D. Sierra-Porta , J.D. Petro-Ramos , D.J. Ruiz-Morales , D.D. Herrera-Acevedo , A.F. García-Teheran , M. Tarazona Alvarado
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Our analysis covers a large dataset spanning six solar cycles, including the current 25th cycle, to provide comprehensive insights into the dynamics of these storms.</p><p>Our study highlights the significance of the interplanetary magnetic field as a key predictor of geomagnetic storms, challenging previous beliefs that primarily focused on sunspot activity. By using high-resolution data, we uncover new patterns and provide a more detailed analysis of the factors influencing geomagnetic storms. We emphasize the importance of considering a range of heliophysical variables, such as proton temperature and flow pressure, which offer new insights into the complex dynamics driving these storm events.</p><p>The application of machine learning models, particularly Random Forest and Gradient Boosting, demonstrated superior predictive accuracy compared to traditional methods. 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引用次数: 0
摘要
本研究旨在利用机器学习模型,分析行星际磁场、质子密度、太阳风速度和质子温度等多个太阳物理变量,从而加深对地磁暴的理解。我们不依赖基于相关性的传统方法,而是采用先进的机器学习技术来研究这些因素与地磁暴之间的复杂关系。我们的分析涵盖了跨越六个太阳周期(包括当前的第 25 个太阳周期)的大型数据集,从而为这些风暴的动态变化提供了全面的见解。我们的研究强调了行星际磁场作为地磁暴关键预测因子的重要性,对以往主要关注太阳黑子活动的观点提出了质疑。通过使用高分辨率数据,我们发现了新的模式,并对影响地磁暴的因素进行了更详细的分析。我们强调了考虑质子温度和流动压力等一系列太阳物理变量的重要性,这些变量为了解驱动这些风暴事件的复杂动力学提供了新的视角。与传统方法相比,机器学习模型的应用,特别是随机森林和梯度提升,显示出更高的预测准确性。我们的研究结果表明,Dst-index MIN、标量 B 和阿尔法/质子比是影响最大的因素,在预测模型的准确性中占了很大比重。这些发现强调了机器学习在识别地磁活动关键驱动因素和提高预测精度方面的实用性。此外,我们的研究还强调了通过整合各种数据源来准确预测地磁暴的综合模型的必要性。这种机器学习方法不仅能提高预测精度,还能加深我们对空间天气内在机制的理解。这项研究获得的见解对科学研究和实际应用都有重要意义,比如改进地磁暴预警系统,减轻地磁暴对地球的潜在影响。
Machine learning models for predicting geomagnetic storms across five solar cycles using Dst index and heliospheric variables
This study aims to improve the understanding of geomagnetic storms by utilizing machine learning models and analyzing several heliophysical variables, such as the interplanetary magnetic field, proton density, solar wind speed, and proton temperature. Rather than relying on traditional correlation-based methods, we employ advanced machine learning techniques to examine the complex relationships between these factors and geomagnetic storms. Our analysis covers a large dataset spanning six solar cycles, including the current 25th cycle, to provide comprehensive insights into the dynamics of these storms.
Our study highlights the significance of the interplanetary magnetic field as a key predictor of geomagnetic storms, challenging previous beliefs that primarily focused on sunspot activity. By using high-resolution data, we uncover new patterns and provide a more detailed analysis of the factors influencing geomagnetic storms. We emphasize the importance of considering a range of heliophysical variables, such as proton temperature and flow pressure, which offer new insights into the complex dynamics driving these storm events.
The application of machine learning models, particularly Random Forest and Gradient Boosting, demonstrated superior predictive accuracy compared to traditional methods. Our results reveal that the Dst-index MIN, scalar B, and alpha/proton ratio are among the most influential factors, accounting for a significant portion of the prediction model’s accuracy. These findings underscore the utility of machine learning in identifying critical drivers of geomagnetic activity and enhancing forecast precision.
Additionally, our research underscores the need for comprehensive models that can accurately predict geomagnetic storms by integrating various data sources. This machine learning approach not only improves predictive accuracy but also enhances our understanding of the underlying mechanisms of space weather. The insights gained from this study have important implications for both scientific research and practical applications, such as improving early warning systems for geomagnetic storms and mitigating their potential impacts on Earth.
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