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  1. To provide backup and supplementation for the Global Navigation Satellite System (GNSS), Doppler shift from Low Earth Orbit (LEO) satellites can be used as signals of opportunity to provide positioning, naviga...

    Authors: Fei Guo, Yan Yang, Fujian Ma, Yifan Zhu, Hang Liu and Xiaohong Zhang
    Citation: Satellite Navigation 2023 4:9
  2. A new Precise Point Positioning (PPP) service, called the PPP-B2b service, has been implemented in the BeiDou-3 Navigation Satellite System (BDS-3), which brings new opportunities for time transfer. However, t...

    Authors: Yulong Ge, Qing Wang, Yong Wang, Daqian Lyu, Xinyun Cao, Fei Shen and Xiaolin Meng
    Citation: Satellite Navigation 2023 4:8
  3. Civilian services of Global Navigation Satellite System are threatened by spoofing attacks since it is hard to determine the authenticity of a navigation signal with a detailed structure open to the public. Si...

    Authors: Muzi Yuan, Xiaomei Tang and Gang Ou
    Citation: Satellite Navigation 2023 4:6
  4. To improve the accuracy of the Ultra-Wide Band (UWB) based quadrotor aircraft localization, a Finite Impulse Response (FIR) filter aided with an integration of the predictive model and Extreme Learning Machine...

    Authors: Yuan Xu, Dong Wan, Shuhui Bi, Hang Guo and Yuan Zhuang
    Citation: Satellite Navigation 2023 4:2
  5. To achieve higher automation level of vehicles defined by the Society of Automotive Engineers, safety is a key requirement affecting navigation accuracy. We apply Light Detection and Ranging (LiDAR) as a main ...

    Authors: Kaiwei Chiang, Yuting Chiu, Surachet Srinara and Menglun Tsai
    Citation: Satellite Navigation 2023 4:3
  6. Unmanned clusters can realize collaborative work, flexible configuration, and efficient operation, which has become an important development trend of unmanned platforms. Cluster positioning is important for en...

    Authors: Zhongliang Deng, Hang Qi, Chengfeng Wu, Enwen Hu and Runmin Wang
    Citation: Satellite Navigation 2023 4:1
  7. The PPP–RTK method, which combines the concepts of Precise of Point Positioning (PPP) and Real-Time Kinematic (RTK), is proposed to provide a centimeter-accuracy positioning service for an unlimited number of ...

    Authors: Xingxing Li, Jiaxin Huang, Xin Li, Zhiheng Shen, Junjie Han, Linyang Li and Bo Wang
    Citation: Satellite Navigation 2022 3:28
  8. Tropospheric delay is an important factor affecting high precision Global Navigation Satellite System (GNSS) positioning and also the basic data for GNSS atmospheric research. However, the existing tropospheri...

    Authors: Ge Zhu, Liangke Huang, Yunzhen Yang, Junyu Li, Lv Zhou and Lilong Liu
    Citation: Satellite Navigation 2022 3:27
  9. Several Wireless Fidelity (WiFi) fingerprint datasets based on Received Signal Strength (RSS) have been shared for indoor localization. However, they can’t meet all the demands of WiFi RSS-based localization. ...

    Authors: Jingxue Bi, Yunjia Wang, Baoguo Yu, Hongji Cao, Tongguang Shi and Lu Huang
    Citation: Satellite Navigation 2022 3:25
  10. Ionospheric delay modeling is not only important for Global Navigation Satellite System (GNSS) based space weather study and monitoring, but also an efficient tool to speed up the convergence time of Precise P...

    Authors: Shengfeng Gu, Chengkun Gan, Chengpeng He, Haixia Lyu, Manuel Hernandez-Pajares, Yidong Lou, Jianghui Geng and Qile Zhao
    Citation: Satellite Navigation 2022 3:24
  11. Geodetic applications of Low Earth Orbit (LEO) satellites requires accurate satellite orbits. Instead of using onboard Global Navigation Satellite System observations, this contribution treats the LEO satellit...

    Authors: Xingchi He, Urs Hugentobler, Anja Schlicht, Yufeng Nie and Bingbing Duan
    Citation: Satellite Navigation 2022 3:22
  12. Precise Point Positioning (PPP) with Ambiguity Resolution (AR) is an important high-precision positioning technique that is gaining popularity in geodetic and geophysical applications. The implementation of PP...

