Automating Inference of Binary Microlensing Events with Neural Density Estimation
Instrumentation and Methods for Astrophysics2021-02-16v2Earth and Planetary AstrophysicsSolar and Stellar AstrophysicsMachine LearningData Analysis, Statistics and Probability
Automated inference of binary microlensing events with traditional sampling-based algorithms such as MCMC has been hampered by the slowness of the physical forward model and the pathological likelihood surface. Current analysis of such events requires both expert knowledge and large-scale grid searches to locate the approximate solution as a prerequisite to MCMC posterior sampling. As the next generation, space-based microlensing survey with the Roman Space Observatory is expected to yield thousands of binary microlensing events, a new scalable and automated approach is desired. Here, we present an automated inference method based on neural density estimation (NDE). We show that the NDE trained on simulated Roman data not only produces fast, accurate, and precise posteriors but also captures expected posterior degeneracies. A hybrid NDE-MCMC framework can further be applied to produce the exact posterior.
@article{arxiv.2010.04156,
title = {Automating Inference of Binary Microlensing Events with Neural Density Estimation},
author = {Keming Zhang and Joshua S. Bloom and B. Scott Gaudi and Francois Lanusse and Casey Lam and Jessica Lu},
journal= {arXiv preprint arXiv:2010.04156},
year = {2021}
}
Comments
7 pages, 1 figure. This article is superseded by arXiv:2102.05673. Accepted to the ML4PS workshop at NeurIPS 2020