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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
Research article (Space Weather, 2023) · cited 10× · AI/ML
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
Summary
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].
Key Facts
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].
References
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Use these citations when quoting this entity in research, articles, AI prompts, or wherever provenance matters. We aggregate Wikidata + Wikipedia + authoritative open-data sources; the stitched, scored, cross-referenced view is what 4ort.xyz contributes.
APA4ort.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 promptAccording 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)