Peter Xiangyuan, Yang, Ruihan, Mandt, Stephan, Bloom, Joshua S.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2506.08306
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author Truong, Tuan
Sudharsan, Rithwik
Yang, Yibo
Ma, Peter Xiangyuan
Yang, Ruihan
Mandt, Stephan
Bloom, Joshua S.
author_facet Truong, Tuan
Sudharsan, Rithwik
Yang, Yibo
Ma, Peter Xiangyuan
Yang, Ruihan
Mandt, Stephan
Bloom, Joshua S.
contents The site conditions that make astronomical observatories in space and on the ground so desirable -- cold and dark -- demand a physical remoteness that leads to limited data transmission capabilities. Such transmission limitations directly bottleneck the amount of data acquired and in an era of costly modern observatories, any improvements in lossless data compression has the potential scale to billions of dollars worth of additional science that can be accomplished on the same instrument. Traditional lossless methods for compressing astrophysical data are manually designed. Neural data compression, on the other hand, holds the promise of learning compression algorithms end-to-end from data and outperforming classical techniques by leveraging the unique spatial, temporal, and wavelength structures of astronomical images. This paper introduces AstroCompress: a neural compression challenge for astrophysics data, featuring four new datasets (and one legacy dataset) with 16-bit unsigned integer imaging data in various modes: space-based, ground-based, multi-wavelength, and time-series imaging. We provide code to easily access the data and benchmark seven lossless compression methods (three neural and four non-neural, including all practical state-of-the-art algorithms). Our results on lossless compression indicate that lossless neural compression techniques can enhance data collection at observatories, and provide guidance on the adoption of neural compression in scientific applications. Though the scope of this paper is restricted to lossless compression, we also comment on the potential exploration of lossy compression methods in future studies.
format Preprint
id arxiv_https___arxiv_org_abs_2506_08306
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle AstroCompress: A benchmark dataset for multi-purpose compression of astronomical data
Truong, Tuan
Sudharsan, Rithwik
Yang, Yibo
Ma, Peter Xiangyuan
Yang, Ruihan
Mandt, Stephan
Bloom, Joshua S.
Artificial Intelligence
Instrumentation and Methods for Astrophysics
The site conditions that make astronomical observatories in space and on the ground so desirable -- cold and dark -- demand a physical remoteness that leads to limited data transmission capabilities. Such transmission limitations directly bottleneck the amount of data acquired and in an era of costly modern observatories, any improvements in lossless data compression has the potential scale to billions of dollars worth of additional science that can be accomplished on the same instrument. Traditional lossless methods for compressing astrophysical data are manually designed. Neural data compression, on the other hand, holds the promise of learning compression algorithms end-to-end from data and outperforming classical techniques by leveraging the unique spatial, temporal, and wavelength structures of astronomical images. This paper introduces AstroCompress: a neural compression challenge for astrophysics data, featuring four new datasets (and one legacy dataset) with 16-bit unsigned integer imaging data in various modes: space-based, ground-based, multi-wavelength, and time-series imaging. We provide code to easily access the data and benchmark seven lossless compression methods (three neural and four non-neural, including all practical state-of-the-art algorithms). Our results on lossless compression indicate that lossless neural compression techniques can enhance data collection at observatories, and provide guidance on the adoption of neural compression in scientific applications. Though the scope of this paper is restricted to lossless compression, we also comment on the potential exploration of lossy compression methods in future studies.
title AstroCompress: A benchmark dataset for multi-purpose compression of astronomical data
topic Artificial Intelligence
Instrumentation and Methods for Astrophysics
url https://arxiv.org/abs/2506.08306