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卫星测高中的垂线偏差法 总被引:6,自引:0,他引:6
卫星测高中的垂线偏差法是当前利用卫星测高技术研究海洋重力场的最优方法,包括利用卫星测高数据计算垂线偏差和利用该垂线偏差确定海洋重力场两部分。研究了Sandwell、Olgiafi、Hwang测高垂线偏差的计算方法和Molodenskii、Hwang利用测高垂线偏差确定海洋重力场的基本原理,分析比较了上述方法的异同,为科学地利用卫星测高资料反演海洋重力场提供理论依据。 相似文献
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利用卫星测高技术确定海洋重力场,垂线偏差数据作为导出观测量在实际工作中被普遍采用。利用物理大地测量边值问题的定义以及扰动位在球面边界条件下的解,给出了由垂线偏差计算大地水准面高、重力异常和扰动重力的公式。分析了不同积分计算公式在重力场阶谱表达形式下对垂线偏差误差的抑制作用,也分析了不同积分核函数的变化特性,得出基本结论:在利用卫星测高数据求解海洋重力场时,当以格网化海面垂线偏差数据计算重力场参数时,求解的大地水准面高的有效性和稳定性优于重力异常和扰动重力。 相似文献
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星载测高仪可以实时测量从卫星到瞬时海面的距离,对这一距离进行各种误差改正后,就可以用于多种不同的目的。 大地测量学家和海洋学家共同关心的问题是:如何从这一距离信息中提取大地水准面和海面地形。鉴于这两种信息在一定波长上是相互迭加的,因而分离海面地形和大地水准面就变得非常艰巨了。过去人们都是采用从平均海面中减去大地水准面的直接方法来分离的,后来人们又采用整体求解法(即同时确定海面地形,改善重力位模型及减小轨道误差)来分离。但这一问题至今并没有得到完美的解决。本文首先介绍了卫星测高技术的一些发展背景,继而对人们惯用的分离海面地形与大地水准面的方法进行了分析讨论,同时提出了改进海面地形与大地水准面可分性的一些方法。 相似文献
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准确的海面风速预报是舰艇航行安全和防台工作的重要保证。目前在舰艇上估测海面风速方法主要是利用传真天气图手工绘算单站地转风,并对理论风速值进行适当摩擦系数订正。这种方法的估测精度比较差,很难满足舰艇指挥人员在复杂天气中的预报需求。为了深入探讨海面风估算方法,给出了传真地面天气图上地转风、梯度风的近似计算公式,介绍了用传真图实时计算地转风与梯度风的实现方法,提出了通过建立风速订正值库由风速理论值实时估测平均海面风速的一种新方法,并深入探讨了梯度风测风方法在强天气测风中的应用特点和优势。经实际应用和分析表明,计算精度得到很大提高,有一定应用和推广价值。 相似文献
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S. Thomas Crough 《Marine Geophysical Researches》1982,5(3):263-271
Geoid height anomalies, as determined by satellite altimetry, suggest that the Cape Verde Rise is in local isostatic equilibrium, supported by a low-density root of altered lithosphere. A depth anomaly map shows the Cape Verde Rise to be approximately 1600 km wide and 2km high. Removal of a quadratic surface from the observed geoid heights leaves a residual positive anomaly with the same shape as the rise and an amplitude of about 8 m. The ratio of residual geoid height anomaly to depth anomaly is consistent with an isostatic root only 40 km deep on average. 相似文献
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With the advent of satellite altimetry in 1973, new scientific applications became available in oceanography, climatology, and marine geosciences. Moreover, satellite altimetry provides a significant source of information facilitated in the geoid determination with a high accuracy and spatial resolution. The information from this approach is a sufficient alternate for marine gravity data in the high-frequency modeling of the marine gravity field quantities. The gravity gradient tensor, consisting of the second-order partial derivatives of the gravity potential, provides more localized information than gravity measurements. Marine gravity observations always carry a high noise level due to environmental effects. Moreover, it is not possible to model the high frequencies of the Earth's gravity field in a global scale using these observations. In this article, we introduce a novel approach for a determination of the gravity gradient tensor at sea level using satellite altimetry. Two numerical techniques are applied and compared for this purpose. In particular, we facilitate the radial basis functions (RBFs) and the harmonic splines. As a case study, the gravitational gradient tensor is determined and results presented in the Persian Gulf. Validation of results reveals that the solution of the harmonic spline approach has a better agreement with a theoretical zero-value of the trace of the Marussi gravitational gradient tensor. However, the data-adaptive technique in the RBF approach allows more efficient selection of the parameters and 3-D configuration of RBFs compared to a fixed parameterization by the harmonic splines. 相似文献
