Application of convolution neural networks for critical frequency fₒF2 prediction

Pub Date : 2023-03-28 DOI:10.12737/stp-91202307
B. Salimov, O. Berngardt, A. Hmelnov, K. Ratovsky, Oleg Kusonsky
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Abstract

Ionosphere has an important impact on the quality of radio communication, radar, and global positioning. One of the essential characteristics describing the state of the ionosphere is its critical frequency fₒF2. Its prediction provides effective modes of operation of technical radio equipment as well as enables calculation of the corrections needed to improve the accuracy of its functioning. Different physical and empirical models are generally used for fₒF2 prediction. This paper proposes an empirical prediction technique based on machine learning methods and observational history. It relies on a regression approach to the prediction based on the known daily quasi-periodicity of ionospheric parameters related to solar illumination. Algorithmically, this approach is implemented in the form of convolutional neural networks with two-dimensional convolution. The input data for the analysis is presented as two-dimensional solar time — date matrices. The model was trained on data from the mid-latitude ionosonde in Irkutsk (RF) and tested using data from several mid-latitude ionosondes: Arti (RF), Warsaw (Poland), Mohe (China). It is shown that the main contribution to the prediction value of fₒF2 is made by the data on the nearest few days before the prediction; the contribution of the remaining days strongly decreases. This model has the following forecast quality metrics (Pearson correlation coefficient 0.928, root mean square error 0.598 MHz, mean absolute error in percent 10.45 %, coefficient of determination 0.861) and can be applied to fₒF2 forecast in middle latitudes.
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卷积神经网络在临界频率fₒF2预测中的应用
电离层对无线电通信、雷达和全球定位的质量有着重要影响。描述电离层状态的基本特征之一是其临界频率fₒF2.它的预测提供了技术无线电设备的有效操作模式,并能够计算出提高其功能准确性所需的校正。f通常使用不同的物理模型和经验模型ₒF2预测。本文提出了一种基于机器学习方法和观测历史的经验预测技术。它依赖于基于已知的与太阳光照有关的电离层参数的每日准周期性的回归预测方法。在算法上,该方法以具有二维卷积的卷积神经网络的形式实现。用于分析的输入数据表示为二维太阳时间-日期矩阵。该模型是根据伊尔库茨克(RF)中纬度电离层的数据进行训练的,并使用几个中纬度电离层:阿提(RF)、华沙(波兰)、漠河(中国)的数据进行测试。结果表明,对f的预测值的主要贡献ₒF2是由预测前最近几天的数据得出的;剩余天数的贡献显著减少。该模型具有以下预测质量指标(Pearson相关系数0.928,均方根误差0.598 MHz,平均绝对误差百分比10.45%,决定系数0.861),可应用于fₒF2在中纬度地区的预报。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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