GNSS无差精密定位在国家参考系坐标确定中的应用

IF 0.7 Q4 ASTRONOMY & ASTROPHYSICS Artificial Satellites-Journal of Planetary Geodesy Pub Date : 2017-09-26 DOI:10.1515/arsa-2017-0006
G. Krzan, K. Stępniak
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引用次数: 1

摘要

摘要在使用GNSS的高精度定位中,最常见的解决方案仍然是使用双频测量的双差观测进行相对定位。相对定位的一种越来越流行的替代方法是无差分方法,这种方法旨在充分利用现代卫星系统和信号。从精确点定位(PPP)或无差分(UD)网络解决方案获得的参考全球国际陆地参考系(ITRF2008)的位置必须转换为国家(地区)参考系,这引入了与转换过程相关的额外基础。本文处理了两个测试网络使用不同观测时间序列的卫星观测结果。第一次测试涉及使用NAPEOS 3.3.1软件处理14个EUREF永久网络(EPN)站一年双频GPS观测结果的定位精度。将结果转换到国家参考系(PL-ETRF2000)中,并将其与EPN累积解中的位置进行比较,该累积解被用作真实坐标。使用PPP和UD多站解决方案处理日常观测,以确定卫星定位、向国家坐标系的转换和欧亚板块内速度产生的最终精度。第二次数值测试涉及使用不同观测时间序列(每天30分钟、1小时、2小时)和不同类别的全球导航卫星系统接收器进行的类似后处理策略。在国家坐标系中显示的结果的厘米精度满足了许多测量和工程应用的要求。
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Application of the Undifferenced GNSS Precise Positioning in Determining Coordinates in National Reference Frames
Abstract In high-accuracy positioning using GNSS, the most common solution is still relative positioning using double-difference observations of dual-frequency measurements. An increasingly popular alternative to relative positioning are undifferenced approaches, which are designed to make full use of modern satellite systems and signals. Positions referenced to global International Terrestrial Reference Frame (ITRF2008) obtained from Precise Point Positioning (PPP) or Undifferenced (UD) network solutions have to be transformed to national (regional) reference frame, which introduces additional bases related to the transformation process. In this paper, satellite observations from two test networks using different observation time series were processed. The first test concerns the positioning accuracy from processing one year of dual-frequency GPS observations from 14 EUREF Permanent Network (EPN) stations using NAPEOS 3.3.1 software. The results were transformed into a national reference frame (PL-ETRF2000) and compared to positions from an EPN cumulative solution, which was adopted as the true coordinates. Daily observations were processed using PPP and UD multi-station solutions to determine the final accuracy resulting from satellite positioning, the transformation to national coordinate systems and Eurasian intraplate plate velocities. The second numerical test involved similar processing strategies of post-processing carried out using different observation time series (30 min., 1 hour, 2 hours, daily) and different classes of GNSS receivers. The centimeter accuracy of results presented in the national coordinate system satisfies the requirements of many surveying and engineering applications.
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