共查询到18条相似文献,搜索用时 93 毫秒
1.
2.
3.
4.
5.
前言水位保证是浅海水深测量的重要环节,因此,凡是从事浅海水深测量业务的工作者,都在水位保证问题上化费了很大的人力、物力。这与浅海区潮汐较复杂有关;另一方面与目前验潮方法落后有关。本文提出WLR5型水位计在浅海水深测量中的应用,主要是改进验潮工作的手段,提高定点验潮的精度。 相似文献
6.
7.
8.
9.
1994年,我们完成了“中国海域验潮站布设和水位改正研究”,成果于1995年11月通过专家评审认为:该课题的成果,提供了我国沿海验潮站的布设方案,这一方案使原来全国海区基本测量时布设的验潮站大大减少,并在局部潮汐复杂海区由于基本测量控制不足而增设了一些站;确定了沿岸验潮站之间的水位分带方案,把过去局部的、分段的、联系不紧密的站间分带,变成整体的、系统的、全国性的分带网络;近海海域的水位改正方案,代替了操作难度大、受气候影响多、精度很难保证的“定点观测”法,而运用高 相似文献
10.
GPS验潮中波浪的误差分析和消除 总被引:8,自引:0,他引:8
GPS验潮采用GPS RTK计算潮位,是目前GPS技术发展和应用的一个方向,对验潮方法的革新和GPS的进一步应用有着重要的意义。在水面上,波浪引起载体的空间位置改变,给验潮带来很大的误差。为了得到厘米级精度的潮位,必须消除波浪的影响。详细分析了GPS测姿方法和姿态补偿,最后采用小波去噪提取出了潮汐信号。实测数据和模拟数据证明GPS验潮可达到厘米级的精度,满足常规水深测量的精度要求。 相似文献
11.
随着GPS技术的发展,具有RTK功能的GPS接收机不但在平面位置上可以达到厘束级,而且以WGS84为参考椭球的垂直高程也可以达到厘束级,因而被广泛地应用于海岸带测量中。本文介绍了RTKGPS在海域勘界、无验潮模式水深测量方面的一些具体应用。 相似文献
12.
黄河三角洲前沿的陆地由于受地面沉降的影响,使地面高程不断发生变化.在水深测量中,深度基准面是根据陆地水准点高程确定的,陆地水准点高程的变化影响深度基准面的确定,从而影响水深测量的准确性.又由于黄河海港附近有一无潮点,其附近的潮汐性质变化大,在黄河三角洲前沿大范围水深测量中,根据测区潮位变化设立足够的验潮站及统一各个验潮站的水尺零点到同一个深度基准面上,是保证水深测量结果可靠的关键.通过黄河三角洲前沿陆地高程的变化和验潮获得的资料,介绍了黄河三角洲前沿深度基准面的变化和潮位变化情况. 相似文献
13.
为全面剖析淤泥质潮滩变化规律及演变特征,运用修改后的输沙公式建立了淤泥质潮滩演变数值模型。经2000,2007年野外实测数据验证,表明该模型各参数设置准确,较真实地反演了滩涂剖面变化过程,可用于淤泥质潮滩的模拟计算。根据数值模型计算结果得出如下结论:1987-2010年河北省沧州市淤泥质潮滩坡度不断增大,但增长速率变化不大,为0.002×10-3。0 m等深线上部坡度逐渐变缓,年均降低0.021×10-3;下部坡度不断变陡,年均增长0.022×10-3。研究区潮滩未达平衡状态,其坡度将进一步变陡。该输沙模型及研究结论对淤泥质潮滩的保护具有重要的理论指导意义,为其科学开发管理提供实际参考依据。 相似文献
14.
Hyeonju Kim Gwang Hoon Lee Bo Yeon Yi Youngho Yoon Kyong-O Kim Han-Joon Kim Sang Hoon Lee 《Ocean Science Journal》2017,52(2):283-292
In high-resolution, shallow-water seismic surveys, correction for water-column height variations caused by tides, weather, and currents is an important part of data processing. In this study, we present a very simple method of correction for profile-length (i.e., long-wavelength) water-column height variations for high-resolution seismic data using a reference bathymetric grid. First, the difference between the depth of the seafloor picked from seismic data and the bathymetry from the bathymetric grid is computed at the locations where the shot points of seismic profiles and the bathymetric grid points are collocated or closest. Then, the results are gridded and smoothed to obtain the profile-length water-column height variations for the survey area. Next, the water-column height variations for each seismic profile are extracted from the smoothed grid and converted to two-way traveltimes. The corrections for the remaining mis-ties at the intersections, computed within a circular region around each tie shot point, are added to the corrections for the water-column height variations. The final, mistie corrected water-column height corrections are loaded to the SEGY trace header of seismic data as a total static. We applied this method to the sparker data acquired from the shallow-water area off the western-central part of Korea where the tidal range is over 7 m. The corrections for water-column height variations range from -10 to 4 m with a median value of about -2 m. Large corrections occur locally between and near the islands probably due to the amplification and shortening in tidal wavelength caused by rapid shoaling toward the islands. 相似文献
15.
声速误差是多波束水深地形测量主要误差源之一,通常采用现场声速剖面测量的方式加以改正,但在深远海多波束水深地形测量时,现场获取全深度的声速剖面并非易事。针对这一问题,利用东南印度洋海洋调查工作中采集到的17个站位的CTD数据,将所有站位声速剖面拓展到全深度,采用经验正交函数分析法(Empirical Orthogonal Functions,EOF)构建调查区声速剖面场,可获得声速剖面场内任意一点的声速值。然后通过EOF重构声速剖面场获得的声速值对测区内多波束水深地形数据进行改正,并与实测声速剖面对多波束水深地形数据的改正结果进行对比,结果表明,5000 m水深范围内2种声速改正结果相差很小,EOF重构法对深水多波束的声速改正满足水深测量的要求。 相似文献
16.
The accuracy of GPS data analysis for the vertical component has reached a level where the vertical crustal deformation due to the ocean tidal loading should be taken into consideration. Ocean loading affects in particular the results of the GPS analysis for those observation sets covering less than 24 hours. Especially in these cases, a correction for this phenomenon should be performed during the data analysis. On the other hand, it is possible to estimate the ocean loading effect from GPS data sets. In this way it is possible to validate models for the loading deformation derived from global ocean tide models. 相似文献
17.
Tidal Correction of Altimetric Data in the Japan Sea 总被引:2,自引:0,他引:2
Satellite altimetric data have been very useful in the study of variation in the eddy field of the ocean. In order to investigate the variation in the eddy field, we have to remove tidal signals from altimetric data. However, global tidal models do not have sufficient accuracy in marginal seas such as the Japan Sea. In this study, we carried out harmonic analysis of temporal fluctuations of sea surface height data in the Japan Sea measured by TOPEX/POSEIDON. We could eliminate the tidal signals from altimetric data of TOPEX/POSEIDON and also from ERS-2 altimetric data with use of the harmonic constants derived from TOPEX/POSEIDON and tide gauge data along the coast. We draw co-tidal and co-range charts in the Japan Sea using the result of the harmonic analysis of TOPEX/POSEIDON altimetric data and tide gauge data along the coast. The results obtained turn out to be very useful for the tidal correction of altimetric data from satellite in the Japan Sea. 相似文献