SBI++: Flexible, Ultra-fast Likelihood-free Inference Customized for Astronomical Applications

TL;DR

SBI++ is a novel likelihood-free inference method tailored for astronomical data, effectively handling out-of-distribution errors and missing data, enabling rapid and accurate galaxy property estimation from large survey datasets.

Contribution

It introduces SBI++, a complete SBI-based approach that manages observational errors and missing data, significantly improving inference accuracy and speed in astronomical applications.

Findings

SBI++ accurately infers photometric redshifts from JWST data.

It outperforms original SBI in handling observational errors.

Inference speed remains around 1 second per object.

Abstract

Flagship near-future surveys targeting $10^8-10^9$ galaxies across cosmic time will soon reveal the processes of galaxy assembly in unprecedented resolution. This creates an immediate computational challenge on effective analyses of the full data-set. With simulation-based inference (SBI), it is possible to attain complex posterior distributions with the accuracy of traditional methods but with a $>10^4$ increase in speed. However, it comes with a major limitation. Standard SBI requires the simulated data to have identical characteristics to the observed data, which is often violated in astronomical surveys due to inhomogeneous coverage and/or fluctuating sky and telescope conditions. In this work, we present a complete SBI-based methodology, ``SBI$^{++}$,'' for treating out-of-distribution measurement errors and missing data. We show that out-of-distribution errors can be approximated by using standard SBI evaluations and that missing data can be marginalized over using SBI evaluations over nearby data realizations in the training set. In addition to the validation set, we apply SBI$^{++}$ to galaxies identified in extragalactic images acquired by the James Webb Space Telescope, and show that SBI$^{++}$ can infer photometric redshifts at least as accurately as traditional sampling methods and crucially, better than the original SBI algorithm using training data with a wide range of observational errors. SBI$^{++}$ retains the fast inference speed of $\sim$1 sec for objects in the observational training set distribution, and additionally permits parameter inference outside of the trained noise and data at $\sim$1 min per object. This expanded regime has broad implications for future applications to astronomical surveys.