Litcius/Paper detail

Machine learning for semi‐automated meteorite recovery

Seamus Anderson, Martin Towner, Phil Bland, Christopher Haikings, William Volante, Eleanor Sansom, Hadrien Devillepoix, Patrick Shober, Benjamin Hartig, Martin Cupak, Trent Jansen‐Sturgeon, Robert Howie, Gretchen Benedix, Geoff Deacon

2020Meteoritics and Planetary Science10 citationsDOIOpen Access PDF

Abstract

Abstract We present a novel methodology for recovering meteorite falls observed and constrained by fireball networks, using drones and machine learning algorithms. This approach uses images of the local terrain for a given fall site to train an artificial neural network, designed to detect meteorite candidates. We have field tested our methodology to show a meteorite detection rate between 75% and 97%, while also providing an efficient mechanism to eliminate false positives. Our tests at a number of locations within Western Australia also showcase the ability for this training scheme to generalize a model to learn localized terrain features. Our model training approach was also able to correctly identify three meteorites in their native fall sites that were found using traditional searching techniques. Our methodology will be used to recover meteorite falls in a wide range of locations within globe‐spanning fireball networks.

Topics & Concepts

MeteoriteTerrainArtificial intelligenceComputer scienceGeologyRemote sensingDroneArtificial neural networkMachine learningField (mathematics)Range (aeronautics)Training (meteorology)Training setComputer visionAstro and Planetary SciencePlanetary Science and ExplorationGamma-ray bursts and supernovae
Machine learning for semi‐automated meteorite recovery | Litcius