海底大地测量控制网研究进展综述

doi:10.13474/j.cnki.11-2246.2018.0002

测绘通报 ›› 2018, Vol. 0 ›› Issue (1): 8-13,87.doi: 10.13474/j.cnki.11-2246.2018.0002

海底大地测量控制网研究进展综述

李林阳¹, 吕志平¹, 崔阳²

1. 信息工程大学地理空间信息学院, 河南郑州 450001;
2. 后勤工程学院, 重庆 401331

收稿日期:2017-04-04 出版日期:2018-01-25 发布日期:2018-02-05
作者简介:李林阳(1991-),男,博士生,主要从事测量数据处理理论与方法。E-mail:lilinyang810810@163.com
基金资助:
海洋大地基准建立理论与方法（2016YFB0501701）

Summary of the Research Progress of Seafloor Geodetic Control Network

LI Linyang¹, LÜ Zhiping¹, CUI Yang²

1. School of Surveying and Mapping, Information Engineering University, Zhengzhou 450001, China;
2. Logistical Engineering University, Chongqing 401331, China

Received:2017-04-04 Online:2018-01-25 Published:2018-02-05

摘要/Abstract

摘要：

高精度的海底大地测量控制网是数字海洋和水下网络中心战的基础设施之一，而现阶段我国海底控制网的建设和研究几乎为空白。为自主建立我国高精度的海底大地测量控制网，本文借鉴发达国家的经验，结合国外海底控制网的发展与研究现状，系统介绍了GNSS/Acoustic系统的组成及发展；详细梳理了数据处理中的关键技术，分析了影响海底控制点精度的因素和控制点定位精度；结合我国现状，建议加紧开展我国海底控制网的建设与研究。

关键词: 全球卫星导航系统, 声学定位, 海底控制网

Abstract:

The high-precision seafloor geodetic control network is one of the infrastructures of digital ocean and underwater network centric warfare. However, the construction and research of seafloor control network at present is almost blank in China. To autonomously establish high-precision seafloor geodetic control network, this paper draws on the experience of the developed countries. Firstly, the development and current situation of the foreign seafloor control network are combined, and the composition and development of GNSS/Acoustic system are introduced systematically.Then the key technologies of data processing are studied in detail, the factors that affect the positioning accuracy of seafloor control point and its positioning accuracy are analyzed.Finally, taking the present situation in our country into account, immediate steps should be taken to speed up the construction and research of the seafloor control network.

Key words: GNSS, acoustic positioning, seafloor control network

中图分类号:

P229.2

李林阳, 吕志平, 崔阳. 海底大地测量控制网研究进展综述[J]. 测绘通报, 2018, 0(1): 8-13,87.

LI Linyang, LÜ Zhiping, CUI Yang. Summary of the Research Progress of Seafloor Geodetic Control Network[J]. 测绘通报, 2018, 0(1): 8-13,87.

