Classification of Ionospheric Scintillations during high Solar Activity and Geomagnetic Storm over Visakhapatnam Region using Machine Learning Approach

Q4 Engineering

Disaster Advances Pub Date : 2024-02-29 DOI:10.25303/174da011017

N. Shiva Kumar, V.B.S. Srilatha Indira Dutt

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引用次数: 0

Abstract

The ionospheric plasma disturbances typically correlate with irregularities in electron density and ionospheric scintillations are produced in reaction to these variations generating radio signal fluctuations. Geolocation services and space based communication are endangered due to ionospheric scintillation which promptly produces fluctuations in information collected by Global Navigation Satellite Systems and this is at its strongest when the solar cycle is at its peak. Ionospheric space weather has a significant impact on Global Navigation Satellite Systems (GNSS) and one crucial aspect used in investigating ionospheric characteristics is total electron content (TEC). Due to fluctuations in time and space, the TEC obtained from GNSS signals is nonlinear and nonstationary. In this study, machine learning approaches for Classification of the ionospheric scintillations were used during the high solar activity and geomagnetic storm in the month of July 2023. This approach enables the classification of ionospheric phase scintillations using well-known classifiers: Decision Tree and Support Vector Machine.

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利用机器学习方法对维萨卡帕特南地区高太阳活动和地磁暴期间的电离层闪烁进行分类

电离层等离子体扰动通常与电子密度的不规则性相关，电离层闪烁是对这些变化产生无线电信号波动的反应。电离层闪烁会使全球导航卫星系统收集到的信息迅速产生波动，从而危及地理定位服务和天基通信，在太阳周期达到顶峰时，电离层闪烁的影响最为强烈。电离层空间天气对全球导航卫星系统（GNSS）有重大影响，而调查电离层特征的一个重要方面是电子总含量（TEC）。由于时间和空间的波动，从全球导航卫星系统信号中获得的 TEC 是非线性和非稳态的。本研究采用机器学习方法对 2023 年 7 月太阳活动频繁和地磁暴期间的电离层闪烁进行分类。这种方法使用著名的分类器对电离层相位闪烁进行分类：决策树和支持向量机。

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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