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1.
根据1998~2000年完成的118个地磁测点 和39个地磁台的三分量绝对测量资料以及IGRF2000,计算2000年中国地磁场冠谐模型(截断 阶数为8),以及2000~2005年中国地磁长期变化冠谐模型(截断阶数为6). 球冠极位于36 °N,104°E,球冠半角为30°. 中国地磁场冠谐模型能更好地表示我国地磁场的时空变化 ,地磁场模型的均方偏差为:104.4 nT(X分量),103.3 nT(Y分量),123.9 nT(Z分量). 依据地磁场及其长期变化的冠谐模型,分别绘制2000年中国地磁图(F,X,Y,Z)和异常磁场图(ΔF,ΔX,ΔY,ΔZ),以及2000~2005年地磁长期变化图(F,X,Y,Z). 指出改善地磁场模型边界效应 的途径,并对如何布设地磁复测点提出了建议. 相似文献
2.
应用泰勒多项式和曲面样条函数法建立了我国地电场观测台网中华东、 华北两个区域台网的地电场日变化(Kp≤5)模型,并对拟合结果进行了对比分析. 结果表明: ① 尽管地电场变化复杂,但用这两种方法建立的日变化模型相当吻合,模型曲线随时间的变化符合样本曲线随时间的变化; ② 用模型曲线可以描述其它年份同农历日期、 同等磁情时实测的地电场日变化; ③ 用模型曲线描述实测地电场日变化时,低磁情时得出的结果要优于高磁情时的结果; ④ 用多日样本曲线得到的模型曲线更能清晰地展示出地电场日变化的两次起伏波形、 幅度以及极值集中在午前午后等变化特点. 今后建立全国各区域台网不同磁情、 不同农历日期的地电场日变化模型可定量评价区域台网的地电场观测资料的质量,同时根据该模型能够分离出地电场的非正常变化,进而研判真实的异常,以服务于地震等灾害事件的预测以及地球电磁环境变化的监测等方面. 相似文献
3.
2002年在京津冀地区进行了45个测点的地磁三分量测量,对测量资料进行通化处理,通化时间为2002年5月5日16~18时(世界时). 通化后的观测均方差分别优于1.5nT(地磁场总强度F),0.5′(磁偏角D和磁倾角I). 将国际参考地磁场(IGRF2000)作为地磁正常场,建立了京津冀地区地磁异常场的球冠谐模型(BTHASCH). 球冠极的空间位置坐标为39.5°N和117.0°E,球冠半角为4°. 在模型计算过程中,球冠谐函数的截断阶数分别取为1~10. 经综合比较, 最终采用的截断阶数为5. 建立了京津冀地区参考地磁场的球冠谐模型(BTHGRF).根据模型,绘制了京津冀地区地磁异常场图(ΔX、ΔY、ΔZ、ΔF、ΔD、ΔI)和京津冀地区地磁图(X、Y、Z、F、D、I). 相似文献
4.
IGRF(国际地磁参考场)是有关地球 主磁场与长期变化的模型,IGRF的误差主要来源于:忽略外源场、球谐级数的截断、台站分 布的不均匀、测量、忽略地壳磁异常场等. 分析我国大陆地区IGRF的误差,有利于我国地磁 研究 人员在工作中合理地应用IGRF资料. 如果不计磁异常与环境干扰都比较大的北京台,29个基 准台的IGRF的误差(均方根差)为146.9nT. 相似文献
5.
Geomagnetic storm effects at low latitudes 总被引:1,自引:0,他引:1
R. G. Rastogi 《Annales Geophysicae》1999,17(3):438-441
The geomagnetic horizontal (H) field from the chain of nine observatories in India are used to study the storm-time and disturbance daily variations. The peak decrease in storm-time variation in H showed significant enhancements at the equatorial electrojet stations over and above the normally expected decrease due to the ring current effects corrected for geomagnetic latitudes. The disturbance daily variation of H at equatorial stations showed a large decrease around midday hours over and above the usual dawn-maximum and dusk-minimum seen at any mid-latitude stations around the world. These slow and persistent additional decreases of H of disturbance daily variation at equatorial latitudes could be the effect of a westward electric field due to the Disturbance Ionospheric dynamo coupled with abnormally large electrical conductivities in the E region over the equator. 相似文献
6.
