Interpreting Stellar Spectra with Unsupervised Domain Adaptation
Abstract
We discuss how to achieve mapping from large sets of imperfect simulations and observational data with unsupervised domain adaptation. Under the hypothesis that simulated and observed data distributions share a common underlying representation, we show how it is possible to transfer between simulated and observed domains. Driven by an application to interpret stellar spectroscopic sky surveys, we construct the domain transfer pipeline from two adversarial autoencoders on each domains with a disentangling latent space, and a cycle-consistency constraint. We then construct a differentiable pipeline from physical stellar parameters to realistic observed spectra, aided by a supplementary generative surrogate physics emulator network. We further exemplify the potential of the method on the reconstructed spectra quality and to discover new spectral features associated to elemental abundances.
Cite
@article{arxiv.2007.03112,
title = {Interpreting Stellar Spectra with Unsupervised Domain Adaptation},
author = {Teaghan O'Briain and Yuan-Sen Ting and Sébastien Fabbro and Kwang M. Yi and Kim Venn and Spencer Bialek},
journal= {arXiv preprint arXiv:2007.03112},
year = {2020}
}
Comments
4 pages, 4 figure, accepted to the ICML 2020 Machine Learning Interpretability for Scientific Discovery workshop. A full 20-page version is submitted to ApJ. The code used in this study is made publicly available on github: https://github.com/teaghan/Cycle_SN