English

Probabilistic Dalek -- Emulator framework with probabilistic prediction for supernova tomography

Machine Learning 2022-09-21 v1 Instrumentation and Methods for Astrophysics

Abstract

Supernova spectral time series can be used to reconstruct a spatially resolved explosion model known as supernova tomography. In addition to an observed spectral time series, a supernova tomography requires a radiative transfer model to perform the inverse problem with uncertainty quantification for a reconstruction. The smallest parametrizations of supernova tomography models are roughly a dozen parameters with a realistic one requiring more than 100. Realistic radiative transfer models require tens of CPU minutes for a single evaluation making the problem computationally intractable with traditional means requiring millions of MCMC samples for such a problem. A new method for accelerating simulations known as surrogate models or emulators using machine learning techniques offers a solution for such problems and a way to understand progenitors/explosions from spectral time series. There exist emulators for the TARDIS supernova radiative transfer code but they only perform well on simplistic low-dimensional models (roughly a dozen parameters) with a small number of applications for knowledge gain in the supernova field. In this work, we present a new emulator for the radiative transfer code TARDIS that not only outperforms existing emulators but also provides uncertainties in its prediction. It offers the foundation for a future active-learning-based machinery that will be able to emulate very high dimensional spaces of hundreds of parameters crucial for unraveling urgent questions in supernovae and related fields.

Cite

@article{arxiv.2209.09453,
  title  = {Probabilistic Dalek -- Emulator framework with probabilistic prediction for supernova tomography},
  author = {Wolfgang Kerzendorf and Nutan Chen and Jack O'Brien and Johannes Buchner and Patrick van der Smagt},
  journal= {arXiv preprint arXiv:2209.09453},
  year   = {2022}
}

Comments

7 pages, accepted at ICML 2022 Workshop on Machine Learning for Astrophysics

R2 v1 2026-06-28T01:42:34.171Z