    Authors: Jianghui Geng, Qiyuan Zhang, Guangcai Li, Jingnan Liu and Donglie Liu
    Citation: Satellite Navigation 2022 3:23
  13. The Indian Regional Navigation Satellite System provides accurate positioning service to the users within and around India, extending up to 1500 km. However, when a receiver encounters a Continuous Wave Interf...

    Authors: Jacob Silva Lorraine Kambham and Madhu Ramarakula
    Citation: Satellite Navigation 2022 3:21
  14. Over the past years the International Global Navigation Satellite System (GNSS) Monitoring and Assessment System (iGMAS) Wuhan Innovation Application Center (IAC) dedicated to exploring the potential of multi-...

    Authors: Xingxing Li, Qingyun Wang, Jiaqi Wu, Yongqiang Yuan, Yun Xiong, Xuewen Gong and Zhilu Wu
    Citation: Satellite Navigation 2022 3:20
  15. Stable and reliable high-precision satellite orbit products are the prerequisites for the positioning services with high performance. In general, the positioning accuracy depends strongly on the quality of sat...

    Authors: Yidong Lou, Xiaolei Dai, Xiaopeng Gong, Chenglong Li, Yun Qing, Yang Liu, Yaquan Peng and Shengfeng Gu
    Citation: Satellite Navigation 2022 3:15
  16. Multipath interference seriously degrades the performance of Global Navigation Satellite System (GNSS) positioning in an urban canyon. Most current multipath mitigation algorithms suffer from heavy computation...

    Authors: Wenqi Qiu, Qinghua Zeng, Rui Xu, Jianye Liu, Jinheng Shi and Qian Meng
    Citation: Satellite Navigation 2022 3:14
  17. The use of dead reckoning and fingerprint matching for navigation is a widespread technical method. However, fingerprint mismatching and low fusion accuracy are prevalent issues in indoor navigation systems. T...

    Authors: Jian Chen, Shaojing Song, Yumei Gong and Shanxin Zhang
    Citation: Satellite Navigation 2022 3:13
  18. With the high-precision products of satellite orbit and clock, uncalibrated phase delay, and the atmosphere delay corrections, Precise Point Positioning (PPP) based on a Real-Time Kinematic (RTK) network is po...

    Authors: Pan Li, Bobin Cui, Jiahuan Hu, Xuexi Liu, Xiaohong Zhang, Maorong Ge and Harald Schuh
    Citation: Satellite Navigation 2022 3:10
  19. Satellite integrity monitoring is vital to satellite-based augmentation systems, and can provide the confidence of the differential corrections for each monitored satellite satisfying the stringent safety-of-l...

    Authors: Shuaiyong Zheng, Mengzhi Gao, Zhigang Huang, Xiaoqin Jin and Kun Li
    Citation: Satellite Navigation 2022 3:9
  20. PPP-RTK which takes full advantages of both Real-Time Kinematic (RTK) and Precise Point Positioning (PPP), is able to provide centimeter-level positioning accuracy with rapid integer Ambiguity Resolution (AR)....

    Authors: Xingxing Li, Bo Wang, Xin Li, Jiaxin Huang, Hongbo Lyu and Xinjuan Han
    Citation: Satellite Navigation 2022 3:7
  21. Real-Time Kinematic Precise Point Positioning (PPP–RTK) is inextricably linked to external ionospheric information. The PPP–RTK performances vary much with the accuracy of ionospheric information, which is der...

    Authors: Xiaohong Zhang, Xiaodong Ren, Jun Chen, Xiang Zuo, Dengkui Mei and Wanke Liu
    Citation: Satellite Navigation 2022 3:6
  22. Within the framework of differential augmentation, this paper introduces the basic technical framework and performance of the BeiDou Global Navigation Satellite System (BDS-3) Satellite-Based Augmentation Syst...

    Authors: Yuanxi Yang, Qun Ding, Weiguang Gao, Jinlong Li, Yangyin Xu and Bijiao Sun
    Citation: Satellite Navigation 2022 3:5
  23. Satellite Based Augmentation System (SBAS) is one of the services provided by the BeiDou Navigation Satellite System (BDS). It broadcasts four types of differential corrections to improve user application perf...

