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1.
利用卫星测量技术和小波滤波方法探测表层地转流 总被引:2,自引:0,他引:2
根据海面地形的空域频谱特征, 提出用小波滤波器对海面地形进行滤波降噪的方法. 通过对全球及黑潮流系区域的海面地形进行小波滤波和高斯低通滤波降噪后所确定的地转流的比较, 显示前者较之后者更能表现地转流的局部特征. 依据CG01C卫星重力场模型和EGM96重力场模型, 分别联合由卫星测高确定的KMSS04平均海面高模型构造海面地形. 将据小波滤波降噪后所推算出的全球平均地转流、黑潮和热带太平洋区域地转流与海洋学结果的比较, 以及据此两不同重力场模型推算的大地水准面误差对计算地转流流速精度的对比都表明: 重力卫星确定的地球重力场模型较之以前存在的重力场模型在长波部分精度有较大提高. 联合现有卫星重力和卫星测高数据探测的全球平均地转流, 在大、中尺度上与海洋学结果相一致, 这表明从大地测量(空间)角度来研究洋流已达到较高的精度. 相似文献
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研究和实施了由卫星测高数据计算垂线偏差,用莫洛 金斯基(Molodensky)公式反演 大地水准面高,由此求得我国海域大地水准面高. 为了检核,将测高垂线偏差利用逆维宁迈 纳斯(Vening Meinesz)公式反演重力异常,与海上船测重力值进行了外部检核;同时还用 司托克斯(Stokes)公式,将上述反演的重力异常计算大地水准面高,与莫洛金斯基公式直 接解得的相应结果进行比较作为内部检核. 在积分计算中充分应用了FFT的严格公式.由重力和GPS水准数据确定的陆地大地水准面,和主要由卫星测高数据确定的海洋大地水准 面,二者之间一般都存在以系统误差为主的拼接差,本文分析了产生这一现象的主要原因, 并结合我国在陆海大地水准面拼接区重力资料稀疏的实际,提出了新的拼接技术,最后将拟 合参数校正中国全部海域的重 力大地水准面,以最大限度地削弱拼接点和制约测高海洋大地水准面可能存在的系统误差. 相似文献
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大陆上用重力数据和GPS水准数据确定(似)大地水准面,海洋上用卫星测高数据确定(似)大地水准面.由于沿海地区和近岸海域往往缺少完好的重力数据,近岸海域卫星测高数据质量相对较差,两类大地水准面在陆海相接区域精度偏低且存在拼合差.纯几何方法拟合陆海局部区域大地水准面,不能顾及大地水准面的物理特性,拟合结果不稳定.顾及到大地水准面的物理特性,依据其在局部所应满足的数学物理方程,拟合陆海局部区域大地水准面问题,转化为Laplace第一边值问题.讨论了有限元法衔接陆海局部区域大地水准面的数学思想,给出了相应的数学模型. 相似文献
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利用测高数据的一次差分计算海域垂线偏差,有效降低了动力海面地形和系统残差对垂线偏差的影响;然后根据扰动场元间的协方差函数是具有各态历经性的平稳随机函数这一特征,提出了利用垂线偏差精确逼近海域大地水准面的协方差函数. 而海域大地水准面的精确确定,为从测高数据中精确分离动力海面地形提供了条件. 本文还利用Topex/Poseidon、ERS 1/2测高数据计算了全球海域大地水准面和动力海面地形,证明了本文所述方法是科学合理的. 相似文献
6.
基于频域法,利用最新的GOCE卫星重力场模型和卫星测高数据计算了稳态海面动力地形.结合海洋表层漂流浮标的观测结果,对稳态海面动力地形进行了最优空间滤波尺度分析,给出了区域、纬度带和全球稳态海面动力地形的最优空间滤波尺度因子.在此基础上,给出了全球和区域地转流.结果表明:在中高纬度和全球区域,可以分别获得空间尺度优于102km和127km的稳态海面动力地形信息.与海洋表层漂流浮标对比可知,在强流区域,采用稳态海面动力地形得到的地转流速可以解释观测浮标流速的70%;在中高纬度区域,由GOCE重力场得到的地转流略优于对应的GRACE结果;在近赤道区域,由GOCE重力场得到的地转流精度略低于对应的GRACE结果;在北大西洋和阿古拉斯强流区域,由GOCE得到的地转流场明显优于对应的GRACE结果,其精度分别提高了16%和24%. 相似文献
7.
