A fast method for Stokes profile synthesis -- Radiative transfer modeling for ZDI and Stokes profile inversion

TL;DR

This paper introduces a neural network-based method that significantly accelerates the synthesis of Stokes profiles in polarized radiative transfer, enabling faster Zeeman-Doppler imaging and Stokes profile inversions without sacrificing accuracy.

Contribution

A novel neural network approach that approximates polarized radiative transfer, reducing computation time by over 1000 times while maintaining high accuracy across various atmospheric conditions.

Findings

Achieves mean RMS errors below 0.2% for Stokes I and V profiles.

Reduces synthesis time by a factor of more than 1000.

Provides accurate local and disk-integrated Stokes profiles.

Abstract

The major challenges for a fully polarized radiative transfer driven approach to Zeeman-Doppler imaging are still the enormous computational requirements. In every cycle of the iterative interplay between the forward process (spectral synthesis) and the inverse process (derivative based optimization) the Stokes profile synthesis requires several thousand evaluations of the polarized radiative transfer equation for a given stellar surface model. To cope with these computational demands and to allow for the incorporation of a full Stokes profile synthesis into Doppler- and Zeeman-Doppler imaging applications as well as into large scale solar Stokes profile inversions, we present a novel fast and accurate synthesis method for calculating local Stokes profiles. Our approach is based on artificial neural network models, which we use to approximate the complex non-linear mapping between the most important atmospheric parameters and the corresponding Stokes profiles. A number of specialized artificial neural networks, are used to model the functional relation between the model atmosphere, magnetic field strength, field inclination, and field azimuth, on one hand and the individual components (I,Q,U,V) of the Stokes profiles, on the other hand. We performed an extensive statistical evaluation and show that our new approach yields accurate local as well as disk-integrated Stokes profiles over a wide range of atmospheric conditions. The mean rms errors for the Stokes I and V profiles are well below 0.2% compared to the exact numerical solution. Errors for Stokes Q and U are in the range of 1%. Our approach does not only offer an accurate approximation to the LTE polarized radiative transfer it, moreover, accelerates the synthesis by a factor of more than 1000.