参考文献

[1] 杨元喜, 徐天河, 薛树强. 我国海洋大地测量基准与海洋导航技术研究进展与展望[J]. 测绘学报, 2017, 46(1):1-8.
[2] SHIMAMURA H, KANAZAWA T. Ocean Bottom Tiltmeter with Acoustic Data Retrieval System Implanted by a Submersible[J]. Marine Geophysical Research, 1988, 9(3):237-254.
[3] YAMADA T, ANDO M, TADOKORO K, et al. Error Evaluation in Acoustic Positioning of a Single Transponder for Seafloor Crustal Deformation Measurements[J]. Earth Planets and Space, 2002, 54(9):871-881.
[4] BALLU V, BOUIN M N, CALMANT S, et al. Absolute Seafloor Vertical Positioning Using Combined Pressure Gauge and Kinematic GPS Data[J]. Journal of Geodesy, 2010, 84(1):65-77.
[5] MIKHAILOV V, TIKHOTSKY S, DIAMENT M, et al. Can Tectonic Processes be Recovered from New Gravity Satellite Data?[J]. Earth & Planetary Science Letters, 2004, 228(3-4):281-297.
[6] CHEN J L, WILSON C R, TAPLEY B D, et al. GRACE Detects Coseismic and Postseismic Deformation from the Sumatra-Andaman Earthquake[J]. Geophysical Research Letters, 2007, 34(13):173-180.
[7] SPIESS F N. Analysis of a Possible Sea Floor Strain Mea-surement System[J]. Marine Geodesy, 1985, 9(4):385-398.
[8] GAGNON K, CHADWELL C D, NORABUENA E. Mea-suring the Onset of Locking in the Peru-Chile Trench with GPS and Acoustic Measurements[J]. Nature, 2005, 434(7030):205.
[9] NISHIMURA T, SATO M, SAGIYA T. Global Positioning System (GPS) and GPS-Acoustic Observations:Insight into Slip along the Subduction Zones around Japan[J]. Annual Review of Earth & Planetary Sciences, 2014, 42(1):653-674.
[10] KIDO M, FUJIMOTO H, MIURA S, et al. Seafloor Displacement at Kumano-nada Caused by the 2004 Off Kii Peninsula Earthquakes, Detected through Repeated GPS/Acoustic Surveys[J]. Earth Plans and Space, 2006, 58(7):911-915.
[11] MATSUMOTO Y, FUJITA M, ISHIKAWA T, et al. Undersea Co-seismic Crustal Movements Associated with the 2005 Off Miyagi Prefecture Earthquake Detected by GPS/acoustic Seafloor Geodetic Observation[J]. Earth Planets and Space, 2006, 58(12):1573-1576.
[12] WATANABE S I, ISHIKAWA T, YOKOTA Y. Non-volcanic Crustal Movements of the Northernmost Philippine Sea Plate Detected by the GPS-acoustic Seafloor Positioning[J]. Earth Planets and Space, 2015, 67(1):184.
[13] ROCKEN C, KELECY T M, BORN G H, et al. Measuring Precise Sea Level from a Buoy Using the Global Positioning System[J]. Geophysical Research Letlers, 1990, 17(12):2145-2148.
[14] PURCELL Jr G H, YOUNG L E, WOLF S K, et al. Accurate GPS Measurement of the Location and Orientation of a Floating Platform[J]. Marine Geodesy, 1990, 14(3-4):225-264.
[15] SPIESS F N, CHADWELL C D, HILDEBRAND J A, et al. Precise GPS/Acoustic Positioning of Seafloor Reference Points for Tectonic Studies[J]. Physics of the Earth & Planetary Interiors, 1998, 108(2):101-112.
[16] CHADWELL C D, SPIESS F N, HILDEBRAND J A, et al. Deep-sea Geodesy:Monitoring the Ocean Floor[J]. GPS World, 1998, 9(9):45-55.
[17] CHADWELL C D. Shipboard Towers for Global Positioning System Antennas[J]. Ocean Engineering, 2003, 30(12):1467-1487.
[18] SPIESS F N, BOEGEMAN D E, PAVLICEK F V, et al. Precision Transponder and Method of Communicating Therewith:US, US4214314[P]. 1980-08-07.
[19] NATIONAL RESEARCH COUNCIL (US). Panel on Ocean Bottom Positioning. Seafloor Referenced Positioning:Needs and Opportunities[M]. Washington D.C.:National Academies Press, 1983.
[20] OBANA K, KATAO H, ANDO M. Seafloor Positioning System with GPS-acoustic Link for Crustal Dynamics Observation——A Preliminary Result from Experiments in the Sea[J]. Earth Planets and Space, 2000, 52(6):415-423.
[21] TADOKORO K, ANDO M, SATO K, et al. Development of an Observation System for Ocean Bottom Crustal Deformation Using an Acoustic Ranging-GPS Link[J]. Journal of Geography, 2009, 110:521-528.
[22] ASADA A, YABUKI T. Centimeter-level Positioning on the Seafloor[J]. Proceedings of the Japan Academy, 2001, 77(1):7-12.
[23] SATO M, FUJITA M, MATSUMOTO Y, et al. Improvement of GPS/Acoustic Seafloor Positioning Precision through Controlling the Ship's Track Line[J]. Journal of Geodesy, 2013, 87(9):825-842.
[24] HAN S. Carrier Phase-based Long-range GPS Kinematic Positioning[M].[S.l.]:University of New South Wales,1997.
[25] ZOU X, GE M, TANG W, et al. URTK:Undifferenced Network RTK Positioning[J]. GPS Solutions, 2013, 17(3):283-293.
[26] GENG J, TEFERLE F N, MENG X, et al. Kinematic Precise Point Positioning at Remote Marine Platforms[J]. GPS Solutions, 2010, 14(4):343-350.
[27] GROSSO V A D. New Equation for the Speed of Sound in Natural Waters (with Comparisons to Other Equations)[J]. Journal of the Acoustical Society of America, 1974, 56(4):1084-1091.
[28] MACKENZIE K V. Nine-term Equation for Sound Speed in the Oceans[J]. Journal of the Acoustical Society of America, 1981, 70(3):807-812.
[29] JACKSON D D. The Use of a Priori Data to Resolve Non-uniqueness in Linear Inversion[J]. Geophysical Journal International, 1979, 57(1):137-157.
[30] FUJITA M, ISHIKAWA T, MOCHIZUKI M, et al. GPS/Acoustic Seafloor Geodetic Observation:Method of Data Analysis and Its Application[J]. Earth Planets and Space, 2006, 58(3):265-275.
[31] OSADA Y, FUJIMOTO H, MIURA S, et al. Estimation and Correction for the Effect of Sound Velocity Variation on GPS/Acoustic Seafloor Positioning:An Experiment off Hawaii Island[J]. Earth Planets and Space, 2003, 55(10):17-20.
[32] 吕志平, 魏子卿, 李军, 等. 我国CGCS2000高精度坐标转换格网模型的建立[J]. 测绘学报, 2013, 42(6):791:797.
[33] 陈俊勇, 杨元喜, 王敏, 等. 2000国家大地控制网的构建和它的技术进步[J]. 测绘学报, 2007, 36(1):1-8.
[34] 刘焱雄, 彭琳, 吴永亭, 等. 超短基线水声定位系统校准方法研究[J]. 武汉大学学报(信息科学版), 2006, 31(7):610-612.
[35] 863计划"水下GPS高精度定位系统"课题组. 我国首套水下GPS高精度定位导航系统简介[J]. 中国水利, 2004(3):52-53.
[36] 吴永亭, 周兴华, 杨龙. 水下声学定位系统及其应用[J]. 海洋测绘, 2003, 23(4):18-21.
[37] 宁津生, 吴永亭, 孙大军. 长基线声学定位系统发展现状及其应用[J]. 海洋测绘, 2014, 34(1):72-75.
[38] 蔡艳辉. 差分GPS水下定位系统集成关键技术研究[D]. 阜新:辽宁工程技术大学, 2007.

