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1.
针对使用自容式压力验潮仪在布设临时验潮站时常出现的验潮零点漂移技术难题,基于附近长期验潮站的潮汐观测数据来计算二站同步时段内逐时日平均海面之差值,以此修正临时验潮站观测数据中隐含的验潮零点逐时漂移量。以福建平潭长期站和王爷山、牛山岛两个临时站的验潮数据为例,进行了自容式压力验潮仪验潮零点漂移处理的实践。结果表明本文相关模型具可操作性和实用价值。  相似文献   

2.
王冬  张墨起  张媛  刘雷 《海洋测绘》2013,33(1):46-48
基于余水位的配置模型,通过潮汐调和分析,利用已知长期验潮站余水位结合临近短期验潮站天文潮位来恢复短期站的实际水位,并对其进行误差分析,证明基于余水位进行推算未知验潮站潮位的可行性与实用性。为了保证验潮仪采集数据的精确度,基于日(月)平均海面在较大的空间尺度内有较强的相关性这一原理,对短期验潮站验潮仪零点漂移进行检测,并对其进行误差分析。  相似文献   

3.
考虑到利用中数法计算的日平均海面可能残留较多的短周期分潮影响,会给验潮站零点的漂移检测及修订引入一项潜在的系统差,进而影响到潮汐分析及水深测量水位改正等应用。提出了基于Godin法计算日平均海面的验潮站零点漂移检测及修正的改进方法。应用结果表明Godin法较中数法可明显削弱短周期分潮影响,从而可提高验潮站零点漂移检测及修订的精度。  相似文献   

4.
验潮井的褒贬之说1引言常规的浮子式验潮仪采用一种验潮井减小海面波的影响。该验潮仪目前仍是潮汐测量的主要仪器,在某些地区仍继续用它监测平均海平面以研究气候的变化和海平面变化的趋势。尽管如此,长期以来,验潮井一直受着它自身的内部困扰,包括非线性响应在内。...  相似文献   

5.
针对沿岸验潮站点布局密度不够的问题,使用压力式验潮仪对遮浪站附近海域进行潮汐应急观测,对实验数据进行了回归分析处理,并计算了实验数据的误差和相关系数。结果表明,台风灾害过程中,压力式验潮仪具有良好的稳定性,压力式验潮仪潮位与实际潮位的数据曲线基本吻合,两者的相关系数均在0.99以上;此外,压力式验潮仪潮位误差绝对值均小于5 cm,反应了压力式验潮仪潮位数据能较好地反应台风灾害过程中实际潮位的变化,表明使用压力式验潮仪开展潮汐观测工作具备良好的可行性。  相似文献   

6.
通过对两台TideMaster验潮仪实际观测数据的分析,验证了该验潮仪能够达到标称测量精度,且其观测值的中误差优于0.5mm。与人工水尺验潮数据相比较,结果表明,TideMaster验潮仪的测量灵敏度及效率更高,并对使用过程中影响测深精度的因素以及消弱误差的方法进行分析。  相似文献   

7.
为实现多频多模GNSS浮标在远距离海洋潮汐测量中的应用,基于精密单点定位(precision pointing positioning,PPP)数据处理策略获取潮位信息,以压力验潮仪为参考,对GNSS浮标测量海面高进行经验模态分解(empirical mode decomposition,EMD),滤去高频波浪和噪声,获取潮位进行精度分析。结果表明:多系统可以提高PPP解算潮位精度。GPS/GLONASS双系统和GPS/GLONASS/Bei Dou三系统PPP提取潮位与验潮仪潮位差值的最大误差均小于18cm,RMSE小于6. 5cm。因此,多系统PPP解算GNSS浮标海面高可以实现远离海岸的潮位获取与监测,能够提高海上潮位测量的效率。  相似文献   