选取江苏及邻区地电台网13个台站地电场观测分钟值,采用泰勒多项式和曲面样条函数模型建立地电日变化模型,使用模型曲线描述不同年份、同农历日期、同等磁情天气的实测地电日变化,结果表明:使用分钟值曲线建立的地电日变化模型,更能清晰反映日变化特点,并可反映一天当中台站观测环境、测量系统等变化引起的地电变化;使用同一区域地电台网中若干台站同方向测道的样本曲线,建立各测道电场变化模型,可反映其自身特征及共性特征。 相似文献
7.
根据青藏高原地磁三分量绝对测量资料,使用泰勒多项式方法和冠谐分析方法,计 算了青藏高原地磁场(X, Y,Z )的泰勒多项式模型和青藏高原地磁剩余场(△X,△Y,△Z)的冠谐 模型,并绘制了相应的理论地磁图.分析了磁异常点对地磁场模型的影响,对比分析了地磁 场的多项式模型和冠谐模型,讨论了地磁场模型的边界效应问题. 相似文献
8.
根据2003年中国地磁观测数据(包括135年地磁测点和35个地磁台)以及我国邻近地区38个IGRF计算点的地磁数据,计算中国地磁异常场的分布。选取两种地磁场模型作为地磁正常场,一是国际参考地磁场的球谐模型,二是中国地磁场泰勒多项式模型。根据各个测点的地磁异常值(观测值减去模型计算值),用球冠谐分析方法计算地磁异常场的球冠谐模型,并绘制2003年中国地磁异常(△D,△I,△F,△X,△Y,△Z)。分析和讨论了中国地磁异常场。 相似文献
9.
计算震磁背景场的数学方法 总被引:2,自引:2,他引:0
安振昌 《地震地磁观测与研究》2000,21(5):9-15
如何计算地磁场 (或地磁剩余场 )及其长期变化的趋势变化 ,是提取震磁异常的关键。文章简要介绍了计算震磁背景场的数学方法 :多项式方法、球冠谐和分析方法、矩谐分析方法和曲面样条函数方法 相似文献
10.
《Physics of the Earth and Planetary Interiors》2003,135(2-3):125-134
Many natural phenomena show a relationship between their spatial and temporal Fourier spectra. This paper discusses such a connection for the geomagnetic field, when some assumptions are made about the (exponential or power-law) behaviour of the spatial power spectrum of the field itself and that of its time derivative (the spatial spectrum of the secular variation) as estimated from global geomagnetic field models. It is shown that, under either assumption, the temporal spectrum of the geomagnetic field computed at the core–mantle boundary (CMB) would have a power-law behaviour with a negative spectral exponent of about 0.5. At the Earth’s surface, although the temporal spectrum obtained from the power-law spatial model assumes a slightly more complicated form, it can be practically approximated with a power law with a negative exponent of about 3.6. Analysis of magnetic observatory data confirms these results and that the starting hypotheses are reasonable, especially in view of the possibly chaotic state of the dynamical processes underlying the generation and maintenance of the geomagnetic field. 相似文献
11.
根据中国、前苏联和蒙古等地区的地磁复测点和地磁台站资料,使用泰勒多项式方法和冠谐分析方法,计算东亚地磁场(X,Y,Z)的泰勒多项式模型和冠谐模型,以及东亚剩余磁场(ΔX,ΔY,ΔZ)的冠谐模型和泰勒多项式模型,并绘制了相应的理论地磁图. 泰勒多项式模型的展开原点位于45°N和100°E,截断阶数为7.地磁场泰勒多项式模型的均方偏差为:X分量是133.0nT,Y分量是107.4nT,Z分量是14.0nT. 球冠极点位于45°N和100°E,球冠半角为42°,冠谐模型的截断阶数为10. 剩余磁场冠谐模型的均方偏差分别为131.2nT(ΔX),112.6nT(ΔY)和13.7nT(ΔZ). 对比分析了上述两种模型. 提出了确定区域模型截断阶数的判据. 相似文献
12.