本文研究了基于泊松小波径向基函数融合多代卫星测高及多源重力数据精化大地水准面模型的方法.分别以沿轨垂线偏差和大地水准面高高差作为卫星测高观测量,研究了使用不同类型测高数据对于大地水准面建模精度的影响.针对全球潮汐模型在浅水区域及部分开阔海域精度较低的问题,引入局部潮汐模型研究了不同潮汐模型对于大地水准面的影响.数值分析表明:相比于使用沿轨垂线偏差作为测高观测量,基于沿轨大地水准面高高差解算得到的大地水准面模型的精度更高,特别是在海域区域,其精度提高了2.3cm.由于使用沿轨大地水准面高高差作为测高观测量削弱了潮汐模型长波误差的影响,采用不同潮汐模型对大地水准面解算的影响较小.总体而言,船载重力及测高观测数据在海洋重力场的确定中呈现互补性关系,联合两类重力场观测量可以提高局部重力场的建模精度. 相似文献
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利用10年高精度卫星测高海面高异常网格资料,联合EGM96稳态海面地形模型,构成南海海域合成海面地形的时间序列,并计算了各个时期的南海表层地转流场. 利用卫星跟踪漂流浮标观测结果与相应时期南海地转流场进行对比验证,结果显示本文结果可以很好地反映南海海域一些中小尺度的环流特征. 根据南海各季节多年平均表层环流场结构,对南海环流周年变化规律和季节特征进行了初步的探讨. 研究结果表明,南海表层环流始终处在不断演变过程之中,在时间和空间上都表现出明显的多尺度特征. 相似文献
10.
利用卫星测高数据推求中国近海及邻域大地水准面起伏和重力异常研究水 总被引:11,自引:2,他引:9
首先对中国近海及邻域(0°-40°N,105°─135°E)内4年的T/P卫星测高数据(1992-10-03-1996-10-09)和1年多的ERS-1卫星测高数据(1992-10-23-1994-01-20)进行了预处理以剔除数据中的粗差影响.然后,对卫星的重复轨迹采用"共线"处理方法得到该海域的平均海平面.在扣除海面地形的影响后得到该海域30'×X30'大地水准面起伏。再分别采用Stokes公式逆运算加FFT技术和最小二乘配置法恢复出该海域30'×30'海洋重力异常.所得到的海洋大地水准面起伏精度为8.5cm,恢复出的重力异常的精度为35×10-5m/s2. 相似文献
11.
HSU HouTse 《中国科学D辑(英文版)》2007,50(6):918-926
According to the features of spatial spectrum of the dynamic ocean topography (DOT),wavelet filter is proposed to reduce short-wavelength and noise signals in DOT. The surface geostrophic currents calculated from the DOT models filtered by wavelet filter in global and Kuroshio regions show more detailed information than those from the DOT models filtered by Gaussian filter. Based on a satellite gravity field model (CG01C) and a gravity field model (EGM96),combining an altimetry-derived mean sea surface height model (KMSS04),two mean DOT models are estimated. The short-wavelength and noise signals of these two DOT models are removed by using wavelet filter,and the DOT models asso-ciated global mean surface geostrophic current fields are calculated separately. Comparison of the surface geostrophic currents from CG01C and EGM96 model in global,Kuroshio and equatorial Pacific regions with that from oceanography,and comparison of influences of the two gravity models errors on the precision of the surface geostrophic currents velocity show that the accuracy of CG01C model has been greatly improved over pre-existing models at long wavelengths. At large and middle scale,the surface geostrophic current from satellite gravity and satellite altimetry agrees well with that from oceanography,which indicates that ocean currents detected by satellite measurement have reached relatively high precision. 相似文献
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Ocean surface fronts and filaments have a strong impact on the global ocean circulation and biogeochemistry. Surface Lagrangian advection with time-evolving altimetric geostrophic velocities can be used to simulate the submesoscale front and filament structures in large-scale tracer fields. We study this technique in the Southern Ocean region south of Tasmania, a domain marked by strong meso- to submesoscale features such as the fronts of the Antarctic Circumpolar Current (ACC). Starting with large-scale surface tracer fields that we stir with altimetric velocities, we determine ‘advected’ fields which compare well with high-resolution in situ or satellite tracer data. We find that fine scales are best represented in a statistical sense after an optimal advection time of ~2 weeks, with enhanced signatures of the ACC fronts and better spectral energy. The technique works best in moderate to high EKE regions where lateral advection dominates. This technique may be used to infer the distribution of unresolved small scales in any physical or biogeochemical surface tracer that is dominated by lateral advection. Submesoscale dynamics also impact the subsurface of the ocean, and the Lagrangian advection at depth shows promising results. Finally, we show that climatological tracer fields computed from the advected large-scale fields display improved fine-scale mean features, such as the ACC fronts, which can be useful in the context of ocean modelling. 相似文献
