Performance Analysis of BDS Single Frequency Ionosphere Model
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摘要: 根据北斗卫星导航系统三步走战略,北斗三号系统空中星座在2020年左右完成部署,信号的覆盖范围从亚太大部分地区扩展至全球.实际上自2018年底北斗三号系统已经可以初步提供全球服务.相应地,北斗系统的单频电离层模型从只适用于亚太大部分地区的BDSKlob模型发展到适用于全球范围的BDGIM模型.为分析北斗三号电离层模型的性能,以IGS GIM最终数据为参考,比较了2019年3月1-31日期间北斗BDGIM模型、BDSKlob模型以及GPSKlob模型在不同时段不同地区的改正效果.结果表明:北斗三号BDGIM模型在中国区域的改正率达75%以上,优于BDSKlob模型59%的改正率;在全球范围的改正率达60%,优于GPSKlob模型49%的改正率.除南半球高纬度地区外,BDGIM模型的电离层误差值均小于GPSKlob模型,其在垂直方向的电离层均方根误差值优于6TECU.
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关键词:
- 北斗卫星导航系统 /
- 单频电离层模型 /
- BDGIM模型 /
- Klobuchar模型
Abstract: With the construction of BDS-3, the single-frequency ionospheric model of BDS-2 (BDSKlob) which is only suitable for the correction of ionosphere delay in Chinese area is no more applicable. The BDGIM model is proposed for the correction of ionosphere delay globally in BDS-3. The performance of BDGIM model is compared with BDSKlob and GPSKlob (the ionospheric model of GPS) in different areas for day and night in the time period of 1-31 March 2019. The results show that the correction ratio of BDGIM model of BDS-3 is over 75% in China while that of BDSKlob is 59%. Its global correction ratio is 60% which is superior to the correction ratio 49% of GPSKlob. As far as the Root Mean Square (RMS) of ionosphere is concerned, the global average value of BDGIM model is less than that of GPSKlob. The RMS of vertical ionospheric error of BDGIM is less than 6 TECU in all the other areas excluding the high latitude area of south hemisphere. -
[1] XIE Gang. Principles of GNSS-GPS, GLONASS and Galileo[M]. Beijing:Publishing House of Electronics Industry, 2013(谢钢. 全球导航卫星系统原理——GPS, 格洛纳斯和伽利略系统[M]. 北京:电子工业出版社, 2013) [2] BENOÎT Bidaine. Ionosphere Modelling for Galileo Single Frequency Users[D]. Liég:University of Liége, 2012 [3] LIU Shuai, JIA Xiaolin. Correction accuracy evaluation and analysis for GNSS ionosphere model[J]. Chin. J. Space Sci., 2016, 36(3):297-304(刘帅, 贾小林. GNSS电离层模型精度评估与分析[J]. 空间科学学报, 2016, 36(3):297-304) [4] China Satellite Navigation Office. Beidou Navigation Satellite System Signal in Space Interface Control Document Open Service Signal[S]. Beijing:China Satellite Navigation Office, 2012(中国卫星导航系统管理办公室. 北斗卫星导航系统空间信号接口控制文件[S]. 北京:中国卫星导航办公室, 2012) [5] China Satellite Navigation Office. Beidou Navigation Satellite System Signal in Space Interface Control Document for Open Service Signal BIC[S]. Beijing:China Satellite Navigation Office, 2017(中国卫星导航系统管理办公室. 北斗卫星导航系统空间信号接口控制文件公开服务信号BIC[S]. 北京:中国卫星导航办公室, 2017) [6] LIU Li, SHI Xin, LI Jing, et al. The definition and using method of the COMPASS basic navigation message[J]. Sci. Sin.:Phys. Mech. Astron., 2015, 45(7):0795091-0795097(刘利, 时鑫, 栗靖, 等. 北斗基本导航电文定义与使用方法[J]. 中国科学:物理学力学天文学, 2015, 45(7):0795091-0795097) [7] KLOBUCHAR J A. Ionospheric time-delay algorithm for single-frequency GPS users[J]. IEEE Trans. Aerosp. Electron. Syst., 1987, 23:325-331 [8] GSA. Ionospheric correction algorithm for Galileo single frequency users[OL]. https://www.gsc-europa.eu/system/files/galileo_documents/Galileo_Ionospheric_Model.pdf,2016 [9] JSC. GLONASS Interface Control Document-General Description of Code Division Multiple Access Signal System[M]. Moscow:Russian Space Systems, 2016 [10] LI Zishen. Study on the Mitigation of Ionospheric Delay and the Monitoring of Global Ionospheric TEC Based on GNSS/Compass[D]. Beijing:Chinese Academy of Sciences, 2012(李子申. GNSS/Compass电离层时延修正及TEC监测理论与方法研究[D]. 北京:中国科学院大学, 2012) [11] WANG Fei, WU Xiaoli, ZHOU Tian, et al. Performance comparison between different Klobuchar model parameters[J]. Acta Geod. Cartograph. Sin., 2014, 43(1):1151-1157(王斐, 吴晓莉, 周田, 等. 不同Klobuchar模型参数的性能比较[J]. 测绘学报, 2014, 43(1):1151-1157) [12] ZHANG Hongping, PING Jinsong, ZHU Wenyao, et al. Brief review of the ionospheric delay models[J]. Prog. Astron., 2006, 24(1):17-25(章红平, 平劲松, 朱文耀, 等. 电离层延迟改正模型综述[J]. 天文学进展, 2006, 24(1):17-25) [13] WU Xiaoli, HU Xiaogong, WANG Gang, et al. Evaluation of COMPASS ionospheric model in GNSS positioning[J]. Adv. Space Res., 2013, 51(6):959-968 [14] ZHANG Hongping. Study on GPS Based China Regional Ionosphere Monitoring and Ionosphere Delay Correction[D]. Shanghai:Shanghai Astronomical Observatory, 2006(章红平. 基于地基GPS的中国区域电离层监测与延迟改正研究[D]. 上海:中国科学院上海天文台, 2006) [15] YUAN Yunbin, WANG Ningbo, LI Zishen, et al. The Beidou Global broadcast Ionospheric delay correction Model (BDGIM) and its preliminary performance evaluation results[J]. Navigation, 2019, 66(1):55-69 [16] WANG Ningbo. Study on GNSS differential code bias and global broadcast ionospheric models of GPS, Galileo and BDS[J]. Acta Geod. Cartograph. Sin., 2017, 46(8):1069 [17] PRIETO CERDEIRA R, ORUS PERES R, BREEUWER E, et al. Performance of the Galileo single-frequency ionospheric correction during in-orbit validation[J]. GPS World, 2014, 25:53-58 [18] FENG Laiping, ZHU Yongxing. Precision analysis of regional ionosphere model based on Beidou navigation satellite system[J]. Hydrograph. Surv. Charting, 2016, 36(5):47-50 -
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