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Abstract Geoid heights and vertical deflections derived from satellite radar altimetry contain characteristic signals that may be reproduced and explained by simple models for seamount gravitation acting on the sea surface. Computer algorithms capable of automatic operation and able to detect, approximately locate, and estimate parameters constraining the shape of actual sea‐mounts were written and tested. The computer program which utilized a digital high‐pass filter combined with a roughness sensor was effective in separating the seamount produced geoid undulation/vertical deflection pattern from the remaining data track features, simultaneously detecting and locating along the track such signals. Tests of the algorithm on several SEASAT passes over known bathymetry produced mixed results. Meaningful shape constraints were obtained by matching the geoid anomaly calculated from the seamount model to the actual mean sea level pattern for some seamounts. Results for other seamounts were poor and possible reasons for the failure are discussed. It is concluded that a computerized seamount detection program for radar altimetry data is feasible, but it will have to be more complex than the present one for fully successful operation. 相似文献
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太平洋卫星测高重力场与地球动力学特征 总被引:6,自引:1,他引:6
通过多卫星测高数据的综合处理,获得西太平洋卫星测高重力场,进行不同尺度、深度构造动力信息的分离,探讨诸边缘海盆的地球动力学问题。测高大地水准面反映了研究区板块相互作用的特点,其高频成分可以刻画各海盆的构造特征。测高空间重力异常也可刻画陆架构造及盆地分布,由其推算出的海底地形含有大量的海底构造信息。各边缘海盆的莫霍面埋深具有往南变浅的趋势,与菲律宾海各海盆的莫霍面埋深大致相当,说明岛弧两侧的构造动力强度基本相似。大尺度地幔流应力场总体上反映了欧亚板块向东南蠕散和太平洋板块向北西扩张的特点;日本海北侧和南海巽他陆架的中尺度上地幔对流与地幔柱之间有着密切关系,西菲律宾海的上地幔对流强化了日本-琉球-台湾-菲律宾岛弧的活动强度;小尺度地幔流主要限于软流圈层内部,在各海盆分散,而在冲绳海槽和马里亚纳海槽则会聚,可与均衡重力异常类比。还讨论了大、中、小地幔流体系的特点及相互之间的关系,籍以阐明海盆及海槽演化的地球动力学过程。 相似文献
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The recovery of quantities related to the gravity field (i.e., geoid heights and gravity anomalies) is carried out in a test area of the central Mediterranean Sea using 5' × 5' marine gravity data and satellite altimeter data from the Geodetic Mission (GM) of ERS‐J. The optimal combination of the two heterogeneous data sources is performed using (1) the space‐domain least‐squares collocation (LSC) method, and (2) the frequency‐domain input‐output system theory (IOST). The results derived by these methods agree at the level of 2 cm in terms of standard deviation in the case of the geoid height prediction. The gravity anomaly prediction results by the same methods vary between 2.18 and 2.54 mGal in terms of standard deviation. In all cases, the spectral techniques have a much higher computational efficiency than the collocation procedure. In order to investigate the importance of satellite altimetry for gravity field modeling, a pure gravimetric geoid solution, carried out in a previous study for our lest area by the fast collocation approach (FCOL), is used in comparison with the combined geoid models. The combined solutions give more accurate results, at the level of about 15 cm in terms of standard deviation, than the gravimetric geoid solution, when the geoid heights derived by each method are compared with TOPEX altimeter sea surface heights (SSHs). Moreover, nonisotropic power spectral density functions (PSDs) can be easily used by IOST, while LSC requires isotropic covariance functions. The results show that higher prediction accuracies are always obtained when using a priori nonisotropic information instead of isotropic information. 相似文献
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Robert E. Cheney Bruce C. Douglas David T. Sandwell James G. Marsh Thomas V. Martin John J. McCarthy 《Marine Geophysical Researches》1984,7(1-2):17-32
Satellite-borne altimeters have had a profound impact on geodesy, geophysics, and physical oceanography. To first order approximation,
profiles of sea surface height are equivalent to the geoid and are highly correlated with seafloor topography for wavelengths
less than 1000 km. Using all available Geos-3 and Seasat altimeter data, mean sea surfaces and geoid gradient maps have been
computed for the Bering Sea and the South Pacific. When enhanced using hill-shading techniques, these images reveal in graphic
detail the surface expression of seamounts, ridges, trenches, and fracture zones. Such maps are invaluable in oceanic regions
where bathymetric data are sparse. Superimposed on the static geoid topography is dynamic topography due to ocean circulation.
