基于卫星高度计资料提取浙江近海的潮汐信息

利用Topex/Poseidon(T/P)、Jason-1和Jason-2卫星24a的原始轨道及6a的变轨轨道高度计资料,对浙江近海区域内进行潮汐调和分析,得到8个主要分潮(Q_1、O_1、P_1、K_1、N_2、M_2、S_2和K_2)的调和常数.比较卫星轨道交叉点处潮汐调和常数结果显示,8个分潮总体综合误差在原始轨道,变轨轨道及原始轨道与变轨轨道交叉点处的和方根RSS值分别为3.16、7.02、5.54cm;用卫星高度计资料及31个近岸验潮站得到的潮汐分布与21个验潮站资料结果进行比较,M_2、S_2、N_2、K_1和O_1主要分潮的多点向量均方根偏差分别为4.32、3.64、1.97、2.61、1.83 cm;本研究结果与前人数值模拟结果比较显示M2、S2分潮在对比点处的多点向量均方根偏差在11、8 cm左右,最后给出了浙江近岸及近海区域更为精确的5个主要分潮(M_2、S_2、N_2、K_1和O_1)的同潮图.     

潮汐调和分析方法的回顾与展望

潮汐作为海洋中最普遍的运动过程,与国民经济建设密切相关。潮汐调和分析作为使用最广泛的潮汐数据分析方法,从1921年至今,已历经100年的发展历程。本文对潮汐调和分析方法100年来的研究与发展进行总结与回顾,并对其未来进行了展望,致敬在潮汐调和分析方法发展及应用历程中有所建树的先贤和前辈。     

基于18.6年卫星高度计资料对南海潮汐的分析与研究

利用TOPEX/Poseidon,Jason-1/2共18.6年卫星高度计资料(含变轨后资料),采用最小二乘调和分析法,提取南海12个分潮(Sa,Ssa,Mm,Mf,Q1,O1,P1,K1,N2,M2,S2和K2)调和常数,与沿岸及岛屿58个验潮站数据拟合较好。结果表明,采用更长时间序列的卫星高度计数据,尤其是增加变轨后的资料,分析所得结果得到明显改善。结合沿岸及岛屿264个验潮站数据,绘制4个主要分潮(M2,S2,K1和O1)的等振幅线和同潮时线,较好的展现了南海潮汐分布特征。     

基于近30a多源卫星高度计数据的东中国海潮汐信息提取

我国HY-2B卫星已成功运行3 a多,本文首次将 HY-2B测高数据用于计算潮汐。将HY-2B与相同时间段的Jason-3在东中国海分别进行潮汐信息提取,验证了其结果的一致性。建立了基于 10 颗国内外卫星高度计(TOPEX/Poseidon、Jason-1、Jason-2、Jason-3、ENVISAT、ERS-1、ERS-2、Sentinel-3A、Sentinel-3B、HY-2B)数据的时间序列,得到东中国海近30 a时间序列的较高空间分辨率网格化海面高度。利用该数据提取了东中国海12个分潮(O₁、K₁、Q₁、P₁、M₂、S₂、N₂、K₂、S_A、S_Sa、M_m、M_f)的潮汐调和常数,并将 4 个主要分潮M₂、S₂、K₁、O₁的调和常数...     

利用T/P 卫星高度计资料调和分析南海潮汐信息

利用j,v模型调和分析1992～2002年共10 a的TOPEX/Poseidon(T/P)海面高度距平资料,提取了南海K1,O1,P1,Q1,M2,S2,N2和K2等8个主要分潮的潮汐调和常数。分析比较了卫星上下行轨道的19个交叉点的振幅和迟角,其中M2,S2,K1和O1的平均向量均方根偏差分别是1.5,1.1,2.5和1.4 cm;将交叉点的调和常数与TPXO7.2模式的结果进行了比较,结果表明M2,S2,K1和O1分潮振幅的绝对平均误差均小于3 cm,迟角的最大绝对平均误差为7.8°。选取了与卫星轨道较近的8个验潮站,对验潮站的实测数据调和常数和本文所得调和常数进行了比较,结果显示K1分潮的向量均方根偏差为4.7 cm,M2分潮的向量均方根偏差为3.7 cm。论文结果表明利用j,v模型调和分析方法对南海海域卫星高度计资料进行潮汐信息提取是可靠的,并可为局部重力场的研究提供海洋潮汐改正数据,有一定的参考价值。     

基于卫星高度计数据的全球海洋潮汐特征分析

本文基于长度为18.61年(1992-10-03～2011-04-29)的TOPEX/Poseidon,Jason-1及Jason-2卫星高度计沿轨数据,选择全球海域48943个计算点进行调和分析,提取了四大分潮(M2,S2,K1,O1)的潮汐调和常数.与分布在不同水深下的162个验潮站分析结果对比,四大分潮的矢量均方...     

