# Analytic marginalization of absorption line continua

**Authors:** Kirill Tchernyshyov

arXiv: 1901.06416 · 2020-01-29

## TL;DR

This paper introduces an analytic method for marginalizing over continuum parameters in absorption line spectroscopy, enabling faster, more accurate, and automated analysis of large datasets compared to traditional numerical methods.

## Contribution

It develops a closed-form analytic marginalization technique for linear continuum models, improving speed and accuracy in automated spectral analysis.

## Key findings

- Analytic marginalization speeds up spectral analysis.
- Improves accuracy of absorption line parameter recovery.
- Facilitates automated continuum placement in large datasets.

## Abstract

Absorption line spectroscopy is a powerful way of measuring properties of stars and the interstellar medium. Absorption spectra are often analyzed manually, an approach that limits reproducibility and which cannot practically be applied to modern datasets consisting of thousands or even millions of spectra. Simultaneous probabilistic modeling of absorption features and continuum shape is a promising approach for automating this analysis. Existing implementations of this approach use numerical methods such as Markov chain Monte Carlo (MCMC) to marginalize over the continuum parameters. Numerical marginalization over large numbers of continuum parameters is too slow to be convenient for exploratory analysis, can increase the dimensionality of an inference problem beyond the capacity of simple MCMC samplers, and is in general impractical for the analysis of large datasets. When continua are parameterized as linear functions such as polynomials or splines, it is possible to reduce continuum parameter marginalization to an integral over a multivariate normal distribution, which has a known closed form. In addition to speeding up probabilistic modeling, analytic marginalization makes it trivial to marginalize over continuum parameterizations and to combine continuum description marginalization with optimization for absorption line parameters. These new possibilities allow automatic, probabilistically justified continuum placement in analyses of large spectroscopic datasets. We compare the accuracy to within which absorption line parameters can be recovered using different continuum placement methods and find that marginalization is in many cases an improvement over other methods. We implement analytic marginalization over linear continuum parameters in the open-source package amlc.

## Full text

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## Figures

7 figures with captions in the complete paper: https://tomesphere.com/paper/1901.06416/full.md

## References

15 references — full list in the complete paper: https://tomesphere.com/paper/1901.06416/full.md

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Source: https://tomesphere.com/paper/1901.06416