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Probabilistic Geomagnetic Storm Forecasting via Deep Learning

Adrian Tasistro‐Hart, Alexander Grayver, Alexey Kuvshinov

2020Journal of Geophysical Research Space Physics31 citationsDOIOpen Access PDF

Abstract

Abstract Geomagnetic storms, which are governed by the plasma magnetohydrodynamics of the solar‐interplanetary‐magnetosphere system, entail a formidable challenge for physical forward modeling. Yet, the abundance of high‐quality observational data has been amenable to the application of data‐hungry neural networks to geomagnetic storm forecasting. Almost all applications of neural networks to storm forecasting have utilized solar wind observations from the Earth‐Sun first Lagrangian point (L1) or closer and generated deterministic output without uncertainty estimates. Furthermore, forecasting work has focused on indices that are also sensitive to induced internal magnetic fields, complicating the forecasting problem with another layer of non‐linearity. We address these points, presenting neural networks trained on observations from both the solar disk and the L1 point. Our architecture generates reliable probabilistic forecasts over Est, the external component of the disturbance storm time index, showing that neural networks can gauge confidence in their output.

Topics & Concepts

Geomagnetic stormProbabilistic logicProbabilistic forecastingSolar windArtificial neural networkMeteorologySpace weatherStormComputer scienceInterplanetary spaceflightEarth's magnetic fieldEnvironmental scienceArtificial intelligenceGeographyPhysicsMagnetic fieldQuantum mechanicsSolar and Space Plasma DynamicsIonosphere and magnetosphere dynamicsGeomagnetism and Paleomagnetism Studies
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