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Presently, two satellite missions, Gravity Recovery and Climate Experiment (GRACE) and Gravity field and steady-state Ocean Circulation Explorer (GOCE), are making detailed measurements of the Earth’s gravity field, from which the geoid can be obtained. The mean dynamic topography (MDT) is the difference between the time-averaged sea surface height and the geoid. The GOCE mission is aimed at determining the geoid with superior accuracy and spatial resolution, so that a more accurate MDT can be estimated. In this study, we determine the mean positions of the Antarctic Circumpolar Current fronts using the purely geodetic estimates of the MDT constructed from an altimetric mean sea surface and GOCE and GRACE geoids. Overall, the frontal positions obtained from the GOCE and GRACE MDTs are close to each other. This means that these independent estimates are robust and can potentially be used to validate frontal positions obtained from sparse and irregular in situ measurements. The geodetic frontal positions are compared to earlier estimates as well as to those derived from MDTs based on satellite and in situ measurements and those obtained from an ocean data synthesis product. The position of the Sub-Antarctic Front identified in the GOCE MDT is found to be in better agreement with the previous estimates than that identified in the GRACE MDT. The geostrophic velocities derived from the GOCE MDT are also closer to observations than those derived from the GRACE MDT. Our results thus show that the GOCE mission represents an improvement upon GRACE in terms of the time-averaged geoid. 相似文献
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Sea surface height (SSH) as measured by satellites has become a powerful tool for oceanographic and climate related studies. Whereas in the open ocean good accuracy has been achieved, more energetic dynamics and a number of calibration problems have limited applications over continental shelves and near the coast. Tidal ranges in the Southwestern Atlantic (SWA) continental shelf are among the highest in the world ocean, reaching up to 12 m at specific locations. This fact highlights the relevance of the accuracy of the tidal correction that must be applied to the satellite data to be useful in the region. In this work, amplitudes and phases of tidal constituents are extracted from five global tide models and three regional models and compared to the corresponding harmonics estimated from coastal tide gauges (TGs) and satellite altimetry data. The Root Sum Square (RSS) of the misfit of the common set of the five tidal constituents solved by the models (M2, N2, S2, K1 and O1) is higher than 18 cm close to the coast for two of the regional models and higher than 24.5 cm for the rest of the models considered. Both values are too high to provide an accurate estimation of geostrophic non-tidal currents from satellite altimetry in the coastal region. On the other hand, the global model with the highest spatial resolution has a RSS lower than 4.5 cm over the continental shelf even when the non-linear M4 overtide is considered. Comparison with in-situ current measurements suggests that this model can be used to de-tide altimetry data to compute large-scale patterns of SSH and associated geostrophic velocities. It is suggested that a local tide model with very high resolution that assimilates in-situ and satellite data should meet the precision needed to estimate geostrophic velocities at a higher resolution both close to the coast and over the Patagonian shelf. 相似文献
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A global 1/4° resolution product of surface currents has been developed by the Centre de Topographie des Océans et de l’Hydrosphère.
