English

Active Learning for Computationally Efficient Distribution of Binary Evolution Simulations

Solar and Stellar Astrophysics 2022-11-08 v3 Machine Learning

Abstract

Binary stars undergo a variety of interactions and evolutionary phases, critical for predicting and explaining observed properties. Binary population synthesis with full stellar-structure and evolution simulations are computationally expensive requiring a large number of mass-transfer sequences. The recently developed binary population synthesis code POSYDON incorporates grids of MESA binary star simulations which are then interpolated to model large-scale populations of massive binaries. The traditional method of computing a high-density rectilinear grid of simulations is not scalable for higher-dimension grids, accounting for a range of metallicities, rotation, and eccentricity. We present a new active learning algorithm, psy-cris, which uses machine learning in the data-gathering process to adaptively and iteratively select targeted simulations to run, resulting in a custom, high-performance training set. We test psy-cris on a toy problem and find the resulting training sets require fewer simulations for accurate classification and regression than either regular or randomly sampled grids. We further apply psy-cris to the target problem of building a dynamic grid of MESA simulations, and we demonstrate that, even without fine tuning, a simulation set of only 1/4\sim 1/4 the size of a rectilinear grid is sufficient to achieve the same classification accuracy. We anticipate further gains when algorithmic parameters are optimized for the targeted application. We find that optimizing for classification only may lead to performance losses in regression, and vice versa. Lowering the computational cost of producing grids will enable future versions of POSYDON to cover more input parameters while preserving interpolation accuracies.

Keywords

Cite

@article{arxiv.2203.16683,
  title  = {Active Learning for Computationally Efficient Distribution of Binary Evolution Simulations},
  author = {Kyle Akira Rocha and Jeff J. Andrews and Christopher P. L. Berry and Zoheyr Doctor and Aggelos K. Katsaggelos and Juan Gabriel Serra Pérez and Pablo Marchant and Vicky Kalogera and Scott Coughlin and Simone S. Bavera and Aaron Dotter and Tassos Fragos and Konstantinos Kovlakas and Devina Misra and Zepei Xing and Emmanouil Zapartas},
  journal= {arXiv preprint arXiv:2203.16683},
  year   = {2022}
}

Comments

21 pages, 10 figures, ApJ in press

R2 v1 2026-06-24T10:32:39.329Z