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A Neural Network-Based TEC Model Capable of Reproducing Nighttime Winter Anomaly

Marjolijn Adolfs, Mainul Hoque

2021Remote Sensing24 citationsDOIOpen Access PDF

Abstract

With the availability of fast computing machines, as well as the advancement of machine learning techniques and Big Data algorithms, the development of a more sophisticated total electron content (TEC) model featuring the Nighttime Winter Anomaly (NWA) and other effects is possible and is presented here. The NWA is visible in the Northern Hemisphere for the American sector and in the Southern Hemisphere for the Asian longitude sector under solar minimum conditions. During the NWA, the mean ionization level is found to be higher in the winter nights compared to the summer nights. The approach proposed here is a fully connected neural network (NN) model trained with Global Ionosphere Maps (GIMs) data from the last two solar cycles. The day of year, universal time, geographic longitude, geomagnetic latitude, solar zenith angle, and solar activity proxy, F10.7, were used as the input parameters for the model. The model was tested with independent TEC datasets from the years 2015 and 2020, representing high solar activity (HSA) and low solar activity (LSA) conditions. Our investigation shows that the root mean squared (RMS) deviations are in the order of 6 and 2.5 TEC units during HSA and LSA period, respectively. Additionally, NN model results were compared with another model, the Neustrelitz TEC Model (NTCM). We found that the neural network model outperformed the NTCM by approximately 1 TEC unit. More importantly, the NN model can reproduce the evolution of the NWA effect during low solar activity, whereas the NTCM model cannot reproduce such effect in the TEC variation.

Topics & Concepts

TECLongitudeEnvironmental scienceUniversal TimeInternational Reference IonosphereSolar zenith angleAnomaly (physics)Total electron contentNorthern HemisphereEarth's magnetic fieldGeographic coordinate systemLatitudeAtmospheric sciencesIonosphereGeodesyGeologyPhysicsGeophysicsAstronomyMagnetic fieldCondensed matter physicsQuantum mechanicsIonosphere and magnetosphere dynamicsSolar and Space Plasma DynamicsAtmospheric Ozone and Climate
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