The surface current is calculated from a combination of Ekman currents derived from wind estimates from QuikSCAT satellite,
geostrophic current anomalies derived from altimetry, and a mean geostrophic current derived from climatology. In the equatorial
band, the currents are adjusted following the methodology proposed by Lagerloef et al. (J Geophys Res, 104(C10):22313–22326,
1999). These satellite-derived currents have been compared to different types of in situ current observations. A global validation
is performed using Lagrangian surface drifting buoys and acoustic Doppler current profiler current observations along ship
tracks. The comparison shows a very good agreement in the subtropical and mid-latitude bands. The correlation between the
satellite-derived currents and the drifter currents in zonal mean bands is around 0.7 for most of the world oceans, both for
the zonal and the meridional components. This correlation rises up to 0.8 in the regions of strong boundary currents. In the
equatorial band, the correlation with the surface drifting buoys is reduced. A direct comparison with the TOGA/TAO moored
current meter data at the equator shows that the low frequency currents are captured by the satellite current product, but
there is a substantial high-frequency signal (<20 days), which is not reproduced. This is especially the case for the meridional
component and is mainly related to the tropical instability waves. We also show that using daily QuikSCAT wind forcing improves
the satellite current product, particularly in the high-latitude westerly wind belt and in the tropical Indian Ocean. 相似文献
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Ocean surface currents play a key role in the earth's climate. They affect virtually all processes occurring in the ocean and can also directly affect many important socio-economic activities. Himawari-8 meteorological satellite has an international advanced geostationary orbit imager sensor, AHI, with high time resolution and spatial coverage, Himawari-8 can be used to observe the subtle changes in marine environments. In this study, we used Himawari-8 data received from the Joint Receiving Station for Satellite Remote Sensing of Xiamen University to retrieve coastal currents in Hangzhou Bay. Particularly, the Maximum Correlation Coefficient(MCC) and the Generalized Hough Transform(GHT) methods were used to retrieve them respectively. The retrieved sea surface currents are analyzed and verified by the numerical model data of the Taiwan Strait current forecasting system(TFOR). The results show that(1) the Himawari-8 satellite data can be used to effectively estimate the ocean current;(2) The results of the two methods are in agreement with each other, and the error in the current measured using the GHT method is smaller in the Yangtze estuary and offshore areas, where the turbidity characteristic front is stronger. 相似文献
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《Continental Shelf Research》1995,15(8):981-1014
Low frequency sea-level variations and associated geostrophic currents in the central Great Barrier Reef (GBR) region near Townsville are studied using optimally-lagged multivariate regression. The analyses show that pressure-adjusted coastal sea levels and mid-shelf geostrophic currents are influenced predominantly by local along-shelf wind stress at the weather time-scale, and by climatic variables, such as atmospheric pressure and temperature, at seasonal and inter-annual time-scales. These forcing variables can specify sea levels over annual and inter-annual time-scales with a forecasting skill of 0.53 and 0.22, respectively (where 1.0 is perfect skill). Associated along-shelf geostrophic currents can be forecast with a skill of 0.57 over an annual time scale. If, instead, absolute coastal sea levels or offshore sea-level differences are used to specify the along-shelf geostrophic current, the forecasting skill is 0.75. A characteristic El Niño/Southern Oscillation (ENSO) response is detected for time periods up to 25 years in monthly sea-level both at Townsville and at western Pacific island sea-level stations. This spatially coherent response varies in intensity and phase within the Coral Sea. Sea-level differences show a pattern which characterizes known features of the large-scale circulation of the Coral Sea. These very low frequency sea-level variations in the Coral Sea must be taken into account to obtain accurate predictions of along-shelf geostrophic current variations on seasonal and inter-annual time scales. Regression analysis and a diagnostic river plume model show that the influence of the major rivers can produce sea-level changes due to buoyancy of order 5 cm. The corresponding errors in geostrophic velocities estimated using pressure-adjusted Townsville sea-level data alone are of order 5 cm s−1 rms. 相似文献
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Frédéric Castruccio Jacques Verron Lionel Gourdeau Jean-Michael Brankart Pierre Brasseur 《Ocean Dynamics》2008,58(1):43-63
The altimetric satellite signal is the sum of the geoid and the dynamic topography, but only the latter is relevant to oceanographic
applications. Poor knowledge of the geoid has prevented oceanographers from fully exploiting altimetric measurements through
its absolute component, and applications have concentrated on ocean variability through analyses of sea level anomalies. Recent
geodetic missions like CHAMP, GRACE and the forthcoming GOCE are changing this perspective. In this study, data assimilation
is used to reconstruct the Tropical Pacific Ocean circulation during the 1993–1996 period. Multivariate observations are assimilated
into a primitive equation ocean model (OPA) using a reduced order Kalman filter (the Singular Evolutive Extended Kalman filter).
A 6-year (1993–1998) hindcast experiment is analyzed and validated by comparison with observations. In this experiment, the
new capability offered by an observed absolute dynamic topography (built using the GRACE geoid to reference the altimetric
data) is used to assimilate, in an efficient way, the in-situ temperature profiles from the TAO/TRITON moorings together with
the T/P and ERS1&2 altimetric signal. GRACE data improves compatibility between both observation data sets. The difficulties
encountered in this regard in previous studies such as Parent et al. (J Mar Syst 40–41:381–401, 2003) are now circumvented. This improvement helps provide more efficient data assimilation, as evidenced, by assessing the results
against independent data. This leads in particular to significantly more realistic currents and vertical thermal structures. 相似文献