Accelerated inference of microlensed gravitational waves with machine learning (2511.08486v1)

Abstract: Gravitational waves (GWs) propagating through the universe can be microlensed by stellar and intermediate-mass objects. Lensing induces frequency-dependent amplification of GWs, which can be computed using \texttt{GLoW}, an accurate code suitable for evaluating this factor for generic lens models and arbitrary impact parameters depending on the lens configuration. For parameter inference, we employ the DINGO algorithm, a machine learning framework based on neural posterior estimation, a simulation-based inference method that uses normalizing flows to efficiently approximate posterior distributions of the physical parameters. As a proof-of-principle, we demonstrate that it enables efficient parameter estimation of diffracted GW signals using an isolated point mass lens model. This method can be useful for rapidly identifying microlensed events within large GW catalogs and for conducting population studies of compact binaries. Compared to traditional parameter estimation techniques, we find that combining DINGO with importance sampling can provide efficient estimation of the background Bayes-factor distribution, which is required in evaluating the significance of candidate lensed events. However, for foreground (lensed) events, care must be taken, as sampling efficiency can decrease when the lensed data lie outside the distribution learned by the unlensed DINGO network. Our framework can be naturally extended to more complex and realistic lens models, allowing detailed analyses of the microlensed GWs.