共查询到19条相似文献,搜索用时 281 毫秒
1.
空间大地测量为测定现代地壳形变提供了高效率的技术方法。根据SLR和GPS的观测资料讨论了地中海地区构造运动的计算结果。 相似文献
2.
根据德国卫星激光测距(SLR)数据分析中心GFZ对1980年1月-1991年7月获取的SLR观测数据处理后得到的41个SLR站的站速度,解算了北美、欧亚、太平洋、南美和澳大利亚板块之间的相对运动欧拉矢量,得到了第1个SLR实测的板块运动模型SPMM1.与地学板块模型RM2和NUVEL-1的比较指出,SPMM1大体上与地学模型一致,与NUVEL-1更为接近;SPMM1的欧亚与北美板块相对运动欧拉极与NUVEL-1的相应极很接近,但旋转速率明显偏小.还分析了各板块上SLR站的局部形变特征.欧亚板块东部和西部存在10-20mm/a的相对运动;板块边界附近SLR站的残差站速度基本上反映了该边界的构造形变特征. 相似文献
3.
随着空间大地测量精度的提高与需求的发展,地心运动的研究与监测日益重要,它是精确实现地球质心参考框架的关键之一.本文详解了地心运动的原因(地球系统中的质量迁移)及对空间大地测量与地球物理学的影响,总结了常用的四种地心运动监测方法(网移动法,运动学法,动力学法和一阶形变法)及部分成果和应用,讨论了各方法和SLR,DIRIS,GPS和VLBI四种空间大地测量技术在地心运动监测中的特点,并给出了一些削减误差的建议.为满足地球动态环境研究的需要,地心运动监测的精度与可靠性仍需进一步提高,这依赖于观测精度的提高,地球物理模型的完善和数据处理方法的发展. 相似文献
4.
该文根据向第21届IUGG大会提交的“日本1991-1994年大地测量工作报告”的内容,综合介绍了日本近年来在地壳运动研究方面取得的进展,包括:断层运动的监测与观测技术,GPS与地震、SLR、VLBI,重力变化,等。 相似文献
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6.
本文首先介绍1998年9月在意大利Trieste召开的第二届国际重力委员会(IGC)与国际大地水准面委员会(IGeC)联合大会的有关情况.然后根据大会报告的论文及交流的信息,对国际上物理大地测量若干领域的研究动态及发展趋势作简要论述.最后结合我国物理大地测量研究的有关状况提出思考和建议. 相似文献
7.
本文研究了四维整体大地测量实用化和空间应变的一系列问题.利用整体大地测量和动态平差的理论,建立了实用模型和基础观测方程;进而导出了重力向量、天顶距、方位角、距离、正常高差和重力位差的观测方程,并解决了实用化的局部重力场协方差函数的求定问题:推导了三维应变的公式,并计算了应变参数;改进了德国学者Landan,Hem等人的OPERA软件,用Fortran语言编写了MASSCOMP小型机上的程序,对一个一等三角锁环和部分二等三角点(共124个点)的三角网和重力、水准、天文测量的两期观测结果进行了整体平差,做了应变分析.取得了有参考价值的初步结果. 相似文献
8.
利用中国数字地震台网(CDSN)兰州台短周期数字地震仪的记录资料,研究了1995年甘肃永登MS5.8地震前后,发生在永登地区小地震的S波波谱参数,获得以下结果:(1)在永登地震前2年左右,该地区小地震的SC波波谱拐角频率fC逐渐下降,由原来的2.4Hz下降到1.8Hz.(2)直达波Sg和地壳内中间层反射波SC的波谱高频衰减斜率比值γ则先逐渐上升,在临震前16个月逐渐下降,在下降过程中发生了永登地震,以后又逐渐恢复.(3)用直达横波Sg的谱参数求出的介质品质因数QSg在永登地震前后有较明显的异常变化 相似文献
9.
