Universal Spectral Tokenization via Self-Supervised Panchromatic Representation Learning
Abstract
Sequential scientific data span many resolutions and domains, and unifying them into a common representation is a key step toward developing foundation models for the sciences. Astronomical spectra exemplify this challenge: massive surveys have collected millions of spectra across a wide range of wavelengths and resolutions, yet analyses remain fragmented across spectral domains (e.g., optical vs. infrared) and object types (e.g., stars vs. galaxies), limiting the ability to pool information across datasets. We present a deep learning model that jointly learns from heterogeneous spectra in a self-supervised manner. Our universal spectral tokenizer processes spectra from a variety of object types and resolutions directly on their native wavelength grids, producing intrinsically aligned, homogeneous, and physically meaningful representations that can be efficiently adapted to achieve competitive performance across a range of downstream tasks. For the first time, we demonstrate that a single model can unify spectral data across resolutions and domains, suggesting that our model can serve as a powerful building block for foundation models in astronomy -- and potentially extend to other scientific domains with heterogeneous sequential data, such as climate and healthcare.
Cite
@article{arxiv.2510.17959,
title = {Universal Spectral Tokenization via Self-Supervised Panchromatic Representation Learning},
author = {Jeff Shen and Francois Lanusse and Liam Holden Parker and Ollie Liu and Tom Hehir and Leopoldo Sarra and Lucas Meyer and Micah Bowles and Sebastian Wagner-Carena and Sebastian Wagner-Carena and Helen Qu and Siavash Golkar and Alberto Bietti and Hatim Bourfoune and Nathan Cassereau and Pierre Cornette and Keiya Hirashima and Geraud Krawezik and Ruben Ohana and Nicholas Lourie and Michael McCabe and Rudy Morel and Payel Mukhopadhyay and Mariel Pettee and Bruno Régaldo-Saint Blancard and Kyunghyun Cho and Miles Cranmer and Shirley Ho},
journal= {arXiv preprint arXiv:2510.17959},
year = {2025}
}
Comments
Accepted at NeurIPS 2025 Machine Learning and the Physical Sciences Workshop; v2: added collaboration