Paper Info
Title
Adaptive Forecasting of High-Energy Electron Flux at Geostationary Orbit Using ADALINE Neural Network
Abstract
High-energy electron flux increases in the recovery phase after the space weather events such as a coronal mass ejection. High-energy electrons can penetrate circuits deeply and the penetration could lead to deep dielectric charging. The forecast of high-energy electron flux is vital in providing warning information for spacecraft operations. We investigate an adaptive predictor based on ADALINE neural network. The predictor can forecast the trend of the daily variations in high-energy electrons. The predictor was trained with the dataset of ten years from 1998 to 2008. We obtained the prediction efficiency approximately 0.6 each year except the first learning year 1998. Furthermore, the predictor can adapt to the changes for the satellite's location. Our model succeeded in forecasting the high-energy electron flux 24 hours ahead.
Year
DOI
Venue
2009
10.1007/978-3-642-04592-9_99
KES (2)
Keywords
Field
DocType
geostationary orbit,prediction efficiency,high-energy electron,deep dielectric,adaptive forecasting,high-energy electron flux,adaline neural network,high-energy electron flux increase,daily variation,adaptive predictor,learning year,coronal mass ejection,adaptive learning,space weather,neural network
Coronal mass ejection,Satellite,Aerospace engineering,Environmental science,Flux,Artificial neural network,Adaptive learning,Space weather,Spacecraft,Geostationary orbit
Conference
Volume
ISSN
Citations 
5712
0302-9743
2
PageRank 
References 
Authors
0.56
2
4
Name
Order
Citations
PageRank
Masahiro Tokumitsu1186.55
Yoshiteru Ishida220955.76
Shinichi Watari3114.71
Kentarou Kitamura430.96