泰国大地水准面模型2017 (TGM2017)的航空和地面重力测定

IF 0.8 4区 地球科学 Q4 GEOSCIENCES, MULTIDISCIPLINARY Terrestrial, Atmospheric and Oceanic Sciences Pub Date : 2021-01-01 DOI:10.3319/tao.2021.08.23.01
Puttipol Dumrongchai, Chawis Srimanee, Nuttanon Duangdee, Jittrakorn Bairaksa
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引用次数: 1

摘要

泰国皇家测量部和清迈大学开发了泰国大地水准面模型2017 (TGM2017),该模型具有1 ' × 1 '网格,以支持全球导航卫星系统(GNSS)椭球高度与Kolak-1915垂直基准正交高度之间的转换。TGM2017是基于泰国重力大地水准面模型2017 (thaai17g)和299 GNSS椭球高度与Kolak-1915高度共同定位的。用于大地水准面计算的所有地面重力数据都来自新的国家重力网,该网由87个绝对重力站和9929个相对重力站组成,每隔10 - 25公里,大部分与现有道路一起。2016 - 2017年,在4000米飞行高度和10公里航迹间距上开展了航空重力测量,获取了沿海和海洋等山地和人迹罕至地区的重力数据,估计精度为3.0 mGal。长波大地面线结构由GOCE-EGM2008联合模型(GECO)和丹麦技术大学全球海洋重力模型2013 (DTU13)控制。采用最小二乘配置和数字地形高程数据2 (DTED2)的残差地形模型约简,对所有重力数据进行组合和向下处理。通过多波段球面快速傅里叶变换确定THAI17G,并将其转换为TGM2017, 299个GNSS/水准点的均方根拟合(rms)为38.2cm,平均偏移量为37.0 cm。这个值表示Kolak-1915与全球平均海平面之间的距离。TGM2017在100个GNSS/水准检查点上的评估显示均方根值为4.9 cm,从而导致可靠的正测高度达到10 cm或更高的精度水平。
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The determination of Thailand Geoid Model 2017 (TGM2017) from airborne and terrestrial gravimetry
The Royal Thai Survey Department and Chiang Mai University developed the Thailand geoid model 2017 (TGM2017) with a 1’ × 1’ grid to support the transformation between Global Navigation satellite System (GNSS) ellipsoid heights and Kolak-1915 vertical datum orthometric heights. TGM2017 was based on Thailand gravimetric geoid model 2017 (THAI17G) and 299 GNSS ellipsoidal heights co-located with Kolak-1915 heights. All terrestrial gravity data used for geoid computation came from the new national gravity network, consisting of 87 absolute and 9929 relative gravity stations at 10 – 25 km intervals, mostly along with existing roads. From 2016 to 2017, airborne gravity surveys were conducted at a 4000m-flight altitude and 10 km along-track spacing to acquire the gravity data over mountainous and inaccessible areas, including coastal and marine areas, at an estimated accuracy of 3.0 mGal. Long-wavelength geoid structure was controlled by the GOCE-EGM2008 combined model (GECO) and the Technical University of Denmark’s global marine gravity model 2013 (DTU13). All gravity data were combined and downward, using least-squares collocation with the residual terrain model reductions from a digital terrain elevation data level 2 (DTED2). THAI17G was determined by multi-band spherical Fast Fourier Transform and converted to TGM2017 with the 38.2cm root-mean-square (rms) fit of 299 GNSS/leveling co-points and a mean offset of 37.0 cm. This value represents the separation between Kolak-1915 and a global mean sea level. The evaluation of TGM2017 at 100 GNSS/leveling checkpoints shows the rms of 4.9 cm, consequently leading to reliable orthometric heights at a 10-cm accuracy level or better.
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来源期刊
CiteScore
2.00
自引率
0.00%
发文量
29
审稿时长
4.5 months
期刊介绍: The major publication of the Chinese Geoscience Union (located in Taipei) since 1990, the journal of Terrestrial, Atmospheric and Oceanic Sciences (TAO) publishes bi-monthly scientific research articles, notes, correspondences and reviews in all disciplines of the Earth sciences. It is the amalgamation of the following journals: Papers in Meteorological Research (published by the Meteorological Society of the ROC) since Vol. 12, No. 2 Bulletin of Geophysics (published by the Institute of Geophysics, National Central University) since No. 27 Acta Oceanographica Taiwanica (published by the Institute of Oceanography, National Taiwan University) since Vol. 42.
期刊最新文献
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