The entropy of galaxy spectra: How much information is encoded?

TL;DR

This study applies information theory to galaxy spectra, revealing their high entropy and low information content, and demonstrates how entropy analysis can distinguish galaxy types and improve population models.

Contribution

The paper introduces an entropy-based framework for analyzing galaxy spectra, highlighting its potential to enhance population synthesis and classification methods.

Findings

Galaxy spectra have high entropy, indicating low effective information content.

Entropy variation is highest in well-studied spectral regions, especially the 4000A break.

Entropy-based analysis can classify galaxy types and reveal spectral transitions.

Abstract

The inverse problem of extracting the stellar population content of galaxy spectra is analysed here from a basic standpoint based on information theory. By interpreting spectra as probability distribution functions, we find that galaxy spectra have high entropy, thus leading to a rather low effective information content. The highest variation in entropy is unsurprisingly found in regions that have been well studied for decades with the conventional approach. We target a set of six spectral regions that show the highest variation in entropy - the 4000A break being the most informative one. As a test case with real data, we measure the entropy of a set of high quality spectra from the Sloan Digital Sky Survey, and contrast entropy-based results with the traditional method based on line strengths. The data are classified into star-forming (SF), quiescent (Q) and AGN galaxies, and show, independently of any physical model, that AGN spectra can be interpreted as a transition between SF and Q galaxies, with SF galaxies featuring a more diverse variation in entropy. The high level of entanglement complicates the determination of population parameters in a robust, unbiased way, and affect traditional methods that compare models with observations, as well as machine learning (especially deep learning) algorithms that rely on the statistical properties of the data to assess the variations among spectra. Entropy provides a new avenue to improve population synthesis models so that they give a more faithful representation of real galaxy spectra.