Using IRI and GSM TIP model results as environment for HF radio wave propagation model during the geomagnetic storm occurred on September 26-29, 2011

D.S. Kotova; M.V. Klimenko; V.V. Klimenko; V.E. Zakharov; K.G. Ratovsky; I.A. Nosikov; B. Zhao

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Using IRI and GSM TIP model results as environment for HF radio wave propagation model during the geomagnetic storm occurred on September 26-29, 2011

机译：使用IRI和GSM TIP模型结果作为2011年9月26-29日发生地磁风暴期间HF无线电波传播模型的环境

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This paper analyses the geomagnetic storm on September 26-29, 2011. We compare the calculation results obtained using the Global Self-consistent Model of the Thermosphere, Ionosphere and Protonosphere (GSM TIP) and IRI-2012 (Bilitza et al., 2014) model with ground-based ionosonde data of stations at different latitudes and longitudes. We examined physical mechanisms responsible for the formation of ionospheric effects during the main phase of geomagnetic storm that occurred at the rising phase of the 24th solar cycle. We used numerical results obtained from IRI-2012 and GSM TIP models as propagation environment for HF signals from an equatorial transmitter during quiet and disturbed conditions. We used the model of HF radio wave propagation developed in I. Kant Baltic Federal University (BFU) that is based on the geometrical optics approximation. We compared the obtained radio paths in quiet conditions and during the main and recovery storm phases and evaluated radio wave attenuation in different media models.

机译：本文分析了2011年9月26日至29日的地磁风暴。我们比较了使用热球，电离层和质子层的全球自洽模型（GSM TIP）和IRI-2012获得的计算结果（Bilitza等人，2014）带有不同纬度和经度的站的地面离子探空仪数据的模型。我们研究了在第24个太阳周期上升阶段发生的地磁风暴主要阶段中电离层效应形成的物理机制。我们使用从IRI-2012和GSM TIP模型获得的数值结果作为来自赤道发射机的HF信号在安静和干扰条件下的传播环境。我们使用了康塔尔·波罗的海联邦大学（BFU）开发的基于几何光学近似的HF无线电波传播模型。我们比较了在安静条件下以及在主要和恢复风暴阶段获得的无线电路径，并评估了不同媒体模型中无线电波的衰减。

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来源
《Advances in space research》 |2015年第9期|2012-2029|共18页
作者
D.S. Kotova; M.V. Klimenko; V.V. Klimenko; V.E. Zakharov; K.G. Ratovsky; I.A. Nosikov; B. Zhao;
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作者单位

West Department of Pushkov Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation, RAS, 236017 Kaliningrad, Russia,Immanuel Kant Baltic Federal University, Department of Radiophysics and Information Safety, 238300 Kaliningrad, Russia;

West Department of Pushkov Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation, RAS, 236017 Kaliningrad, Russia,Immanuel Kant Baltic Federal University, Department of Radiophysics and Information Safety, 238300 Kaliningrad, Russia;

West Department of Pushkov Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation, RAS, 236017 Kaliningrad, Russia;

Immanuel Kant Baltic Federal University, Department of Radiophysics and Information Safety, 238300 Kaliningrad, Russia;

Institute of Solar-Terrestrial Physics SB RAS, 664033 Irkutsk, Russia;

West Department of Pushkov Institute of Terrestrial Magnetism, Ionosphere and Radio Wave Propagation, RAS, 236017 Kaliningrad, Russia,Immanuel Kant Baltic Federal University, Department of Radiophysics and Information Safety, 238300 Kaliningrad, Russia;

Beijing National Observatory of Space Environment, Institute of Geology and Geophysics, Chinese Academy of Sciences, 100029 Beijing, China,Key Laboratory of Earth and Planetary Physics, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing, China;

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正文语种 eng
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关键词
HF radio wave propagation model; IRI model; First principles model; Ionosonde; F3 layer; Geomagnetic storm;

机译：HF无线电波传播模型;IRI模型;第一性原则模型;离子探空仪F3层;地磁风暴;

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1. Influence of Geomagnetic Storms of September 26-30, 2011, on the Ionosphere and HF Radiowave Propagation. II. Radiowave Propagation [J] . Kotova D. S., Klimenko M. V., Klimenko V. V., Geomagnetism and aeronomy . 2017,第3期

机译：2011年9月26日至30日到2011年9月26日至30日的影响对电离层和HF无线电波传播。 II。 RadioWave繁殖
2. Influence of geomagnetic storms of September 26-30, 2011, on the ionosphere and HF radiowave propagation. I. Ionospheric effects [J] . Klimenko M. V., Klimenko V. V., Bessarab F. S., Geomagnetism and aeronomy . 2015,第6期

机译：2011年9月26日至30日的地磁风暴对电离层和HF无线电波传播的影响。一，电离层效应
3. A Deterministic Model for UHF Radio Wave Propagation through Building Windows in Cellular Environments [J] . Honggang ZHANG, Taro HAYASHIDA, Takashi YOSHINO IEICE Transactions on Communications . 1999,第6期

机译：通过蜂窝环境中的Windows构建UHF无线电波的确定性模型
4. Ionospheric Effects of Geomagnetic Storms on 26–30 September 2011 in the Different Longitudinal Sectors and Their Impact on the HF Radio Wave Propagation [C] . Klimenko Maxim V., Klimenko Vladimir V., Zakharenkova Irina E., 2015 1st URSI Atlantic Radio Science Conference . 2015

机译：2011年9月26日至30日不同纵向区域的地磁风暴的电离层效应及其对HF无线电波传播的影响
5. UHF/MICROWAVE PROPAGATION IN URBAN ENVIRONMENTS (DIFFRACTION, PROPAGATION, MOBILE RADIO). [D] . WALFISCH, JORAM. 1986

机译：UHF /微波在城市环境中的传播（衍射，传播，移动无线电）。
6. Path loss dataset for modeling radio wave propagation in smart campus environment [O] . Segun I. Popoola, Aderemi A. Atayero, Oghenekaro D. Arausi, 2018

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机译：2017年8月31日至9月12日磁场磁风暴中“Novosibirsk-Ulan-Ude”和“Komsomolsk-on-Amur-Ulan-Ude”的波导“地球层”中无线电波传播条件分析
8. HF Radio-Noise Models for Severely Disturbed Propagation Environments [R] . Price, G. H., Hatfield, V. E. 1981

机译：用于严重扰乱传播环境的HF无线电噪声模型

Using IRI and GSM TIP model results as environment for HF radio wave propagation model during the geomagnetic storm occurred on September 26-29, 2011

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