Behavior of Broadcast Ionospheric-Delay Models from GPS, Beidou, and Galileo Systems

IF 0.7 Q4 ASTRONOMY & ASTROPHYSICS

Artificial Satellites-Journal of Planetary Geodesy Pub Date : 2020-06-01 DOI:10.2478/arsa-2020-0005

A. Farah

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引用次数: 3

Abstract

Abstract The GNSS observations suffer from different types of errors that could affect the achieved positioning accuracy based on the receiver type used. Single-frequency receivers are widely used worldwide because of its low cost. The ionospheric delay considers the most challenging error for single-frequency GNSS observations. All satellite navigation systems, except GLONASS, are advising their users to correct for the ionospheric delay using a certain model. Those models’ coefficients are sent to users in the system’s navigation message. These models are different in their accuracy and behavior based on its foundation theory as well as the updating rate of their coefficients. The GPS uses Klobuchar model for mitigating the ionospheric delay. BeiDou system (BDS-2) adopts a slightly modified Klobuchar model that resembles GPS ICA (Ionospheric Correction Algorithm) with eight correction parameters but is formulated in a geographic coordinate system with different coefficients in origin and updating rate. Galileo system uses a different model (NeQuick model). This article investigates the behavior of the three models in correcting the ionospheric delay for three stations at different latitudes during 3 months of different states of ionospheric activity, comparing with International GNSS Service-Global Ionospheric Maps (IGS-GIMs). It is advised from this research’s outputs to use the GPS model for mitigating the ionospheric delay in low-latitude regions during the state of low-and medium-activity ionosphere. It is advised to use the BeiDou model for mitigating the ionospheric delay in mid-latitude regions during different states of ionospheric activity. It is advised to use the Galileo model for mitigating the ionospheric delay in high-latitude regions during different states of ionospheric activity. Also, the Galileo model is recommended for mitigating the ionospheric delay for low-latitude regions during the state of high-activity ionosphere.

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来自GPS、北斗和伽利略系统的广播电离层延迟模型的行为

根据不同的接收机类型，GNSS观测值存在不同类型的误差，这些误差会影响GNSS的定位精度。单频接收机因其成本低而在世界范围内得到广泛应用。电离层延迟是单频GNSS观测中最具挑战性的误差。除了GLONASS之外，所有的卫星导航系统都建议用户使用特定的模型来校正电离层延迟。这些模型的系数通过系统的导航消息发送给用户。这些模型基于其基础理论和其系数的更新速度，在精度和行为上存在差异。GPS采用Klobuchar模型减轻电离层延迟。北斗系统(BDS-2)采用稍作修改的Klobuchar模型，该模型类似于GPS ICA (Ionospheric Correction Algorithm，电离层校正算法)，具有8个校正参数，但在不同原点系数和更新速率的地理坐标系中制定。伽利略系统使用不同的模型(NeQuick模型)。本文通过与国际GNSS服务-全球电离层地图(IGS-GIMs)的比较，研究了三种模式在不同电离层活动状态下3个月不同纬度3个站点电离层延迟校正的行为。从本研究的结果来看，建议在电离层低活动和中活动状态下，使用GPS模型来减轻低纬度地区电离层延迟。建议在电离层活动的不同状态下，使用北斗模型来减轻中纬度地区电离层的延迟。在电离层活动的不同状态下，建议使用伽利略模式来减轻高纬度地区电离层的延迟。此外，在电离层高活跃状态下，伽利略模式可用于降低低纬度地区的电离层延迟。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Artificial Satellites-Journal of Planetary Geodesy ASTRONOMY & ASTROPHYSICS-

CiteScore

1.00

自引率

11.10%

发文量