High latitude ionospheric scintillation forecasting using Deep Learning
International audience Irregularities of ionospheric layer can lead to rapid fluctuations of the amplitude, phase and direction of arrival of a received GNSS signal. Recent advances in deep-learning bring many approaches to study ionospheric scintillation. So that this paper presents models belongin...
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ftonera:oai:HAL:hal-03844421v1 2024-09-15T18:10:08+00:00 High latitude ionospheric scintillation forecasting using Deep Learning Remy, Armand Fabbro, Vincent Jacobsen, Knut Stanley DEMR, ONERA, Université de Toulouse Toulouse ONERA-PRES Université de Toulouse NMA, Norway Boston, United States 2022-08-01 https://hal.science/hal-03844421 en eng HAL CCSD hal-03844421 https://hal.science/hal-03844421 BSS 2022 https://hal.science/hal-03844421 BSS 2022, Aug 2022, Boston, United States IONOSPHERIC SCINTILLATION FORECASTING DEEP LEARNING GNSS [SPI]Engineering Sciences [physics] [PHYS]Physics [physics] info:eu-repo/semantics/conferenceObject Conference papers 2022 ftonera 2024-07-29T23:39:41Z International audience Irregularities of ionospheric layer can lead to rapid fluctuations of the amplitude, phase and direction of arrival of a received GNSS signal. Recent advances in deep-learning bring many approaches to study ionospheric scintillation. So that this paper presents models belonging to the field of artificial intelligence, based on solar wind and geomagnetic indices, to predict Rate of TEC index (ROTI) which is well related to high latitude ionospheric disturbances [Fabbro et al. 2021]. To forecast ROTI index taking into consideration the complex and nonlinear dynamics of the Earth’s magnetosphere and ionosphere, nonlinear models such as Recurrent Neural Network (RNN) have been investigated. First, we have worked on the development and the optimization of Long Short Term Memory (LSTM) neural networks. These models have proven their efficiency in space weather domain to forecast geomagnetic indices specific to Earth magnetic current systems, like am index in [Gruet, 2018]. ROTI databases used come from the Greenland GNSS Network (GNET) and the Norwegian Mapping Authority (NMA). The advantage of such databases is their latitude coverage, offering a large geographic survey of the ionosphere conditions in Arctic region during the 2010-2020 period. ROTI measurements have been aggregated into time series using similar, but not identical, super-observations as introduced in [McGranaghan et al., 2018]. Superobservations should be considered as a statistical summary of the ground receiver-to-individualGNSS satellite links available at a given time and in a given Magnetic Latitude (MLAT) interval. Feature parameters that permit to predict ROTI time series are extracted from the fiveminute resolution HRO dataset, which is provided, by the National Aeronautics and Space Administration (NASA)’s Space Physics Data Facility. The Kendall correlation coefficients have been used to study the existence of a potential relationship between each HRO feature and ROTI super-observations for a 1-hour lead-time ... Conference Object Greenland ONERA: HAL (French Aerospace Lab) |
institution |
Open Polar |
collection |
ONERA: HAL (French Aerospace Lab) |
op_collection_id |
ftonera |
language |
English |
topic |
IONOSPHERIC SCINTILLATION FORECASTING DEEP LEARNING GNSS [SPI]Engineering Sciences [physics] [PHYS]Physics [physics] |
spellingShingle |
IONOSPHERIC SCINTILLATION FORECASTING DEEP LEARNING GNSS [SPI]Engineering Sciences [physics] [PHYS]Physics [physics] Remy, Armand Fabbro, Vincent Jacobsen, Knut Stanley High latitude ionospheric scintillation forecasting using Deep Learning |
topic_facet |
IONOSPHERIC SCINTILLATION FORECASTING DEEP LEARNING GNSS [SPI]Engineering Sciences [physics] [PHYS]Physics [physics] |
description |
International audience Irregularities of ionospheric layer can lead to rapid fluctuations of the amplitude, phase and direction of arrival of a received GNSS signal. Recent advances in deep-learning bring many approaches to study ionospheric scintillation. So that this paper presents models belonging to the field of artificial intelligence, based on solar wind and geomagnetic indices, to predict Rate of TEC index (ROTI) which is well related to high latitude ionospheric disturbances [Fabbro et al. 2021]. To forecast ROTI index taking into consideration the complex and nonlinear dynamics of the Earth’s magnetosphere and ionosphere, nonlinear models such as Recurrent Neural Network (RNN) have been investigated. First, we have worked on the development and the optimization of Long Short Term Memory (LSTM) neural networks. These models have proven their efficiency in space weather domain to forecast geomagnetic indices specific to Earth magnetic current systems, like am index in [Gruet, 2018]. ROTI databases used come from the Greenland GNSS Network (GNET) and the Norwegian Mapping Authority (NMA). The advantage of such databases is their latitude coverage, offering a large geographic survey of the ionosphere conditions in Arctic region during the 2010-2020 period. ROTI measurements have been aggregated into time series using similar, but not identical, super-observations as introduced in [McGranaghan et al., 2018]. Superobservations should be considered as a statistical summary of the ground receiver-to-individualGNSS satellite links available at a given time and in a given Magnetic Latitude (MLAT) interval. Feature parameters that permit to predict ROTI time series are extracted from the fiveminute resolution HRO dataset, which is provided, by the National Aeronautics and Space Administration (NASA)’s Space Physics Data Facility. The Kendall correlation coefficients have been used to study the existence of a potential relationship between each HRO feature and ROTI super-observations for a 1-hour lead-time ... |
author2 |
DEMR, ONERA, Université de Toulouse Toulouse ONERA-PRES Université de Toulouse NMA, Norway |
format |
Conference Object |
author |
Remy, Armand Fabbro, Vincent Jacobsen, Knut Stanley |
author_facet |
Remy, Armand Fabbro, Vincent Jacobsen, Knut Stanley |
author_sort |
Remy, Armand |
title |
High latitude ionospheric scintillation forecasting using Deep Learning |
title_short |
High latitude ionospheric scintillation forecasting using Deep Learning |
title_full |
High latitude ionospheric scintillation forecasting using Deep Learning |
title_fullStr |
High latitude ionospheric scintillation forecasting using Deep Learning |
title_full_unstemmed |
High latitude ionospheric scintillation forecasting using Deep Learning |
title_sort |
high latitude ionospheric scintillation forecasting using deep learning |
publisher |
HAL CCSD |
publishDate |
2022 |
url |
https://hal.science/hal-03844421 |
op_coverage |
Boston, United States |
genre |
Greenland |
genre_facet |
Greenland |
op_source |
BSS 2022 https://hal.science/hal-03844421 BSS 2022, Aug 2022, Boston, United States |
op_relation |
hal-03844421 https://hal.science/hal-03844421 |
_version_ |
1810447731204816896 |