Enhanced Local Ionosphere Model for Multi-Constellations Single Frequency Precise Point Positioning Applications: Egyptian Case Study

IF 0.7 Q4 ASTRONOMY & ASTROPHYSICS
Emad El Manaily, M. Abd Rabbou, A. El-Shazly, M. Baraka
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引用次数: 2

Abstract

Abstract The positioning accuracy of single frequency precise point positioning (SFPPP) attributes mainly to the ionosphere error, which strongly affects GNSS signals. When GNSS signals pass through the various ionosphere layers, they will be bent and their speed will be changed due to dispersive nature of ionosphere. To correct the ionosphere error, it is common to use Klobuchar ionosphere model or Global Ionosphere Maps (GIM). However, Klobuchar can deal with only about 50% of the Ionosphere effect and global Ionosphere maps are often inadequate to describe detailed features of local ionosphere because of limited precision and resolution. In this paper, an enhanced local ionosphere model was developed relying on modeling of measurements from a dense Egyptian permanent tracking GNSS network in order to achieve high precision ionosphere delay correction. The performance of the developed enhanced Egyptian ionosphere model (EIM) was verified through multi-constellations SFPPP accuracy for static and kinematic modes. For static mode, 24 hours multi-constellations datasets collected at three selected stations, Alexandria, Cairo, and Aswan, in Egypt on February 27, 2017, to investigate the performance of the developed local ionospheric model in comparison with the Klobuchar, GIM and ionosphere free models. After session time of half an hour, the results show that the performance of static SFPPP based on the developed Egyptian ionospheric map (EIM) achieved a comparable accuracy WRT using ionosphere free model. While using EIM, achieved an improvements of (38%, 28%, and 42%) and (32%, 10%, and 37%) for accuracy of latitude, longitude, and altitude in comparison with using Klobuchar and GIM models, respectively For kinematic mode, datasets of 2 hours of observations with 1 second sampling rate were logged during vehicular test; the test was carried out on the ring road of the city of Cairo, Egypt, on September 16, 2017. After half an hour of kinematic SFPPP data-processing, the performance of using Egyptian ionospheric map (EIM) for ionosphere delay correction, achieved an improvements of three dimension coordinates of (83%, 47%, and 62%) and (57%, 65%, and 21%) with respect to using Klobuchar model and GIM model, respectively.
用于多星座单频精确点定位应用的增强型局部电离层模型:埃及案例研究
摘要单频精密点定位(SFPPP)的定位精度主要归因于电离层误差,电离层误差对GNSS信号有很大影响。当GNSS信号穿过不同的电离层层时,由于电离层的分散性,它们会发生弯曲,速度也会发生变化。为了校正电离层误差,通常使用Klobuchar电离层模型或全球电离层图(GIM)。然而,Klobuchar只能处理大约50%的电离层效应,并且由于精度和分辨率有限,全球电离层地图往往不足以描述局部电离层的详细特征。在本文中,为了实现高精度的电离层延迟校正,根据密集的埃及永久跟踪全球导航卫星系统网络的测量建模,开发了一个增强的本地电离层模型。通过多星座SFPPP静态和动态模式的精度验证了所开发的增强埃及电离层模型的性能。对于静态模式,2017年2月27日在埃及亚历山大、开罗和阿斯旺三个选定站点收集的24小时多星座数据集,以研究所开发的本地电离层模型与Klobuchar、GIM和无电离层模型相比的性能。在半小时的会话时间后,结果表明,基于开发的埃及电离层图(EIM)的静态SFPPP的性能在使用无电离层模型的情况下达到了相当的精度WRT。在使用EIM的同时,与使用Klobuchar和GIM模型相比,纬度、经度和海拔的精度分别提高了(38%、28%和42%)和(32%、10%和37%)。对于运动学模式,在车辆测试期间记录了2小时、1秒采样率的观测数据集;测试于2017年9月16日在埃及开罗市的环城公路上进行。经过半小时的运动学SFPPP数据处理,使用埃及电离层图(EIM)进行电离层延迟校正的性能,相对于使用Klobuchar模型和GIM模型,分别实现了(83%、47%和62%)和(57%、65%和21%)的三维坐标改进。
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CiteScore
1.00
自引率
11.10%
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