通过不同GNSS测量技术的位置解的可重复性实现一致性

IF 0.3 Q4 REMOTE SENSING South African Journal of Geomatics Pub Date : 2022-09-01 DOI:10.4314/sajg.v11i2.8
Osman Mohammed Abukari, Akwasi Acheampong, I. Dadzie, S. Osah
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引用次数: 0

摘要

在这项研究中,我们通过三种不同的GNSS定位技术确定了加纳八个新的连续运行参考站(CORS)的三维位置坐标。CORS网络与ITRF14和War Office 1926基准相连的三种全球导航卫星系统定位技术包括:1)精确点定位(PPP);2) 使用基于ITRF14的参考站的精密差分全球导航卫星系统;以及3)PDGNSS,使用基于War Office的参考站。PPP解决方案是使用加拿大空间参考系统精确点定位软件(CSRS-PPP)计算的,该软件可在线获得,并作为开源GNSS实验室工具软件(gLAB)。PDGNSS解决方案来自OPUS和AUSPOS在线服务,以及使用Topcon Tools软件v8.2.3的自后期处理。使用2018年10月连续12天的24小时数据计算所有解决方案(GPS DoY 284至GPS DoY 295)。位置解的质量、可靠性和可接受性是通过计算解的平均定位误差、模糊度分辨率和重复性比率来衡量的。计算每对不同定位技术的坐标差的可变性,以确定其解的一致性。最终,北距、东距和高度的平均定位误差分别为0.003米、0.005米和0.009米。歧义消解率为75.3%~90.3%,重复率为1:68500000~1:411100000。最后,每对定位技术的坐标差变化的最小和最大范围是水平位置为1mm至16mm,垂直位置为2mm至137mm。
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Congruence through repeatability of position solutions by different GNSS survey techniques
In this study, we determined three-dimensional (3D) position coordinates for eight new Continuous Operating Reference Stations (CORS) in Ghana through three different GNSS positioning techniques. The three GNSS positioning techniques whereby the network of CORS was tied to ITRF14 and War Office 1926 datums included:1) Precise Point Positioning (PPP); 2) Precise Differential GNSS (PDGNSS), using reference stations based on ITRF14; and 3) PDGNSS, using reference stations based on War Office. The PPP solutions were computed using the Canadian Spatial Reference System Precise Point Positioning software (CSRS-PPP), available online and as an open source GNSS laboratory tool software (gLAB). The PDGNSS solutions were obtained from OPUS and AUSPOS online services, as well as from self-post-processing using Topcon Tools software v8.2.3. All solutions were computed using 24-hour data for twelve consecutive days in the month of October 2018 (GPS DoY 284 to GPS DoY 295). The quality, reliability, and acceptability of position solutions were measured by computing the average positioning error, the rate of ambiguity resolution and the repeatability ratios of the solutions. The variability of coordinate differences for each pair of different positioning techniques was computed to determine their solution congruences. Ultimately, , the average positioning errors in northing, easting, and height were 0.003m, 0.005m and 0.009m, respectively. The rate of ambiguity resolution was between 75.3% and 90.3%. Repeatability ratios ranged between 1: 68,500,000 and 1: 411,100,000. Finally, the minimum and maximum range of variability in coordinate differences for each pair of positioning techniques was 1mm to 16mm for horizontal positions and 2mm to 137mm for vertical positions.
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