A Multiscale Approach to Geomagnetic Storm Morphology Analysis Based on DMA Activity Measures

Agayan, S. M.; Богоутдинов, Ш. Р.; Krasnoperov, Roman; Сидоров, Роман

doi:10.3390/app112412120

Cited by 3 publications

(7 citation statements)

References 21 publications

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“…The result of this work in theoretical terms should be considered the construction for the original record f = f (t) and the property P specified relative to it, of interest to the researcher, a two-dimensional function µP f = µP f (t, s), expressing on the scale of the segment [−1, 1] in at a given node t, a measure of the manifestation of property P on a record f at a given scale of its consideration s ≥ 0 [Agayan et al, 2016[Agayan et al, , 2021b[Agayan et al, , 2020Oshchenko et al, 2020;Soloviev et al, 2017].…”

Section: Introductionmentioning

confidence: 99%

Regression Derivatives and Their Application in the Study of Magnetic Storms

Agayan,

Bogoutdinov,

Sidorov

et al. 2024

Russian Journal of Earth Sciences

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Discrete Mathematical Analysis (DMA) is a data analysis method that uses fuzzy mathematics and fuzzy logic. DMA involves the active participation of the researcher in the study of records, offering technologies and algorithms for analyzing records through the properties of interest to the researcher. In the present work, such properties are related to regression derivatives, and the results obtained are applied to magnetic records. The possibilities of the method in the morphological analysis of geomagnetic storms are demonstrated on the example of three strongest storms that have occurred since the beginning of the current 25th solar cycle.

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Section: Introductionmentioning

confidence: 99%

Regression Derivatives and Their Application in the Study of Magnetic Storms

Agayan,

Bogoutdinov,

Sidorov

et al. 2024

Russian Journal of Earth Sciences

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“…They occur in the polar region and propagate to the region of mid-and low-latitudes as geomagnetic activity grows. Thus, the task of the current diagnostics of such events is quite topical and is has been solved for several decades by different scientists and research groups [2][3][4][5][6]12,[20][21][22][23][24].…”

Section: Introductionmentioning

confidence: 99%

“…The geomagnetic data modeling and analysis problems are associated with their complicated irregular structure and the presence of noises of different origin (natural and anthropogenic) [22,[24][25][26]. The geomagnetic data structure and the anomalous feature occurrence times contain essential information on nonstationary processes in NES and characterize magnetic disturbance intensity at the place of data recording.…”

Section: Introductionmentioning

confidence: 99%

“…allow us to investigate long-term variations and regular diurnal changes of the magnetic field [2]. However, they are not effective enough to analyze sudden short-period features occurring during increased solar activity and magnetic storms [5,22,[24][25][26]. At the present time, new methods and approaches are being developed to analyze complex geophysical data.…”

Section: Introductionmentioning

confidence: 99%

“…In the papers [5,6,25], it was proposed to apply a fuzzy logic technology to investigate geomagnetic data complicated structures. Application of fuzzy logic elements was further developed in the paper [22], where the authors consider a multi-scale approach and study morphological features of several intensive geomagnetic storms based on it. At the present time, to improve the efficiency of complicated raw data analysis, hybrid approaches, including machine learning methods, are frequently used [8,[26][27][28].…”

Section: Introductionmentioning

confidence: 99%

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Wavelet Model of Geomagnetic Field Variations and Its Application to Detect Short-Period Geomagnetic Anomalies

2022

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Geomagnetic data analysis is an important basis for the investigation of the processes in the near-Earth space, Earth magnetosphere, and ionosphere. The negative impact of geomagnetic anomalies on modern technical objects and human health determine the applied significance of the investigation and requires the creation of effective methods for timely detection of the anomalies. Priory complicated structure of geomagnetic data makes their formalization and analysis difficult. This paper proposes a wavelet model for geomagnetic field variations. It describes characteristic changes and anomalies of different amplitude and duration. Numerical realization of the model provides the possibility to apply it in online analysis. We describe the process of model identification and show its efficiency in the detection of sudden, short-period geomagnetic anomalies occurring before and during magnetic storms. Raw second data of the Paratunka and Magadan observatories and post-processed minute data were used in the paper. The question of noise effect on the proposed model results was under consideration.

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Анализ Вариаций Геомагнитного Поля По Результатам Интерактивной Системы «Аврора»

Ю.А.,

О.В.

2024

Вестник КРАУНЦ. Физико-Математические Науки

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В статье описана геомагнитная компонента системы «Аврора», выполняющая оценку состояния магнитного поля Земли по данным станций «Паратунка» (Камчатский край, 52.97∘ N, 158.24∘ E) и «Хабаровск» (47.61∘ N, 134.69∘ E). Данные получены путем прямых измерений на магнитных обсерваториях. Геомагнитная компонента системы «Аврора» разработана в ИКИР ДВО РАН. Функции данной компоненты базируются на новых подходах и методах, построенных коллективом ученых лаборатории Системного анализа. Разработанные методы основаны на синтезе элементов теории вейвлет-преобразования с методами теории вероятностей и математической статистики. Система обеспечивает комплексную оценку состояния магнитного поля Земли в возмущенные и спокойные периоды и дает возможность изучать пространственно-временные особенности и динамику процессов в магнитосфере Земли. Заключение о состоянии магнитного поля формируется в оперативном режиме. Анализ работы системы в периоды рассмотренных в статье событий подтвердил возможность возникновения слабых короткопериодных синхронных геомагнитных возмущений, предшествующих началу магнитных бурь. Рассмотренная в статье геомагнитная компонента дополняет комплексный анализ данных геофизического мониторинга в системе и является важнейшей её частью. Результаты геомагнитной компоненты системы «Аврора» могут быть использованы в качестве дополнительного инструмента в задачах оперативного прогноза космической погоды. This paper describes the geomagnetic component of the Aurora system, which assesses the state of the Earth’s magnetic field using data from the Paratunka (Kamchatka Krai, 52.97∘ N, 158.24∘ E) and Khabarovsk (47.61∘ N, 134.69∘ E) stations. The data were obtained by direct measurements at magnetic observatories. The geomagnetic component of the Aurora system was developed at IKIR FEB RAS. The functions of this component are based on new approaches and methods developed by the team of scientists of the System Analysis Laboratory. The developed methods are based on the synthesis of elements of wavelet transform theory with methods of probability theory and mathematical statistics. The system provides a comprehensive assessment of the state of the Earth’s magnetic field in disturbed and calm periods and enables the study of spatial and temporal features and dynamics of processes in the Earth’s magnetosphere. The conclusion about the state of the magnetic field is formed in the operational mode. The analysis of the system operation during the periods of the events considered in the article confirmed the possibility of weak short-period synchronous geomagnetic disturbances preceding the onset of magnetic storms. The geomagnetic component considered in the article complements the complex analysis of geophysical monitoring data in the system. The results of the geomagnetic component of the Aurora system can be used as an additional tool in the tasks of operational space weather forecasting.

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A Multiscale Approach to Geomagnetic Storm Morphology Analysis Based on DMA Activity Measures

Cited by 3 publications

References 21 publications

Regression Derivatives and Their Application in the Study of Magnetic Storms

Regression Derivatives and Their Application in the Study of Magnetic Storms

Wavelet Model of Geomagnetic Field Variations and Its Application to Detect Short-Period Geomagnetic Anomalies

Анализ Вариаций Геомагнитного Поля По Результатам Интерактивной Системы «Аврора»

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