地磁太阴日变化L的M2和O1潮 总被引:1,自引:0,他引:1
介绍M2和O1潮引起的地磁太阳日变化L谐波分析方法,计算了佘山地磁台的磁偏角,水平和垂直分量L的谐波系数,分析了L变化的基本特征,季节变化和场源性质,并与国外其它台站的结果进行对比分析。 相似文献
13.
地磁场模型和冠谐分析 总被引:4,自引:2,他引:4
地磁场是由内源场(地核场和地壳场)和外源场(电离层场和磁层场)组成的,地磁场模型是表示地磁场时空分布的数学表达式.本文简述了地磁场全球模型和区域模型的计算方法和应用;评述了冠谐分析方法及其在地磁学中的应用;介绍了地磁场模型误差的主要来源. 相似文献
14.
An inspection of the long-term behaviour of the range of the daily geomagnetic field variation from comprehensive modelling 总被引:1,自引:0,他引:1
J. Miquel Torta Luis R. Gaya-Piqu Juan J. Curto David Altadill 《Journal of Atmospheric and Solar》2009,71(13):1497-1510
This paper attempts to reveal whether long-term trends in the ionosphere are reflected in the amplitude range of the geomagnetic daily variation recorded at ground level. The smooth and regular variation observed in the magnetograms on magnetically quiet days is induced by the ionospheric currents flowing in the dynamo region. So it is likely that trends in the conductivity or in the dynamics of this region could produce changes in the current densities, and consequently in the range of the geomagnetic variation. The crucial aspect is how to separate the changes produced by the geomagnetic activity itself, or by secular changes of the Earth's magnetic field, from the part of the variation produced by factors affecting trends in the ionosphere, which could have an anthropogenic origin. To investigate this, we synthesized for several geomagnetic observatories the daily ranges of the geomagnetic field components with a comprehensive model of the quiet-time, near-Earth magnetic field, and finally we removed the synthetic values from the observed ranges at those observatories. This comprehensive model accounts for contributions from Earth's core, lithosphere, ionosphere, magnetosphere and coupling currents, and, additionally, accounts for influences of main field and solar activity variations on the ionosphere. Therefore, any trend remaining in the residuals, assuming that all the contributions mentioned above are properly described and thus removed by the comprehensive model, should reflect the influence of other sources. Results, based on series of magnetic data from observatories worldwide distributed, are presented. Trends in the X and Z components are misleading, since the current system changes in form as well as in intensity, producing changes of the focus latitude in the course of a solar cycle and from one cycle to another. Some differences exist between the long-term trends in the Y component between the real and modelled ranges, suggesting that other non-direct solar causes to the amplitude changes of the solar quiet geomagnetic variation should not be ruled out. Nevertheless, the results also reflect some short-comings in the way that the comprehensive modelling accounts for the influence of the solar activity on the range of the daily geomagnetic variation. 相似文献
15.
The spatial-temporal model of the geomagnetic field has been constructed using the data of the high-accuracy survey of the CHAMP German satellite, obtained during its operation from May 2001 to September 2007. The daily average spherical harmonic models calculated at an interval of four days are used as initial data in order to expand these models by the method of natural orthogonal components (NOCs). It has been indicated that the obtained NOC series rapidly converges. The secular variations, secular acceleration, and Dst variation are distinguished as individual NOC components, which makes it possible to construct the spatial-temporal field model. In addition, the models-predictions have been constructed for the year 2008 based on the candidate models of the main field and the secular variation for the year 2005, which were used to obtain the IGRF2005 international model. A comparison of the models-predictions with the model constructed for the year 2008 using our method indicated that the accuracy of our model is not lower than that of the models, obtained by other scientific groups using the traditional method. 相似文献
16.
