删除或更新信息,请邮件至freekaoyan#163.com(#换成@)

基于单站多系统的GNSS硬件延迟估算方法及其应用

本站小编 Free考研考试/2022-01-03

熊波1,2,4,5,,
李肖霖1,
万卫星2,3,4,5,
佘承莉2,4,5,
胡连欢2,4,5,
丁锋2,3,4,5,
赵必强2,3,4,5
1. 华北电力大学数理学院, 河北保定 071003
2. 中国科学院地质与地球物理研究所, 中国科学院地球与行星物理重点实验室, 北京 100029
3. 中国科学院大学地球与行星科学学院, 北京 100049
4. 中国科学院地球科学研究院, 北京 100029
5. 北京空间环境国家野外科学观测研究站, 北京 100029

基金项目: 国家自然科学基金(41574151,41574162和41404127),中央高校基本科研业务费专项资金(2018MS128和2016MS94)和国家高技术研究发展计划(863计划,2014AA123503)项目,中国科学院"十三五"信息化建设专项(XXH13505-04)联合资助


详细信息
作者简介: 熊波, 男, 1979年生, 副教授, 主要从事GNSS-TEC的反演与电离层太阳耀斑效应方面的研究.E-mail:xiongbo@mail.iggcas.ac.cn
中图分类号: P352

收稿日期:2018-05-25
修回日期:2019-02-22
上线日期:2019-04-05



A method for estimating GNSS instrumental biases and its application based on a receiver of multisystem

XIONG Bo1,2,4,5,,
LI XiaoLin1,
WAN WeiXing2,3,4,5,
SHE ChengLi2,4,5,
HU LianHuan2,4,5,
DING Feng2,3,4,5,
ZHAO BiQiang2,3,4,5
1. School of Mathematics and Physics, North China Electric Power University, Baoding Hebei 071003, China
2. Key Laboratory of Earth and Planetary Physics, Institute of Geology and Geophysics, Chinese Academy of Sciences, Beijing 100029, China
3. College of Earth and Planetary Sciences, University of Chinese Academy of Sciences, Beijing 100049, China
4. Institutions of Earth Science, Chinese Academy of Sciences, Beijing 100029, China
5. Beijing National Observatory for Space Environment, Beijing 100029, China


MSC: P352

--> Received Date: 25 May 2018
Revised Date: 22 February 2019
Available Online: 05 April 2019


摘要
随着全球导航卫星系统(Global Navigation Satellite Systems,GNSS)的不断发展,中国地区单个GNSS接收站在一个时刻可以接收到超过30颗GNSS卫星的信号,这为单站GNSS硬件延迟估算方法的研究提供了有利条件.本文首先通过GNSS硬件实验,分析了不同温度条件下GNSS系统硬件延迟的变化特征,研究结果显示:当温度快速变化时,硬件延迟变化比较剧烈,变化幅度可达12.53 TECU(1 TECU=10 16el·m-2);在恒温条件或室温条件下,硬件延迟变化比较缓慢,变化幅度在1.00 TECU左右.在GNSS系统硬件延迟实验的基础上,充分利用单站多星观测的特点,提出了一种基于单站多系统的GNSS硬件延迟的估算方法——单站三角分解与差分消元法,并将该方法应用于河北保定站2015-2017年GNSS系统硬件延迟的求解中.通过对估算的GNSS系统硬件延迟进行分析显示:单站三角分解与差分消元法具有计算速度快、独立性好的特点;在北斗系统上硬件延迟的求解效果优于GPS、GLONASS系统,硬件延迟求解的结果整体上比利用欧洲定轨中心全球电离层地图校正的结果大2.50~3.00TECU左右;同时,该方法在消除GNSS系统硬件延迟后,获得的垂直总电子含量(Total Electron Content,TEC)能较好地反映电离层TEC的周日变化、日出增强、半年变化、年变化和春秋分不对称性等特征.
GNSS/
硬件延迟/
电离层/
TEC

With the development of Global Navigation Satellite Systems (GNSS), the signal from more than 30 satellites of GNSS can be caught by a receiver in China at a time, which will provide conveniences for estimating instrumental biases of GNSS system. In this paper, instrumental biases of GNSS system have been firstly analyzed under different temperature conditions. The results show that instrumental biases are changed with the rapid change of temperature and the variation of instrumental biases can reach 12.53 total electron content unit (TECU, 1 TECU=1016el·m-2). Furthermore, the change of instrumental biases is slow and about 1.00 TECU under constant or room temperature. Based on the above experiments of instrumental biases, we have proposed a method of estimating GNSS instrumental biases for a receiver of multisystem. The method is named Triangle Decomposition and Difference Elimination (TDDE) method for single station and applied in analyzing GNSS data in Baoding during 2015-2017. Our analysis shows that TDDE is advanced in speed and independence for solving instrumental biases. The result obtained by TDDE in BeiDou Navigation Satellite System is better than that in GPS and GLONASS. Meanwhile, the instrumental biases corrected by TDDE are 2.50~3.00 TECU larger than those adjusted by Global Ionosphere Maps from Center for Obit Determination in Europe. In addition, the vertical TEC corrected by TDDE can clearly present diurnal variation, sunrise enhancement, semi-annual and annual variations, and equinoctial asymmetry of ionosphere TEC.
GNSS/
Instrumental biases/
Ionosphere/
Total electron content



PDF全文下载地址:

http://www.geophy.cn/data/article/export-pdf?id=dqwlxb_14931
相关话题/系统 北京 中国科学院 地球 观测