Forecasting Global Ionospheric TEC Using Deep Learning Approach

Liu, Lei; Zou, Shasha; Yao, Yibin; Wang, Zi Han

doi:10.1029/2020sw002501

Cited by 114 publications

(77 citation statements)

References 30 publications

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“…The model results show that the first/second hour TEC root mean square error (RMSE) is 1.27/2.20 TECU during storm time and 0.86/1.51 TECU during quiet time. Comparing with the CODE GIMS, the RMSE of the LSTM prediction is 1.06/1.84 TECU for the 1st /2nd hour, while the RMSE errors from the IRI-2016 and NeQuick-2 models are around 9.21/5.5 TECU, respectively (Liu et al, 2020). Moreover, typical large-scale ionospheric structures, such as equatorial ionization anomaly and storm-enhanced density are well reproduced in the predicted TEC maps during storm time.…”

Section: Total Electron Content (Tec) Mapsmentioning

confidence: 80%

“…Spherical harmonic (SH) fitting is often used in constructing the GIM map. We applied an LSTM neural network method (LSTM/NN, Hochreiter and Schmidhuber, 1997) to forecast the 256 SH coefficients, which are then used to construct the GIM maps (Liu et al, 2020). The model results show that the first/second hour TEC root mean square error (RMSE) is 1.27/2.20 TECU during storm time and 0.86/1.51 TECU during quiet time.…”

Section: Total Electron Content (Tec) Mapsmentioning

confidence: 99%

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What sustained multi-disciplinary research can achieve: The space weather modeling framework

Gombosi

Chen

Glocer

et al. 2021

J. Space Weather Space Clim.

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MHD-based global space weather models have mostly been developed and maintained at academic institutions. While the ``free spirit'' approach of academia enables the rapid emergence and testing of new ideas and methods, the lack of long-term stability and support makes this arrangement very challenging. This paper describes a successful example of a university-based group, the Center of Space Environment Modeling (CSEM) at the University of Michigan that developed and maintained the Space Weather Modeling Framework (SWMF) and its core element, the BATS-R-US extended MHD code. It took a quarter of a century to develop this capability and reach its present level of maturity that makes it suitable for research use by the space physics community through the Community Coordinated Modeling Center (CCMC) as well as operational use by the NOAA Space Weather Prediction Center (SWPC).

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Section: Total Electron Content (Tec) Mapsmentioning

confidence: 80%

Section: Total Electron Content (Tec) Mapsmentioning

confidence: 99%

What sustained multi-disciplinary research can achieve: The space weather modeling framework

Gombosi

Chen

Glocer

et al. 2021

J. Space Weather Space Clim.

Self Cite

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“…Areas of interest go from the core GNSS goal, improving localization (Hosseinyalamdary 2018; Diggelen 2019) to all other bias effect presented in Eq. ( 1) like multipath (Diggelen and Wang 2020; Quan et al 2018), ionosphere (Orus 2018;Jiao et al 2007;Liu et al 2020;Linty et al 2019) and troposphere (Benevides et al 2019) effects. These works demonstrate how ML can contribute to address problems addressed in a different way.…”

Section: Machine Learning For Gnssmentioning

confidence: 99%

Proceedings - 3rd Congress in Geomatics Engineering - CIGeo

Furones¹,

Esteban²

2021

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The use of medium/high-density LIDAR (Light Detection And Ranging) data for land modelling and DTM (Digital Terrain Model) is becoming more widespread. This level of detail is difficult to achieve with other means or materials. However, the horizontal and vertical geometric accuracy of the LIDAR points obtained, although high, is not homogeneous. Horizontally you can reach precisions around 30-50 cm, while the vertical precision is rarely greater than 10-15 cm. The result of LIDAR flights, are clouds of points very close to each other (30-60 cm) with significant elevation variations, even if the terrain is flat. And this makes the triangulated models TIN (Triangulated Irregular Network) obtained from such LIDAR data especially chaotic. Since contour lines are generated directly from such triangulated models, their appearance shows excessive noise, with excessively broken and rapidly closed on themselves. Getting smoothed contour liness, without decreasing accuracy, is a challenge for terrain model software. In addition, triangulated models obtained from LIDAR data are the basis for future slope maps of the land. And for the same reason explained in the previous paragraph, these slope maps generated from high or medium density LIDAR point clouds are especially heterogeneous. Achieving uniformity and greater adjustment to reality by reducing the natural noise of LIDAR data is another added challenge. In this paper, the problem of excessive noise from LIDAR data of high (around 8 points/m 2 ) and medium density (around 2 points/m 2 ) in the generation of contour lines and terrain slope maps is raised and solutions are proposed to reduce this noise. All this, in the area of specific software for the management of TIN models and GIS (Geographic Information System) and adapting the alternatives proposed by these programmes.

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“…McGranaghan et al (2017) demonstrated successful application of network analysis to an ionospheric dataset and discovered connections between multi-scale TEC properties and solar influences. Machine learning shows promise in TEC forecasting (Liu et al, 2020). Chen et al (2019) demonstrated a deep learning based approach to fill in missing information in TEC maps.…”

Section: Introductionmentioning

confidence: 99%

Classification of High Density Regions in Global Ionospheric Maps With Neural Networks

Verkhoglyadova

Maus

Meng

2021

Earth and Space Science

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The database of Global Ionospheric Maps (GIMs) produced at Jet Propulsion Laboratory is analyzed. We define high density Total Electron Content (TEC) regions (HDRs) in a map, following certain selection criteria. For the first time, we trained four convolutional neural networks (CNNs) corresponding to four phases of a solar cycle to classify the GIMs by the number of HDRs in each map with ∼76% accuracy on average. We compared HDR counts for GIMs across ten years to draw conclusions on how the number of HDRs in the GIMs changes throughout the solar cycle. Occurrence of HDRs during different geomagnetic activity conditions is discussed. Catalogue of selected HDRs for ten years and four CNN-based models that can be used to extend classification to other years are provided for the community to use.

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Forecasting Global Ionospheric TEC Using Deep Learning Approach

Cited by 114 publications

References 30 publications

What sustained multi-disciplinary research can achieve: The space weather modeling framework

What sustained multi-disciplinary research can achieve: The space weather modeling framework

Proceedings - 3rd Congress in Geomatics Engineering - CIGeo

Classification of High Density Regions in Global Ionospheric Maps With Neural Networks

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