中国地震局地球物理研究所与蒙古科学院天文与地球物理研究中心于2011—2012年合作开展了蒙古119个野外地磁测点的测量工作. 本文利用蒙古119个测点准确可靠的地磁数据, 分别加上9组边界点EMM2010模型计算值, 得到了蒙古2010.0年代地磁异常场的9个球冠谐和模型; 给出了地磁异常场北向分量ΔX、 东向分量ΔY和垂向分量ΔZ的等值线分布图, 并比较分析了这9个模型的异同; 同时计算了119个测点的地磁测量值与模型计算值之差的均方根误差σ, 以σ为指标来表征这9个模型的精度, 由此定量评价了边界点选取对模型精度的影响. 结果表明, 适当引入边界点能够提高模型精度, 而远离测区3°—5°的均匀边界点也能起到改善模型精度的作用. 因此在实际建模时, 应当在计算区域边界引入适当的边界点, 以改善地磁模型的精度. 相似文献
17.
2009年12月,国际地磁学与高空物理学协会(IAGA)发布了第11代国际地磁参考场(IGRF-11)。第11代IGRF包括1900.0-2010.0年代(间隔为5年)共23个地磁模型与2010.0---2015.0年代地磁长期变化的预测模型,其中1900.0-1995.0年代模型的阶次为N=M=10,相应球谐系数的精度为lnT;2000.0—2010.0年代模型的阶次为N=M=13,其球谐系数的精度为0.1nT;而2010.0—2015.0年代地磁长期变化预测模型的阶次为N=M=8,其球谐系数的精度为0.1nT。本文概述了第11代国际地磁参考场及其2010.0年代地磁模型与2010.0--2015.0年代地磁长期变化的预测模型。 相似文献
18.
本文利用中国地磁子午链台站的资料,对1997~1999年期间发生的25次磁暴,用自然正交分量法(NOC)、相关分析和傅里叶分析三种方法,分3个步骤依次分离出依赖于世界时(UT)的暴时变化(Dst)、依赖于地方时(LT)的太阳静日变化(Sq)和太阳扰日变化(SD).对各种变化时空特征的分析表明:①Dst变化清楚地反映出赤道对称环电流磁扰的空间分布和时间演化特征;②满洲里、北京十三陵和琼中台Sq幅度在多数磁暴主相期间出现极大和极小值,反映了Sq焦点在纬度方向上的移动所产生的地磁效应;③SD变化在主相期间最强,在恢复相期间逐渐减弱;④相关分析和傅里叶分析提供了一种能有效提取Sq和SD变化的方法. 相似文献
19.
根据1936年中国东部和中部地区的地磁测量资料,以及国际地磁参考场DGRF1935和DGRF1940,用冠谐分析方法计算1936年中国地磁参考场(CGRF)的冠谐模型. 冠谐模型的截断阶数为8,球冠极位于36°N和104°E,球冠半角为30°.CGRF1936比相应的国际地磁参考场能更好地表示中国地磁场的分布,本文计算的冠谐模型的均方偏差分别为104.9 nT(X分量),84.8 nT(Y分量)和121.1 nT(Z分量). 根据地磁场的冠谐模型,绘制1936年中国地磁图(X,Y,Z,F)和异常磁场图(ΔX,ΔY,ΔZ,ΔF). 相似文献
20.
S. S. Starjinsky 《Geomagnetism and Aeronomy》2008,48(2):265-276
Results of studying the lunar daily geomagnetic variations in the spectral and time regions at the network of observatories are presented. The seasonal variations in the amplitudes of the fundamental harmonic constituents of three lunar variation components have been revealed. The seasonal time variations have been analyzed using the digital bandpass filtering and harmonic synthesis based on the data of the Kakioka and Memambetsu geomagnetic observatories. The 11-year solar cycle and annual and semiannual periods have been distinguished in the seasonal variation spectrum. Studying the spectral singularities of the lunar daily variation at these observatories and the sea level variations in daytime and nighttime hours has made it possible to identify the contribution of the oceanic dynamo to the lunar variation vertical component. 相似文献