    Authors: Junping Chen, Yize Zhang, Chao Yu, Ahao Wang, Ziyuan Song and Jianhua Zhou
    Citation: Satellite Navigation 2022 3:4
  24. Since the first pair of BeiDou satellites was deployed in 2000, China has made continuous efforts to establish its own independent BeiDou Navigation Satellite System (BDS) to provide the regional radio determi...

    Authors: Qile Zhao, Jing Guo, Chen Wang, Yifei Lyu, Xiaolong Xu, Chao Yang and Junqiang Li
    Citation: Satellite Navigation 2022 3:2
  25. The Precise Point Positioning (PPP) service of BeiDou-3 Navigation Satellite System (BDS-3) is implemented on its Geostationary Earth Orbit (GEO) satellites. However, its signal design is limited by the actual...

    Authors: Cheng Liu, Zheng Yao, Dun Wang, Weiguang Gao, Tianxiong Liu, Yongnan Rao, Dongjun Li and Chengeng Su
    Citation: Satellite Navigation 2022 3:1
  26. The Precise Point Positioning (PPP) technique uses a single Global Navigation Satellite System (GNSS) receiver to collect carrier-phase and code observations and perform centimeter-accuracy positioning togethe...

    Authors: Qile Zhao, Jing Guo, Sijing Liu, Jun Tao, Zhigang Hu and Gang Chen
    Citation: Satellite Navigation 2021 2:29
  27. Wi-Fi technology has become an important candidate for localization due to its low cost and no need of additional installation. The Wi-Fi fingerprint-based positioning is widely used because of its ready hardw...

    Authors: Xiaoxiang Cao, Yuan Zhuang, Xiansheng Yang, Xiao Sun and Xuan Wang
    Citation: Satellite Navigation 2021 2:27
  28. Accurate positioning and navigation play a vital role in vehicle-related applications, such as autonomous driving and precision agriculture. With the rapid development of Global Navigation Satellite Systems (G...

    Authors: Xingxing Li, Huidan Wang, Shengyu Li, Shaoquan Feng, Xuanbin Wang and Jianchi Liao
    Citation: Satellite Navigation 2021 2:26
  29. An aided Inertial Navigation System (INS) is increasingly exploited in precise engineering surveying, such as railway track irregularity measurement, where a high relative measurement accuracy rather than abso...

    Authors: Qijin Chen, Quan Zhang, Xiaoji Niu and Jingnan Liu
    Citation: Satellite Navigation 2021 2:25
  30. Recent studies revealed that the long-lasting daytime ionospheric enhancements of Total Electron Content (TEC) were sometimes observed in the Asian sector during the recovery phase of geomagnetic storms (e.g.,...

    Authors: Xin Wan, Chao Xiong, Shunzu Gao, Fuqing Huang, Yiwen Liu, Ercha Aa, Fan Yin and Hongtao Cai
    Citation: Satellite Navigation 2021 2:23
  31. Colored Measurement Noise (CMN) has a great impact on the accuracy of human localization in indoor environments with Inertial Navigation System (INS) integrated with Ultra Wide Band (UWB). To mitigate its infl...

    Authors: Yuan Xu, Jing Cao, Yuriy S. Shmaliy and Yuan Zhuang
    Citation: Satellite Navigation 2021 2:22
  32. As a new Ionosphere Associate Analysis Center (IAAC) of the International GNSS Service (IGS), Chinese Academy of Sciences (CAS) started the routine computation of the real-time, rapid, and final Global Ionosph...

    Authors: Zishen Li, Ningbo Wang, Ang Liu, Yunbin Yuan, Liang Wang, Manuel Hernández-Pajares, Andrzej Krankowski and Hong Yuan
    Citation: Satellite Navigation 2021 2:19

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  • Citation Impact 2023
    Journal Impact Factor: 9.0
    5-year Journal Impact Factor: 9.1
    Source Normalized Impact per Paper (SNIP): 3.815
    SCImago Journal Rank (SJR): 2.363

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    Submission to first editorial decision (median days): 9
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