使用混合GPS/Gronass单频观测的运动学PPP

IF 0.7 Q4 ASTRONOMY & ASTROPHYSICS
Mostafa Hamed, A. Abdallah, A. Farah
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引用次数: 4

摘要

摘要目前,精确点定位(PPP)是一种非常流行的全球导航卫星系统(GNSS)定位技术。与差分技术相比,PPP的优点是成本低,并且没有距离限制。与昂贵的双频接收机相比,单频接收机具有成本效益的优势,但电离层误差使其难以完全缓解。本研究旨在评估使用GPS和GLONASS星座的观测结果与使用单频观测仅用于运动学目的的GPS相比的效果。2018年的六天,埃塞俄比亚IGS站名为“ADIS”的单频数据被逐历元处理了24小时,一次仅使用GPS观测,另一次使用GPS/GLONASS观测。除了“ADIS”站外,还使用Leica GS15观测了埃及阿斯旺新阿斯旺市的一条运动学轨道,该轨道采用大地测量型双频GPS/GLONASS全球导航卫星系统接收器,并处理了单频数据。Net_Diff软件用于处理所有数据。将结果与参考溶液进行了比较。添加GLONASS卫星显著提高了卫星数量和位置精度稀释值,从而提高了定位精度。在“ADIS”数据的情况下,仅GPS的三维均方根误差(RMSE)范围在0.273至0.816 m之间,而GPS/GLONASS在处理的6天内提高到0.256至0.550 m之间。东部、北部、高度和3D位置分量的平均改善率分别为24%、29%、30%和29%。对于运动学轨迹,3D位置RMSE从仅GPS的0.733米提高到GPS/GLONASS的0.638米。运动学轨迹数据的东部、北部、高度和三维位置分量的改善率分别为7%、5%、28%和13%。这为增加其他两个星座(伽利略和北斗)的观测开辟了道路,以在未来的研究中获得更高的准确性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Kinematic PPP Using Mixed GPS/Glonass Single-Frequency Observations
Abstract Nowadays, Precise Point Positioning (PPP) is a very popular technique for Global Navigation Satellite System (GNSS) positioning. The advantage of PPP is its low cost as well as no distance limitation when compared with the differential technique. Single-frequency receivers have the advantage of cost effectiveness when compared with the expensive dual-frequency receivers, but the ionosphere error makes a difficulty to be completely mitigated. This research aims to assess the effect of using observations from both GPS and GLONASS constellations in comparison with GPS only for kinematic purposes using single-frequency observations. Six days of the year 2018 with single-frequency data for the Ethiopian IGS station named “ADIS” were processed epoch by epoch for 24 hours once with GPS-only observations and another with GPS/GLONASS observations. In addition to “ADIS” station, a kinematic track in the New Aswan City, Aswan, Egypt, has been observed using Leica GS15, geodetic type, dual-frequency, GPS/GLONASS GNSS receiver and single-frequency data have been processed. Net_Diff software was used for processing all the data. The results have been compared with a reference solution. Adding GLONASS satellites significantly improved the satellite number and Position Dilution Of Precision (PDOP) value and accordingly improved the accuracy of positioning. In the case of “ADIS” data, the 3D Root Mean Square Error (RMSE) ranged between 0.273 and 0.816 m for GPS only and improved to a range from 0.256 to 0.550 m for GPS/GLONASS for the 6 processed days. An average improvement ratio of 24%, 29%, 30%, and 29% in the east, north, height, and 3D position components, respectively, was achieved. For the kinematic trajectory, the 3D position RMSE improved from 0.733 m for GPS only to 0.638 m for GPS/GLONASS. The improvement ratios were 7%, 5%, 28%, and 13% in the east, north, height, and 3D position components, respectively, for the kinematic trajectory data. This opens the way to add observations from the other two constellations (Galileo and BeiDou) for more accuracy in future research.
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