利用TOPEX/Poseidon卫星高度计资料提取黄海、东海潮汐信息的研究

为了更好地利用卫星测高数据分析黄海和东海的潮汐特性 ,对 1 993— 1 999年期间的TOPEX/Poseidon测高数据进行了质量控制和共线平差处理。在此基础上 ,在黄海、东海选取了 1 738个测高点 ,用最小二乘拟合法计算出 1 2个分潮的调和常数。计算得出的M2 和m1分潮的调和常数 ,在交叉点评估的内符精度振幅分别为 2 4cm和 0 8cm ,迟角分别为 2 3°和2 5°。测高点与附近验潮站的这两个分潮结果相比 ,振幅的均方根误差小于 4cm ,而迟角相差较大。这可能与验潮站的地理环境因素有关。用卫星测高数据算得的调和常数绘制的主要分潮特性图与现有常规观测得到的相应图进行了比较 ,在外海深水区两者符合较好 ;近岸由于卫星测高误差较大 ,所以两者符合差。     

正交潮响应分析法与调和分析法在验潮站潮汐资料分析中的对比研究

根据Munk和Cartwright(1966)提出的响应法与Groves和Renolds(1975)作的正交潮改进,本文利用正交潮响应分析法和调和分析法的混合模型对某验潮站长期潮汐资料进行了分析。将分析结果与调和分析法作对比,结果表明正交潮响应分析法与调和分析法精度基本相同。关于长周期分潮、辐射潮和浅水分潮的正交响应有待进一步研究。     

越南沿海若干验潮站长期观测资料的潮汐分析

为掌握越南沿海潮汐分布特征和变化规律,利用越南沿海HONDAU、HONNGU、DANANG、QUYNHON、VUNGTAU和RACHGIA共6个验潮站长期观测资料进行了调和分析,计算了主要分潮O1、P1、K1、Q1、M2、S2、N2、K2以及交点分潮Mn等长周期分潮的调和常数。计算结果表明,越南沿海地区潮汐特征复杂,极易受季节性海平面变化的影响。分析得到的18.61年交点分潮Mn空间分布不均匀,且明显高于其理论平衡潮振幅,可能与非潮汐低频海平面变化有关。     

基于T/P 和Jason-1 高度计数据的渤黄东海潮汐信息提取

对19 a 的TOPEX/POSEIDON(以下称T/P)和Jason-1 卫星高度计测高数据进行调和分析, 得到渤黄东海海域的8 个主要分潮(M2、S2、N2、K2、K1、O1、P1 和Q1)。提出一种将两类卫星高度计数据统一的方法, 消除了因两类卫星高度计校正算法等不同所导致的相互之间的偏差。变轨后的T/P与Jason-1 卫星加密了高度计对潮汐观测的空间分布。通过对交叉点处升轨与降轨的潮汐调和分析结果进行比较, 检验调和分析方法及高度计数据的可靠性; 将基于高度计数据的调和分析结果与验潮站资料进行比较, 以检验其正确性。4 个主要分潮(M2、S2、K1、O1)振幅之差的均方根介于1.0~1.8 cm, 迟角之差的均方根介于4.1°~7.8°。与已有研究结果相比, 调和分析结果的精确性有所提高。在此基础上, 综合变轨前后两类高度计测高数据的调和分析结果, 给出并分析了渤黄东海4 个主要分潮的同潮图。     

Cotidal charts and tidal power input atlases of the global ocean from TOPEX/Poseidon and JASON-1 altimetry

The global distributions of eight principal tidal constituents, M₂ , S₂ , K₁ , O₁ , N₂ , K₂ , P₁ , and Q₁ , are derived using TOPEX/Poseidon and JASON-1（T/P-J） satellite altimeter data for 16 a. The intercomparison of the derived harmonics at 7000 subsatellite track crossover points shows that the root mean square （RMS） values of the tidal height differences of the above eight constituents range from 1.19 cm to 2.67 cm, with an average of about 2 cm. The RMS values of the tidal height differences between T/P-J solutions and the harmonics from ground measurements at 152 tidal gauge stations for the above constituents range from 0.34 cm to 1.08 cm, and the relative deviations range from 0.031 to 0.211. The root sum square of the RMS differences of these eight constituents is 2.12 cm, showing the improvement of the present model over the existing global ocean tidal models. Based on the obtained tidal model the global ocean tidal energetics is studied and the global distribution of the tidal power input density by tide-generating force of each constituent is calculated, showing that the power input source regions of semidiurnal tides are mainly concentrated in the tropical belt between 30 S and 30 N, while the power input source regions of diurnal tides are mainly concentrated off the tropic oceans. The global energy dissipation rates of the M₂ , S₂ , K₁ , O₁ , N₂ , P₁ , K₂ and Q₁ tides are 2.424, 0.401, 0.334, 0.160, 0.113, 0.035, 0.030 and 0.006 TW, respectively. The total global tidal dissipation rate of these eight constituents amounts to 3.5 TW.     