根据采用动力学方程对亚暴期间磁尾磁场向偶极形弛豫过程中离子分布函数的模拟结果 ,研究了磁尾来自电离层的O+,H+和He+离子的速度及能量随时间的变化 .主要结果为 :(1 )离子的加速及能量变化主要发生在磁场偶极化过程的中期 ,对应的地心距离位于- 1 2RE到 - 8RE 之间 ;(2 )垂直于磁场方向上离子加速及能量变化较快 ,平行方向上较慢 ;(3)轻离子较重离子加速及能量变化快 ,磁场偶极化终结 ,3种离子的能量均可增加 2 0 0倍左右 ;(4)初始能量较高时 ,离子加速及能量变化较快 ,离子最终获得的能量较大 .理论计算的磁尾离子能量在磁场偶极化过程终了可达 1 0 2 keV的量级 ,这与观测结果一致 . 相似文献
10.
近些年来,GPS(全球定位系统)测量取得的进展是其测量精度已可与VLBI及SLR相媲美,由于这样的发展及GPS具有使用方便经济的特点,作为强有力的工具而被用于研究全球大地测量学及地球动力学,GPS测量监测全球板块运动,监视海平面上升,建立地球(参考)框架等等。 相似文献
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The Earth center of mass (geocenter) time series with the sampling interval of one week are determined from Satellite Laser Ranging (SLR), Global Navigation Satellite System (GNSS) and Doppler Orbitography and Radiopositioning Integrated by Satellite (DORIS) observations. The 3D geocenter time series were projected onto XY, YZ and ZX planes of the International Terrestrial Reference Frame (ITRF), thus, three complex-valued time series can be analyzed for each observation technique. The signal to noise ratio in these geocenter time series is very small and detectable oscillations are rather broadband, however, the annual oscillation can be noticed in each one of them. The wavelet transform technique with the Morlet wavelet function was applied to compute the mean and spectra-temporal polarization functions from the prograde (positive periods) and retrograde (negative periods) spectra of the examined complex-valued time series. The sign of the polarization function determines turning direction in the elliptical motion. If this function is positive or negative for oscillation with a chosen period, then this oscillation is prograde or retrograde, respectively. To estimate the significance level of polarization functions, corresponding to time series data length, the Monte Carlo experiment was performed using complex-valued white noise data. In order to detect similarity between elliptic oscillations in two different time series the spectra-temporal wavelet semblance function was computed. This function reveals that in the XY equatorial plane there is phase agreement between retrograde annual oscillation for SLR and GNSS techniques, and between prograde annual oscillation for DORIS and two other techniques. To construct a model of geocenter motion from GNSS and SLR center of mass time series the wavelet based semblance filtering method was applied. Common oscillations in the analyzed time series are dominated by the annual oscillation with amplitude less than 5 mm. 相似文献
12.
Vivien Gornitz 《地球表面变化过程与地形》1995,20(1):7-20
Global mean sea level is a potentially sensitive indicator of climate change. Global warming will contribute to worldwide sea-level rise (SLR) from thermal expansion of ocean water, melting of mountain glaciers and polar ice sheets. A number of studies, mostly using tide-gauge data from the Permanent Service for Mean Sea Level, Bidston Observatory, England, have obtained rates of global SLR within the last 100 years that range between 0·3 and 3 mm yr?1, with most values concentrated between 1 and 2 mm yr?1. However, the reliability of these results has been questioned because of problems with data quality and physical processes that introduce a high level of spatial and temporal variability. Sources of uncertainty in the sea-level data include variations in winds, ocean currents, river runoff, vertical earth movements, and geographically uneven distribution of long-term records. Crustal motions introduce a major source of error. To a large extent, these can be filtered by employing palaeo-sea-level proxies, and geophysical modelling to remove glacio-isostatic changes. Ultimately, satellite geodesy will help resolve the inherent ambiguity between the land and ocean level changes recorded by tide gauges. Future sea level is expected to rise by ~ 1 m, with a ‘best-guess’ value of 48 cm by the year 2100. Such rates represent an acceleration of four to seven times over present rates. Local land subsidence could substantially increase the apparent SLR. For example, Louisiana is currently experiencing SLR trends nearly 10 times the global mean rate. These recently reduced SLR estimates are based on climate models that predict a zero to negative contribution to SLR from Antarctica. Most global climate models (GCMs) indicate an ice accumulation over Antarctica, because in a warmer world, precipitation will exceed ablation/snow-melt. However, the impacts of attritional processes, such as thinning of the ice shelves, have been downplayed according to some experts. Furthermore, not all climate models are in agreement. Opposite conclusions may be drawn from the results of other GCMs. In addition, the West Antarctic Ice Sheet is potentially subject to dynamic and volcanic instabilities that are difficult to predict. Because of the great uncertainty in SLR projections, careful monitoring of future sea-level trends by upgraded tide-gauge networks and satellite geodesy will become essential. Finally, because of the high spatial variability in crustal subsidence rates, wave climates and tidal regimes, it will be the set of local conditions (especially the relative sea-level rise), rather than a single global mean sea-level trend, that will determine each locality's vulnerability to future SLR. 相似文献
13.
