Deriving Ionospheric Sporadic E Intensity From FORMOSAT‐3/COSMIC and FY‐3C Radio Occultation Measurements

Hu, Tianyang; Luo, Jia; Xu, Xiaohua

doi:10.1029/2022sw003214

Cited by 3 publications

(6 citation statements)

References 50 publications

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“…Similarly, in plot (d), we see E s intensity peaking in the austral summer (December-February) and reaching its minimum in winter (June-August). Although in the Southern Hemisphere, the intensities do not get quite as high as the Northern Hemisphere, which has also been noticed in Hu et al (2022) and Niu et al (2019). Both the solar driven diurnal behavior and maximum intensity during summer months of the respective hemisphere agree with results reported in literature (Hodos et al, 2022;Yu et al, 2022).…”

Section: Overall E S Intensity Performancesupporting

confidence: 88%

“…Although in the Southern Hemisphere, the intensities do not get quite as high as the Northern Hemisphere, which has also been noticed in Hu et al. (2022) and Niu et al. (2019).…”

Section: Resultssupporting

confidence: 66%

“…In the remaining sections, the method from Yu et al (2020) will be referred to as S 4, max , the method from Gooch et al (2019) as TEC, and the method from Hu et al (2022) as S max .…”

Section: Existing Model Comparisonsmentioning

confidence: 99%

“…In addition to analyzing the ML models, it is useful to compare the models with others found in literature. For this comparison, we use the methods from Yu et al (2020), Gooch et al (2019), andHu et al (2022) to make predictions using the same testing set as the CNN models.…”

Section: Existing Model Comparisonsmentioning

confidence: 99%

“…Over the years, sporadic E has been measured and monitored using a variety of different instrumentation and methods. This list includes sounding rockets (Hall et al., 1971; Mori & Oyama, 1998; Yamamoto et al., 1998), incoherent scatter radars (ISR) (Christakis et al., 2009; Mathews, 1998), ionosondes (Haldoupis et al., 2006; Merriman et al., 2021; Oikonomou et al., 2014), and GNSS radio occultations (RO) (Arras & Wickert, 2018; Arras et al., 2008; Chu et al., 2014; Gooch et al., 2019; Hocke et al., 2001; Hu et al., 2022; Wu et al., 2005; Zeng & Sokolovskiy, 2010). While sounding rockets are able to provide accurate in situ measurements, they are generally carried out in campaigns which limited spatial and temporal coverage.…”

Section: Introductionmentioning

confidence: 99%

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Detection and Classification of Sporadic E Using Convolutional Neural Networks

Ellis,

Emmons,

Cohen

2024

Space Weather

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In this work, convolutional neural networks (CNN) are developed to detect and characterize sporadic E (Es), demonstrating an improvement over current methods. This includes a binary classification model to determine if Es is present, followed by a regression model to estimate the Es ordinary mode critical frequency (foEs), a proxy for the intensity, along with the height at which the Es layer occurs (hEs). Signal‐to‐noise ratio (SNR) and excess phase profiles from six Global Navigation Satellite System (GNSS) radio occultation (RO) missions during the years 2008–2022 are used as the inputs of the model. Intensity (foEs) and the height (hEs) values are obtained from the global network of ground‐based Digisonde ionosondes and are used as the “ground truth,” or target variables, during training. After corresponding the two data sets, a total of 36,521 samples are available for training and testing the models. The foEs CNN binary classification model achieved an accuracy of 74% and F1‐score of 0.70. Mean absolute errors (MAE) of 0.63 MHz and 5.81 km along with root‐mean squared errors (RMSE) of 0.95 MHz and 7.89 km were attained for estimating foEs and hEs, respectively, when it was known that Es was present. When combining the classification and regression models together for use in practical applications where it is unknown if Es is present, an foEs MAE and RMSE of 0.97 and 1.65 MHz, respectively, were realized. We implemented three other techniques for sporadic E characterization, and found that the CNN model appears to perform better.

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Section: Overall E S Intensity Performancesupporting

confidence: 88%

“…Although in the Southern Hemisphere, the intensities do not get quite as high as the Northern Hemisphere, which has also been noticed in Hu et al. (2022) and Niu et al. (2019).…”

Section: Resultssupporting

confidence: 66%

“…In the remaining sections, the method from Yu et al (2020) will be referred to as S 4, max , the method from Gooch et al (2019) as TEC, and the method from Hu et al (2022) as S max .…”

Section: Existing Model Comparisonsmentioning

confidence: 99%

Section: Existing Model Comparisonsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Detection and Classification of Sporadic E Using Convolutional Neural Networks

Ellis,

Emmons,

Cohen

2024

Space Weather

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Sporadic E critical frequency detection using three EIA region ionosonde stations over Southeast Asia

Wichaipanich,

Nishioka,

Min Myint

et al. 2024

Advances in Space Research

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Validation of Ionospheric Parameters From Electron Density Profiles of FY‐3E Satellite Using Ionosonde, GIMs, Satellite Altimetry and Other Occultations

Huang,

Chen,

Yao

et al. 2024

JGR Space Physics

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The FengYun‐3E satellite (FY‐3E) is the first to feature the GNSS Occultation Sounder II (GNOS‐II). Occultation is effective for ionosphere detection, but data variations between FY‐3E and other techniques are inevitable due to differing instruments and methodologies. Evaluating the GNOS‐II performance against other techniques is imperative. We extract ionospheric parameters—the F2 layer peak height (hmF2), F2 layer critical frequency (foF2), and Vertical Total Electron Content (VTEC)—from FY‐3E's electron density profile. We use ionosonde, Global Ionospheric Maps (GIMs), and Satellite Altimetry (SA), along with FY‐3D and COSMIC‐2 to analyze FY‐3E's performance. Additionally, we use the International Reference Ionosphere (IRI‐2020) to normalize VTEC, eliminating systematic biases due to altitude differences. Results show that FY‐3E's foF2 has high consistency with ionosonde, while hmF2 shows larger differences. However, both foF2 and hmF2 from FY‐3E, FY‐3D, and COSMIC‐2 have comparable data quality. TEC differences between FY‐3E and GIMs are greater during equinoxes and in the daytime. Significant TEC deviations are observed, particularly in low‐latitude region affected by the Equatorial Ionization Anomaly (EIA) during the daytime, with underestimation at EIA crests and overestimation at EIA troughs and around ±40° geomagnetic latitude, a phenomenon also observed when compared to SA. FY‐3D and COSMIC‐2 exhibit similar patterns, but FY‐3E shows better consistency with GIMs and SA compared to FY‐3D. Compared to FY‐3D and FY‐3E, COSMIC‐2 has fewer overestimated profiles. Furthermore, FY‐3E performs poorly in observing ionospheric structure in the EIA region but performs well in the Weddell Sea Anomaly (WSA) region, similar to FY‐3E.

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Deriving Ionospheric Sporadic E Intensity From FORMOSAT‐3/COSMIC and FY‐3C Radio Occultation Measurements

Cited by 3 publications

References 50 publications

Detection and Classification of Sporadic E Using Convolutional Neural Networks

Detection and Classification of Sporadic E Using Convolutional Neural Networks

Sporadic E critical frequency detection using three EIA region ionosonde stations over Southeast Asia

Validation of Ionospheric Parameters From Electron Density Profiles of FY‐3E Satellite Using Ionosonde, GIMs, Satellite Altimetry and Other Occultations

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