Homogenizing coordinates through the use of the active CORS in Ghana

IF 0.3 Q4 REMOTE SENSING South African Journal of Geomatics Pub Date : 2023-08-07 DOI:10.4314/sajg.v12i.2.2
Osman Mohammed Abukari, Akwasi Afrifa Acheampong, Samuel Osah, John Ayer
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Abstract

In this study, the course towards determining the homogeneous three-dimensional (3D) coordinates of the newly established active Continuously Operating Reference Station (CORS), based on ITRF2014 in Ghana, is revealed. The aim is to address coordinate inconsistencies and inhomogeneity in the published positions of the new active CORS in Ghana. In order to attain homogeneity, the coordinates of two primary control points, GCS 305 and GCS 306, were obtained using AUSPOS online services via email. These were subsequently used as reference stations to compute the position of the LISAG_KUMASI CORS. Adjustments to the position coordinates were performed using Topcon Tools v8.2.3 software at a 1mm standard deviation. The adjusted coordinates of LISAG_KUMASI were used as the reference points to compute the positions of the LiSAGNet CORS in differential mode by using 24 hour data for 11 consecutive days. The GPS data covered DoY 284 to DoY 295 in 2021. The final positions of the CORS, computed by this approach, indicate some differences from the officially published coordinates of the same CORS, confirming the suspicion of inhomogeneity in the source coordinates used in determining the coordinates of the local CORS. Furthermore, a test network, consisting of five COR stations, was designed and used to address the coordinate inconsistencies in the officially published coordinates. Using the officially published coordinates as reference inputs, the ROVER I station was fixed by three different CORSs, thus resulting in average coordinate variabilities of 2.78m and 0.80m in the northing (N) and easting (E) directions, respectively. Through substitution, the coordinates computed in this study as reference inputs, namely, the ROVER I station, were fixed by the same three CORSs, thus resulting in a coordinate variability of 0.002m and 0.006m in the northing (N) and easting (E) directions, respectively. The analysis revealed inconsistencies and inhomogeneity in terms of the officially published coordinates. It is, therefore, recommended that the officially published coordinates of the CORS be replaced by the adjusted homogeneous and consistent values determined through the approach adopted in this study.
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在加纳通过使用主动CORS使坐标均匀化
在本研究中,揭示了基于ITRF2014在加纳新建立的主动连续运行参考站(CORS)的均匀三维(3D)坐标确定过程。其目的是解决加纳新活跃的CORS公布立场的协调不一致和不均匀性。为了达到均匀性,两个主要控制点gcs305和gcs306的坐标通过AUSPOS在线服务通过电子邮件获得。这些随后被用作计算LISAG_KUMASI CORS位置的参考站。使用Topcon Tools v8.2.3软件以1mm的标准差对位置坐标进行调整。以LISAG_KUMASI调整后的坐标为参考点,利用连续11天的24小时数据,计算LiSAGNet CORS在差分模式下的位置。GPS数据覆盖2021年284年至295年。用这种方法计算出的CORS的最终位置与官方公布的同一CORS的坐标有些不同,证实了在确定当地CORS坐标时所使用的源坐标不均匀性的怀疑。此外,设计了一个由5个COR站组成的测试网,用于解决官方公布的坐标不一致的问题。以官方公布的坐标作为参考输入,ROVER I站由3个不同的CORSs固定,得到北(N)和东(E)方向的平均坐标变化分别为2.78m和0.80m。通过代入,本研究计算的坐标作为参考输入,即ROVER I站,被相同的三个CORSs固定,从而在北(N)方向和东(E)方向分别产生0.002m和0.006m的坐标变率。分析显示官方公布的坐标不一致和不均匀。因此,建议将正式公布的CORS坐标替换为通过本研究采用的方法确定的调整后的均匀一致值。
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