海底大地测量控制网研究进展综述

Summary of the Research Progress of Seafloor Geodetic Control Network

PDF

可视化

被引次数

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 6

编辑推荐

Metrics

本文评价

[1]	熊常亮, 贺小星, 马下平, 付杰. 联合LMD与EMD的GNSS站坐标时间序列去噪方法[J]. 测绘通报, 2022, 0(2): 78-82.
[2]	姜卫平, 郭迟, 左文炜. 我国导航与位置服务的进展及思考[J]. 测绘通报, 2020, 0(1): 1-4,25.
[3]	戴金倩, 吴迪, 戴小蕾, 楼益栋. BDS-3实时精密单点定位精度分析[J]. 测绘通报, 2020, 0(1): 30-34.
[4]	张元迪, 焦瑞莉, 朱云龙, 吴世玉. GNSS-R海面目标成像仿真方法研究[J]. 测绘通报, 2019, 0(2): 86-90,107.
[5]	邝英才, 吕志平, 蔡汶江, 王方超. GNSS/声学系统定位精度影响因素分析[J]. 测绘通报, 2018, 0(12): 15-20,45.
[6]	李林阳, 张学东, 黄娴, 李崇辉, 吕志平. 大规模GNSS网发展及数据处理现状[J]. 测绘通报, 2018, 0(10): 1-5.