Estimating trends of the Mediterranean Sea level changes from tide gauge and satellite altimetry data (1993-2015)

The impact of climate change on sea level has received a great deal of attention by scientists worldwide. In this context, the problem of sea levels on global and regional scales have been analyzed in a number of studies based on tide gauges observations and satellite altimetry measurements. This study focuses on trend estimates from 18 high-quality tide gauge stations along the Mediterranean Sea coast. The seasonal Mann-Kendall test was run at a 5% significance level for each of the 18 stations for the period of 1993-2015 (satellite altimetry era). The results of this test indicate that the trends for 17 stations were statistically significant and showed an increase (no significant trend was observed only at one station). The rates of sea level change for the 17 stations that exhibit significant trends, estimated using seasonal Sen's approach, range after correction for Vertical Land Motion (VLM) from 1.48 to 8.72 mm/a for the period 1993-2015. Furthermore, the magnitude of change at the location of each tide gauge station was estimated using the satellite altimetry measurements. Thus, the results obtained agree with those from the tide-gauge data analysis.     

15年测高资料反演南海北部潮汐结果的分析

在调和分析的基础上,结合差比关系的运用,利用T／P和Jason-1卫星测高数据进行了南海北部潮汐状况的反演、分析。其中沿轨数据和交点数据的海面异常（SLA）样本标准差（STD）值计算表明,对于15年资料而言,潮汐分析结果已基本一致。对3年轨道改变后的T／P资料分析发现,运用差比分析的办法能使其分析精度有20％左右的提高,达到与15年资料相近的分析效果。最后文章将近岸的反演结果与实测值作了对比,得出在大多数地区（除水动力复杂区域外）,沿轨数据的反演水位与实测值的误差均值小于19cm,STD值小于14cm。     

Seamount detection and size estimation using filtered geosat altimetry data

Local changes in the marine geoid (<100 nm in size) correspond well with bathymetric features such as seamounts. Thus the marine geoid height may be used to verify existing features, predict the bathymetry of unsurveyed areas, and fill gaps in existing data. The application of matching high‐pass filters to both the geoid and bathymetry data of an area allows the regional trends to be removed so that only the features remain. Filter values that begin to pass data with wavelengths less than 125 miles and all data with wave lengths less than 70 miles were selected. The high‐frequency variations of the geoid can then be correlated to the bathymetry and a scaling factor between the two calculated. The highest correlations (.81) were achieved using a cut‐off value for the filtered geoid data. A gridded synthetic bathymetry file was created by scaling the filtered geoid to the filtered bathymetry and adding the low pass background bathymetry. The gridded historical bathymetry could then be subtracted from the synthetic bathymetry in an automated method to display probable new features. A final selection of 458 previously unreported major features was then made.     

引入差比关系法分析西北太平洋TOPEX/POSEIDON卫星高度计测高数据

TOPEX/POSEIDON(T/P)卫星高度计数据信息中存在周期成分混淆问题.对其中的一类混淆引入差比关系方法对混淆的分潮进行分离.卫星轨道交叉点资料包括升轨和降轨资料,资料量比沿轨点资料多1倍,经分析发现:在已有为期6a多的观测资料时间序列中,在沿轨处混淆的分潮如K₁和SSA在交叉点处不再混淆,可以直接分离.因此首先对交叉点资料进行调和分析.然后由交叉点的分析结果得到分潮间的差比关系,处理到相近的沿轨点处,从而得到沿轨点的调和常数.用引入差比关系方法,对西北太平洋海区6a多的T/P卫星高度计资料进行了潮汐分析,并与沿岸及岛屿验潮站资料进行了比较,所得结果较满意.     

