Bézier Cubics and Neural Network Agreement along a Moderate Geomagnetic Storm

IF 1.3 4区数学 Q3 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Discrete Dynamics in Nature and Society Pub Date : 2024-03-26 DOI:10.1155/2024/3559969

Emre Eroglu, Mehmet Emir Koksal

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引用次数: 0

Abstract

The discussion models the IRI-2012 TEC map over a moderate geomagnetic storm period (5 days) in February 2015 and compares the yield of the models. The models are constructed with the help of cubic Bézier curves and machine learning. In a sense, the comparison of a classical and mechanical approach with a modern and computer-based one is a considerable experience for the paper. The parametric curve approach governs models of piecewise continuous Bézier cubics, while the models employ only the TEC map. The design is separated into curve components at every five-hour curvature point, and each component is handled independently. Instead of the traditional least squares method for finding control points of cubics, it utilizes the mean of every five-hour of the piecewise curves of the TEC data. Accordingly, the prediction error can be controlled at a rate that can compete with the modern network approach. In the network model, 120 hours of the solar wind parameters and the TEC map of the storm are processed. The reliability of the network model is assessed by the (R) correlation coefficient and mean square error. In modeling the TEC map with the classical approach, the mean absolute error is 0.0901% and the correlation coefficient (R) score is 99.9%. The R score of the network model is 99.6%, and the mean square error is 0.71958 (TECU) (at epoch 47). The results agree with the literature.

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贝塞尔立方体与神经网络在中度地磁暴中的一致性

讨论对 2015 年 2 月中度地磁暴期间（5 天）的 IRI-2012 TEC 图进行建模，并比较模型的收益。这些模型是在立方贝塞尔曲线和机器学习的帮助下构建的。从某种意义上说，将经典的机械方法与现代的计算机方法进行比较是本文的一个重要经验。参数曲线方法适用于片断连续贝塞尔立方体模型，而模型仅采用 TEC 地图。设计在每五个小时的曲率点上分成若干曲线组件，每个组件独立处理。它没有采用传统的最小二乘法来寻找立方体的控制点，而是利用了 TEC 数据中每五小时分段曲线的平均值。因此，预测误差的控制率可与现代网络方法相媲美。在网络模型中，要处理 120 小时的太阳风参数和风暴的 TEC 图。网络模型的可靠性通过（R）相关系数和均方误差来评估。在用经典方法对 TEC 地图建模时，平均绝对误差为 0.0901%，相关系数 (R) 得分为 99.9%。网络模型的 R 得分为 99.6%，均方误差为 0.71958 (TECU)（第 47 个历元）。结果与文献一致。

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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来源期刊

Discrete Dynamics in Nature and Society 综合性期刊-数学跨学科应用

CiteScore

3.00

自引率

0.00%

发文量

598

审稿时长

3 months

期刊介绍： The main objective of Discrete Dynamics in Nature and Society is to foster links between basic and applied research relating to discrete dynamics of complex systems encountered in the natural and social sciences. The journal intends to stimulate publications directed to the analyses of computer generated solutions and chaotic in particular, correctness of numerical procedures, chaos synchronization and control, discrete optimization methods among other related topics. The journal provides a channel of communication between scientists and practitioners working in the field of complex systems analysis and will stimulate the development and use of discrete dynamical approach.