本文指出了最新的国际地球参考框架ITRF(International Terrestrial Reference Frame)2005已不能满足当今毫米级地球动态变化监测的需要.提出了利用ITRF2005、SBL/GGFC(Special Bureau for Loading/Global Geophysical Fluids Center)和GRACE(Gravity Recovery and Climate Experiment)等卫星的最新成果,构建毫米级地球参考框架的方案,介绍了对其两个关键问题:地壳非线性运动特征∑RΔXiR(t)和地球质心运动ΔX0(t)的空间技术(GPS,VLBI,SLR和GRACE)监测和地球物理因素模制的方法和一些初步结果,并对目前建立和实现毫米级地球参考框架存在的问题和所能达到的精度进行了初步评估. 相似文献
14.
《Journal of Geodynamics》2006,41(4-5):436-449
In the interest of improving the performance and efficiency of space geodesy a diverse group in the US, in collaboration with IGGOS, has begun to establish a unified National Geodetic Observatory (NGO). To launch this effort an international team will conduct a multi-year program of research into the technical issues of integrating SLR, VLBI, and GPS geodesy to produce a unified set of global geodetic products. The goal is to improve measurement accuracy by up to an order of magnitude while lowering the cost to current sponsors. A secondary goal is to expand and diversify international sponsorship of space geodesy. Principal benefits will be to open new vistas of research in geodynamics and surface change while freeing scarce NASA funds for scientific studies. NGO will proceed in partnership with, and under the auspices of, the International Association of Geodesy (IAG) as an element of the Integrated Global Geodetic Observation System project. The collaboration will be conducted within, and will make full use of, the IAG's existing international services: the IGS, IVS, ILRS, and IERS. Seed funding for organizational activities and technical analysis will come from NASA's Solid Earth and Natural Hazards Program. Additional funds to develop an integrated geodetic data system known as Inter-service Data Integration for Geodetic Operations (INDIGO), will come from a separate NASA program in Earth science information technology. INDIGO will offer ready access to the full variety of NASA's space geodetic data and will extend the GPS Seamless Archive (GSAC) philosophy to all space geodetic data types. 相似文献
15.
Krzysztof Sośnica 《Acta Geophysica》2015,63(4):1181-1203
Satellite Laser Ranging (SLR) to LAGEOS has a remarkable contribution to high-precise geodesy and geodynamics through deriving and validating various global geophysical models. This paper validates ocean tide models based on the analysis of satellite altimetry data, coastal tide gauges, and hydrodynamic data, i.e., CSR3.0, TOPEX4.0, CSR4.0A, FES2004, GOT00.2, and the CSRC Schwiderski model. LAGEOS orbits and SLR observation residuals from solutions based on different ocean tide models are compared and examined. It is found that LAGEOS orbits are sensitive to tidal waves larger than 5 mm. The analysis of the aliasing periods of LAGEOS orbits and tidal waves reveals that, in particular, the tidal constituent S2 is not well established in the recent ocean tide models. Some of the models introduce spurious peaks to empirical orbit parameters, which can be associated with S2, Sa, and K2 tidal constituents, and, as a consequence, can be propagated to fundamental parameters derived from LAGEOS observations. 相似文献
16.