利用卫星测高、GRACE和GOCE资料估计全球海洋表面地转流

重力恢复和气候试验GRACE(gravity recovery and climate experiment)卫星极大地提高了地球重力场的精度和分辨率,特别是中长波分量,联合卫星测高数据可获得全球海洋表面大尺度洋流循环。另外,新一代地球重力和海洋环流探测卫星GOCE(gravity field and steady-state ocean circulation explorer)于2009年3月成功发射,采用卫星重力梯度测量原理,对重力场的高频部分非常敏感,使其高分辨率监测全球海洋循环成为可能。本文利用1~7年GRACE观测数据确定的重力场模型和18个月GOCE观测数据确定的地球重力场模型GO_CONS_GCF_2_TIM_R3,联合卫星测高确定的平均海面高模型MSS_CNES_CLS_11,分别估计全球海洋表面地转流,并且与实测浮标数据结果进行比较。分析表明GOCE重力卫星确定的重力场模型具有更高的空间分辨率,能够确定高精度和高空间分辨率的全球海洋地转流,如墨西哥湾暖流的细节和特征,并且与实测浮标结果基本一致。而基于1~4年GRACE观测资料的模型不能很好估计全球地转流特征,基于7年GRACE观测资料的重力场模型ITG-Grace2010s确定的全球地转流的精度仍低于18个月GOCE观测数据确定的地球重力场模型GO_CONS_GCF_2_TIM_R3的结果,估计的全球地转流仍含有较大的噪声,不能很好地反应中小尺度地转流细节特征。并计算ITG_Grace2010s和GOCE_TIM3的稳态海面地形和全球平均地转流的内符合精度,结果显示,在全球范围内,GOCE_TIM3的稳态海面地形和全球平均地转流的精度都比ITG_Grace2010s结果的精度有着很大的改善,其中ITG_Grace2010s的稳态海面地形的精度为21.6cm,而GOCE_TIM3的结果则为7.45cm,ITG_Grace2010s的全球平均地转流的精度为40.7cm/s,而GOCE_TIM3的结果则为19.6cm/s。     

Persian gulf and Oman sea tide modeling using satellite altimetry and tide gauge data (TM-IR01)

Satellite altimetry observations and tide gauge data are invaluable tools to diagnose and resolve tidal constituents over the Oceans and Seas. The aim of this study is to introduce a new purely empirical tide model named TM-IR01 in the Persian Gulf, Oman Sea, and North Indian Ocean. The observations of three altimeter sensors including TOPEX/POSIDON, JASON1, and JASON2 and 13 coastal tide gauge (TG) stations are processed and analyzed in this research. First of all, the least square spectral analysis is utilized to recover the significant tide components and consequently the amplitude and phases of the constituents are found during the tide modeling. Finally, the analysis results are interpolated into a grid of 1/4° using the Kriging method. TM-IR01 model is validated by comparing with TG stations and global tide models. It is shown that for main tidal frequencies M2, S2, K1, and O1 the root mean square error (RMSE) between TM-IR01 and TG stations results are 0.372, 0.130, 0.141, and 0.084?m, respectively, and also the RMSE between TM-IR01 and FES2004 models are 0.231, 0.087, 0.027, and 0.042?m, respectively. Validating with FES2012 and Tpxo7.2, the results obtained are close to the above values.     

用于分析主要分潮振幅和迟角季节变化的“分步式”调和分析方法

近年来,研究表明全球部分海域的主要分潮存在季节变化。然而,由于使用传统调和分析方法时,分潮的选取受时间窗长度影响,因此难以准确分析潮汐的季节变化。本文结合长、短时间窗,提出“分步式”调和分析方法,通过理想实验和验潮站实际数据分析验证了该方法的准确性。将新方法与传统调和分析方法加以对比,发现无论潮汐是否存在季节变化,该方法都能更加准确地计算主要分潮各月的振幅和迟角。新方法不仅可用于分析验潮站水位数据,还可用于内潮平稳性和非平稳性特征的研究。     

Patterns of upper layer circulation variability in the South China Sea from satellite altimetry using the self-organizing map

Patterns of the South China Sea (SCS) circulation variability are extracted from merged satellite altimetry data from October 1992 through August 2004 by using the self-organizing map (SOM). The annual cycle, seasonal and inter-annual variations of the SCS surface circulation are identified through the evolution of the characteristic circulation patterns. The annual cycle of the SCS gener- al circulation patterns is described as a change between two opposite basin-scale SW-NE oriented gyres embedded with eddies: low sea surface height anomaly (SSHA) (cyclonic) in winter and high SSHA (anticyclonic) in summer half year. The transition starts from July--August (January--February) with a high (low) SSHA tongue east of Vietnam around 12°～14° N, which de- velopa into a big anticyclonic (cyclonic) gyre while moving eastward to the deep basin. During the transitions, a dipole structure, cyclonic (anticyclonic) in the north and anticyclonic (cyclonic) in the south, may be formed southeast off Vietnam with a strong zonal jet around 10°～12° N. The seasonal variation is modulated by the interannual variations. Besides the strong 1997/1998 e- vent in response to the peak Pacific El Nino in 1997, the overall SCS sea level is found to have a significant rise during 1999～ 2001, however, in summer 2004 the overall SCS sea level is lower and the basin-wide anticyclonic gyre becomes weaker than the other years.