Improvement of international reference ionospheric model total electron content maps: a case study using artificial neural network in Egypt

IF 1.2 Q4 REMOTE SENSING
Basma E. Mohamed, Heba S. Tawfik, M. Abdelfatah, G. El-fiky
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引用次数: 0

Abstract

Abstract An essential ionosphere parameter that can be applied for ionosphere corrections in radio systems is the ionosphere’s total electron content (TEC). TEC is a crucial parameter for ionospheric correction in the Global Navigation Satellite Systems (GNSS) of positioning, navigation, and radio science. This study uses the artificial neural network (ANN) application to improve the International Reference Ionospheric Model (IRI-2016) TEC maps across Egypt. The study period is based on the data that were accessible between 2013 and 2020. The ANN model input parameters are (year, day, hour, latitude, and longitude). The ANN1 and ANN2 estimate TEC values of the enhanced IRI-2020 and IRI-2016 according to the Center for Orbit Determination in Europe (CODE), respectively. ANN3 and ANN4 estimate TEC values of the enhanced IRI-2020 and IRI-2016 regarding IGS stations data analyzed by GNSS Analysis software for the multi-constellation and multi-frequency Precise Positioning (GAMP) model, respectively. The ANN model’s validations were based on the root mean square error (RMSE), correlation coefficient (CC), and T-test. According to the results, the suggested ANN can accurately predict the TEC over Egypt. In comparison to the IRI model, the TEC maps that the ANN models produced are significantly more in accordance with the related CODE and GAMP TEC maps. These results demonstrate that the developed approach can enhance IRI 2016 and IRI-2020s ability to estimate global TEC maps. For the ANN1 model, the mean CC and RMSE are 0.92, and 5.15 TECU for all the global data sets compared by CODE. On the other hand, the CC and RMSE between IRI-2020 and CODE are 0.847 and 7.67 TECU. For the ANN2, the mean CC and RMSE are 0.87, 5.59 TECU compared by CODE, respectively. Although the CC and RMSE between IRI-2016 and CODE are 0.820 and 9.052 TECU respectively. For the ANN3, the CC and RMSE are 0.830 and 4.87 TECU compared with GAMP for all global data, respectively. On the other hand, the CC and RMSE between IRI-2020 and GAMP are 0.644 and 10.41, respectively. For the ANN4 the CC and RMSE are 0.82, and 5.95 TECU compared with GAMP, respectively. Although the CC and RMSE between IRI-2016 and GAMP are 0.665 and 12.347 TECU respectively.
国际电离层参考模型总电子含量图的改进:以埃及人工神经网络为例
摘要电离层总电子含量(TEC)是可用于无线电系统电离层校正的一个重要电离层参数。在定位、导航和无线电科学的全球导航卫星系统(GNSS)中,TEC是电离层校正的关键参数。本研究使用人工神经网络(ANN)应用程序改进了国际参考电离层模型(IRI-2016)埃及TEC地图。研究期间基于2013年至2020年期间可获得的数据。ANN模型的输入参数为(年、日、小时、纬度和经度)。根据欧洲轨道确定中心(CODE),ANN1和ANN2分别估计了增强型IRI-2020和IRI-2016的TEC值。ANN3和ANN4分别针对多星座和多频率精确定位(GAMP)模型的GNSS分析软件分析的IGS站数据,估计增强型IRI-2020和IRI-2016的TEC值。神经网络模型的验证基于均方根误差(RMSE)、相关系数(CC)和T检验。结果表明,所提出的人工神经网络能够准确预测埃及上空的TEC。与IRI模型相比,ANN模型产生的TEC映射明显更符合相关的CODE和GAMP TEC映射。这些结果表明,所开发的方法可以增强IRI 2016和IRI-2020s估计全球TEC地图的能力。对于ANN1模型,CODE比较的所有全局数据集的平均CC和RMSE分别为0.92和5.15 TECU。另一方面,IRI-2020和CODE之间的CC和RMSE分别为0.847和7.67 TECU。对于ANN2,与CODE相比,平均CC和RMSE分别为0.87和5.59 TECU。尽管IRI-2016和CODE之间的CC和RMSE分别为0.820和9.052 TECU。对于ANN3,与所有全局数据的GAMP相比,CC和RMSE分别为0.830和4.87 TECU。另一方面,IRI-2020和GAMP之间的CC和RMSE分别为0.644和10.41。对于ANN4,与GAMP相比,CC和RMSE分别为0.82和5.95 TECU。尽管IRI-2016和GAMP之间的CC和RMSE分别为0.665和12.347 TECU。
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来源期刊
Journal of Applied Geodesy
Journal of Applied Geodesy REMOTE SENSING-
CiteScore
2.30
自引率
7.10%
发文量
30
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