Sequential simulation-based inference for extreme mass ratio inspirals
Abstract
Extreme mass-ratio inspirals pose a difficult challenge in terms of both search and parameter estimation for upcoming space-based gravitational-wave detectors such as LISA. Their signals are long and of complex morphology, meaning they carry a large amount of information about their source, but are also difficult to search for and analyse. We explore how sequential simulation-based inference methods, specifically truncated marginal neural ratio estimation, could offer solutions to some of the challenges surrounding extreme-mass-ratio inspiral data analysis. We show that this method can efficiently narrow down the volume of the complex 11-dimensional search parameter space by a factor of and provide 1-dimensional marginal proposal distributions for non-spinning extreme-mass-ratio inspirals. We discuss the current limitations of this approach and place it in the broader context of a global strategy for future space-based gravitational-wave data analysis.
Cite
@article{arxiv.2505.16795,
title = {Sequential simulation-based inference for extreme mass ratio inspirals},
author = {Philippa S. Cole and James Alvey and Lorenzo Speri and Christoph Weniger and Uddipta Bhardwaj and Davide Gerosa and Gianfranco Bertone},
journal= {arXiv preprint arXiv:2505.16795},
year = {2025}
}
Comments
11 pages, 9 figures plus appendices