An Automated Bolide Detection Pipeline for GOES GLM

TL;DR

This paper introduces an automated machine learning pipeline for detecting bolides using GOES GLM satellite data, aiming to create a comprehensive bolide catalog for atmospheric and asteroid research.

Contribution

It presents a novel automated detection pipeline utilizing machine learning to identify bolides in satellite data, with progress on training, performance, and public data sharing.

Findings

Pipeline successfully detects bolides in satellite data.

Progress in training ML models improves detection accuracy.

Bolide lightcurves are promptly published for research use.

Abstract

The Geostationary Lightning Mapper (GLM) instrument onboard the GOES 16 and 17 satellites has been shown to be capable of detecting bolides (bright meteors) in Earth's atmosphere. Due to its large, continuous field of view and immediate public data availability, GLM provides a unique opportunity to detect a large variety of bolides, including those in the 0.1 to 3 m diameter range and complements current ground-based bolide detection systems, which are typically sensitive to smaller events. We present a machine learning-based bolide detection and light curve generation pipeline being developed at NASA Ames Research Center as part of NASA's Asteroid Threat Assessment Project (ATAP). The ultimate goal is to generate a large catalog of calibrated bolide lightcurves to provide an unprecedented data set which will be used to inform meteor entry models on how incoming bodies interact with the Earth's atmosphere and to infer the pre-entry properties of the impacting bodies. The data set will also be useful for other asteroidal studies. This paper reports on the progress of the first part of this ultimate goal, namely, the automated bolide detection pipeline. Development of the training set, ML model training and iterative improvements in detection performance are presented. The pipeline runs in an automated fashion and bolide lightcurves along with other measured properties are promptly published on a NASA hosted publicly accessible website, https://neo-bolide.ndc.nasa.gov.