8.
压力式验潮仪的精密基准控制1引言目前,世界上使用了不同类型的验潮仪,包括传统的浮子式和验潮井式验潮(Noye,1974年;IOC,1985年;Pugh,1987年)、声学验潮仪(Gill和Mero,1990年)以及测量次表面压力的验潮仪(Pugh,1...  相似文献   

9.
使用压力式TGR-2050型验潮仪,在珠江口等河道入海口测量潮汐时,误差比较大;针对珠江口潮汐的特点,分析和研究了大气压扰动、潮流、海水密度、压力感应零点漂移等因素对潮汐测量带来的误差,有针对性地提出解决方案,并通过实验证明了方案的可行性。  相似文献   

10.
压力式验潮仪获取的数据需要经过单位换算、气压改正、密度改正等数据处理才能转化为潮位数据,在数据处理过程中容易因某一环节的疏漏而造成结果不准确。梳理了压力式验潮仪在数据处理过程中应该注意的几个问题,推荐了一种压力式验潮仪数据处理的流程,为压力式验潮仪的正确使用提供了很好的建议。  相似文献   

11.
Tide gauges distributed all over the world provide valuable information for monitoring mean sea level changes. The statistical models used in estimating sea level change from the tide gauge data assume implicitly that the random model components are stationary in variance. We show that for a large number of global tide gauge data this is not the case for the seasonal part using a variate-differencing algorithm. This finding is important for assessing the reliability of the present estimates of mean sea level changes because nonstationarity of the data may have marked impact on the sea level rate estimates, especially, for the data from short records.  相似文献   

12.
H. B  kiiz  H. M. Ng 《Marine Geodesy》2005,28(3):209-217
Tide gauges distributed all over the world provide valuable information for monitoring mean sea level changes. The statistical models used in estimating sea level change from the tide gauge data assume implicitly that the random model components are stationary in variance. We show that for a large number of global tide gauge data this is not the case for the seasonal part using a variate-differencing algorithm. This finding is important for assessing the reliability of the present estimates of mean sea level changes because nonstationarity of the data may have marked impact on the sea level rate estimates, especially, for the data from short records.  相似文献   

13.
针对平均海平面的定义,分别介绍了利用验潮站资料和卫星高度计资料确立平均海平面的方法原理,并对2种方法的特性及存在的问题进行了比较阐述,确定了以沿岸长期验潮站为控制条件,对卫星测高数据确定的高分辨率高精度的平均海平面网格模型进行改正,最终构建平均海平面与国家大地坐标系关系的研究方法.  相似文献   