The horizontal transport of water in Earth's surface layer, including sea level change, deglaciation, and surface runoff, is a manifestation of many geophysical processes. These processes entail ocean and atmosphere circulation and tidal attraction, global climate change, and the hydrological cycle, all having a broad range of spatiotemporal scales. The largest atmospheric mass variations occur mostly at synoptic wavelengths and at seasonal time scales. The longest wavelength component of surface mass transport, the spherical harmonic degree-1, involves the exchange of mass between the northern and southern hemispheres. These degree-1 mass loads deform the solid Earth, including its surface, and induce geocenter motion between the center-of-mass of the total Earth system (CM) and the center-of-figure (CF) of the solid Earth surface. Because geocenter motion also depends on the mechanical properties of the solid Earth, monitoring geocenter motion thus provides an additional opportunity to probe deep into Earth's interior. Most modern geodetic measurement systems rely on tracking data between ground stations and satellites that orbit around CM. Consequently, geocenter motion is intimately related to the realization of the International Terrestrial Reference Frame (ITRF) origin, and, in various ways, affects many of our measurement objectives for global change monitoring. In the last 15 years, there have been vast improvements in geophysical fluid modeling and in the global coverage, densification, and accuracy of geodetic observations. As a result of these developments, tremendous progress has been made in the study of geocenter motion over the same period. This paper reviews both the theoretical and measurement aspects of geocenter motion and its implications. 相似文献
17.
《Journal of Geodynamics》2006,41(4-5):494-501
We have processed all available DORIS data from all available satellites, except Jason-1 over the past 10 years (from January 1993 to April 2003). Weekly solutions have been produced for stations positions coordinates, geocenter motion and scale factor stability. We present here accuracy presently achievable for all types of potential geodetic products. Typically weekly stations positions can be derived with a repeatability of 1.0–1.5 cm using data from 5 satellites simultaneously, showing the significant improvement in precision that has been gained recently using the additional new DORIS satellites. As an example, we show how such new results can detect displacement from large magnitude earthquakes, such as the 2003 Denali fault earthquake in Alaska. Displacements of −5 cm in latitude and +2 cm in longitude were easily detected using the DORIS data and are confirmed by recent GPS determination. The terrestrial reference frame was also well be monitored with DORIS during this 10-year period. Other geodetic products, such as tropospheric corrections for atmospheric studies are also analyzed. Finally, we discuss here the possible advantages and weaknesses of the DORIS system as additional geodetic tool, in conjunction with the already existing GPS, VLBI and SLR services, to participate in an Global Geodetic Observing System (GGOS). 相似文献
18.
An established numerical tidal model has been used to investigate the impact of various sea-level rise (SLR) scenarios, as well as SLR in combination with large-scale tidal power plants on European shelf tidal dynamics. Even moderate and realistic levels of future SLR are shown to have significant impacts on the tidal dynamics of the area. These changes are further enhanced when SLR and tidal power plants are considered in combination, resulting in changes to tidal amplitudes, currents and associated tidal dissipation and bed shear stresses. Sea-level rise is the dominant influence on any far-field impacts, whereas tidal power plants are shown to have the prevailing influence over any changes close to the point of energy extraction. The spatial extent of the impacts of energy extraction is shown to be affected by the sea level when more than one tidal power plant in the Irish Sea was considered. Different ways to implement SLR in the model are also discussed and shown to be of great significance for the response of the tides. 相似文献
19.
Sea-level rise (SLR) is considered to be important for barrier behaviour when barriers are swash-aligned and single-crested, which is typical of only one part of a barrier's lifeterm. Under such conditions gravel-barrier retreat rate correlates with mesoscale (sub-decadal: <101 a) SLR rate. Barrier crest overwashing, depending on surge frequency/magnitude, is recognized as the dynamic element that controls barrier retreat rate. Surge characterization of the Halifax tide gauge (using an annual forcing coefficient derived from tide gauge surge residuals) is shown to have high correlation with Story Head (Nova Scotia) barrier retreat rate between 1945 and 1987. Barrier response appears to vary as a function of mesoscale (sub-decadal) SLR and antecedent barrier conditions in combination with the forcing coefficient. Mesoscale (100 a–102 a) rather than macroscale (> 102 a) SLR rate is the critical control on barrier retreat, as mesoscale SLR variation in combination with surge potential is able to raise water level to the elevation threshold sufficient for barrier overwash and hence drive barrier retreat. 相似文献