Temporal variability of dynamic height due to oceanic eddies can be determined from time series of repeated altimeter profiles.
Maps of sea height variability and eddy kinetic energy derived from Geos-3 and Seasat altimetry in some cases represent improvements
over those derived from standard oceanographic observations. Measurement of absolute dynamic height imposes stringent requirements
on geoid and orbit accuracies, although existing models and data have been used to derive surprisingly realistic global circulation
solutions. Further improvement will only be made when advances are made in geoid modeling and precision orbit determination.
In contrast, it appears that use of altimeter data to correct satellite orbits will enable observation of basin-scale sea
level variations of the type associated with climatic phenomena. 相似文献
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Ship-board global navigation satellite system (GNSS) measurements are widely used to determine sea surface heights, marine geoid validation, and/or satellite altimetry calibration. However, the use of a vessel could be complicated near coastal areas due to shallow water. Therefore, in the area of sea ice formation, GNSS measurements on the ice surface could be a viable alternative to vessel-borne surveys. Importantly, the ice-covered water is not affected by short-term winds, which otherwise could have systematic influence on the instantaneous sea surface topography. This study tackles methodology and validation of marine geoid models by profile-wise GNSS measurements on ice in an archipelago of the Baltic Sea. The GNSS measurements were carried out on the three ice roads with total length 48 kilometers. The along-route standard deviation between the gravimetric geoid model and profile-wise GNSS heights remained within ±2.1 centimeters. 相似文献
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A method has been developed to monitor the surface velocity field by combining repeated acoustic Doppler current profiler
(ADCP) observations and satellite altimetry data. The geostrophic velocity anomaly is calculated from the sea surface height
anomaly field estimated from the altimetry data by an optimal interpolation. It has been confirmed that this accurately observes
the smoothed velocity anomaly field when the interpolation scales are set according to the spatio-temporal sampling pattern
of the altimeter used. The velocity anomaly obtained from the altimetry data is subtracted from the repeated ADCP observations
to estimate temporal mean velocity along the ship tracks. Regularly sampled, nine-year time series of surface velocity can
then be obtained by adding the computed mean velocity and the altimetry anomaly components. This clearly illustrates surface
velocity fluctuations such as the movement of the Kuroshio axis due to its meandering and an increase of the interannual variability
of the Subtropical Countercurrent toward its downstream region.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
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Ole Baltazar Andersen Karina Nielsen Per Knudsen Chris W. Hughes Rory Bingham Luciana Fenoglio-Marc 《Marine Geodesy》2013,36(6):517-545
AbstractThe ocean mean dynamic topography (MDT) is the surface representation of the ocean circulation. The MDT may be determined by the ocean approach, which involves temporal averaging of numerical ocean circulation model information, or by the geodetic approach, wherein the MDT is derived using the ellipsoidal height of the mean sea surface (MSS), or mean sea level (MSL) minus the geoid as the geoid. The ellipsoidal height of the MSS might be estimated either by satellite or coastal tide gauges by connecting the tide gauge datum to the Earth-centred reference frame. In this article we present a novel approach to improve the coastal MDT, where the solution is based on both satellite altimetry and tide gauge data using new set of 302 tide gauges with ellipsoidal heights through the SONEL network. The approach was evaluated for the Northeast Atlantic coast where a dense network of GNSS-surveyed tide gauges is available. The typical misfit between tide gauge and satellite or oceanographic MDT was found to be around 9?cm. This misfit was found to be mainly due to small scale geoid errors. Similarly, we found, that a single tide gauge places only weak constraints on the coastal dynamic topography. 相似文献