14.
Abstract

The 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   

15.
An attempt is made to infer the global mean sea level(GMSL) from a global tide gauge network and frame the problem in terms of the limitations of the network. The network,owing to its limited number of gauges and poor geographical distribution complicated further by unknown vertical land movements,is ill suited for measuring the GMSL. Yet it remains the only available source for deciphering the sea level rise over the last 100 a. The poor sampling characteristics of the tide gauge network have necessitated the usage of statistical inference. A linear optimal estimator based on the Gauss-Markov theorem seems well suited for the job. This still leaves a great deal of freedom in choosing the estimator. GMSL is poorly correlated with tide gauge measurements because the small uniform rise and fall of sea level are masked by the far larger regional signals. On the other hand,a regional mean sea level(RMSL) is much better correlated with the corresponding regional tide gauge measurements. Since the GMSL is simply the sum of RMSLs,the problem is transformed to one of estimating the RMSLs from regional tide gauge measurements. Specifically for the annual heating and cooling cycle,we separate the global ocean into 10-latitude bands and compute for each 10-latitude band the estimator that predicts its RMSL from tide gauges within. In the future,the statistical correlations are to be computed using satellite altimetry. However,as a first attempt,we have used numerical model outputs instead to isolate the problem so as not to get distracted by altimetry or tide gauge errors. That is,model outputs for sea level at tide gauge locations of the GLOSS network are taken as tide gauge measurements,and the RMSLs are computed from the model outputs. The results show an estimation error of approximately 2 mm versus an error of 2.7 cm if we simply average the tide gauge measurements to estimate the GMSL,caused by the much larger regional seasonal cycle and mesoscale variation plaguing the individual tide gauges. The numerical model,Los Alamos POP model Run 11 lasting 3 1/4 a,is one of the best eddy-resolving models and does a good job simulating the annual heating and cooling cycle,but it has no global or regional trend. Thus it has basically succeeded in estimating the seasonal cycle of the GMSL. This is still going to be the case even if we use the altimetry data because the RMSLs are dominated by the seasonal cycle in relatively short periods. For estimating the GMSL trend,longer records and low-pass filtering to isolate the statistical relations that are of interest. Here we have managed to avoid the much larger regional seasonal cycle plaguing individual tide gauges to get a fairly accurate estimate of the much smaller seasonal cycle in the GMSL so as to enhance the prospect of an accurate estimate of GMSL trend in short periods. One should reasonably expect to be able to do the same for longer periods during which tide gauges are plagued by much larger regional interannual(e. g.,ENSO events) and decadal sea level variations. In the future,with the availability of the satellite altimeter data,we could use the same approach adopted here to estimate the seasonal variations of GMSL and RMSL accurately and remove these seasonal variations accordingly so as to get a more accurate statistical inference between the tide gauge data and the RMSLs(therefore the GMSL) at periods longer than 1 a,i. e.,the long-term trend.  相似文献   

16.
This paper attempts to assess the use of Global Navigation Satellite System (GNSS) as an accurate, reliable, and easy tool for sea level measurement. The GNSS technique was incorporated into a float based tide gauge system. A prototype of such an instrument was developed based on principles of conventional tide gauges, where high frequency noise is reduced mechanically. The ability of the GNSS based tide gauge (GTG) to monitor sea levels was tested in several experiments. The performance of the GTG was compared to that of a traditional tide gauge. The method of data analysis and data comparison between the GPS measurements and the tide gauge data is presented. The results show that the GTG is equal in performance to the traditional float operated tide gauge. It seems that the GTG is capable of delivering the same level of accuracy (1 cm), and its results are as reliable as its competitor, the traditional float tide gauge. The suggested instrument can be easily integrated into the array of permanent GNSS stations and assist in absolute measurements of sea level changes, caused by global warming and the greenhouse effect, for example.  相似文献   

17.
This paper attempts to assess the use of Global Navigation Satellite System (GNSS) as an accurate, reliable, and easy tool for sea level measurement. The GNSS technique was incorporated into a float based tide gauge system. A prototype of such an instrument was developed based on principles of conventional tide gauges, where high frequency noise is reduced mechanically. The ability of the GNSS based tide gauge (GTG) to monitor sea levels was tested in several experiments. The performance of the GTG was compared to that of a traditional tide gauge. The method of data analysis and data comparison between the GPS measurements and the tide gauge data is presented. The results show that the GTG is equal in performance to the traditional float operated tide gauge. It seems that the GTG is capable of delivering the same level of accuracy (1 cm), and its results are as reliable as its competitor, the traditional float tide gauge. The suggested instrument can be easily integrated into the array of permanent GNSS stations and assist in absolute measurements of sea level changes, caused by global warming and the greenhouse effect, for example.  相似文献   

18.
Rabaul tide gauge records from 1968 through 1985 give the amount of vertical movement in the northern part of Rabaul Caldera. Monthly mean sea level data were compared with other regional tide gauge stations to remove large scale oceanographic effects. No large vertical movements (> 0.3 cm/yr) were noted in this portion of the caldera. The results of sea level measurements at other points around the caldera, from 1981 through 1983 are consistent with the 1 to 10 cm of uplift observed on Matupit Island from optical leveling surveys. There was relatively little vertical movement (~ 0.1 cm/yr) in the Vulcan area.  相似文献   

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