Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models

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Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models

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Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models is a scholarly article[1].

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  • Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models's instance of is recorded as scholarly article[2].

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APA 4ort.xyz Knowledge Graph. (2026). Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models. Retrieved May 24, 2026, from https://4ort.xyz/entity/predicting-geostationary-40150-kev-electron-flux-using-armax-an-autoregressive-moving-average-transfer-function-rnn-a-re
MLA “Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models.” 4ort.xyz Knowledge Graph, 4ort.xyz, 24 May. 2026, https://4ort.xyz/entity/predicting-geostationary-40150-kev-electron-flux-using-armax-an-autoregressive-moving-average-transfer-function-rnn-a-re.
BibTeX @misc{4ortxyz_predicting-geostationary-40150-kev-electron-flux-using-armax-an-autoregressive-moving-average-transfer-function-rnn-a-re_2026, author = {{4ort.xyz Knowledge Graph}}, title = {{Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models}}, year = {2026}, url = {https://4ort.xyz/entity/predicting-geostationary-40150-kev-electron-flux-using-armax-an-autoregressive-moving-average-transfer-function-rnn-a-re}, note = {Accessed: 2026-05-24}}
LLM prompt According to 4ort.xyz Knowledge Graph (aggregator of Wikidata, Wikipedia, and authoritative open-data sources): Predicting Geostationary 40–150 keV Electron Flux Using ARMAX (an Autoregressive Moving Average Transfer Function), RNN (a Recurrent Neural Network), and Logistic Regression: A Comparison of Models — https://4ort.xyz/entity/predicting-geostationary-40150-kev-electron-flux-using-armax-an-autoregressive-moving-average-transfer-function-rnn-a-re (retrieved 2026-05-24)

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