基本信息

王侃  女    中国科学院国家授时中心

电子邮件: wangkan@ntsc.ac.cn

王侃,中国科学院国家授时中心研究员,中国科学院大学博士生导师,时间基准及应用重点实验室(中国科学院)主任,国家自然科学基金国家级海外人才项目获得者,陕西省三秦优才,西安市高层次人才(地方级领军人才)。于德国、瑞士、澳大利亚学习工作17年,博士毕业于世界排名前十的瑞士苏黎世联邦理工大学,主要从事高精度卫星导航领域研究工作,在低轨卫星定轨定时、GNSS定位授时、时钟建模、整周模糊度解算、完好性监测等领域参与/承担国际国内科研项目二十余个,发表论文100余篇,其中SCI 论文70余篇,进行国内国际会议报告70余次,任SCI期刊编委,组织多个SCI低轨及GNSS专刊,先后任国际大地测量协会(IAG) “精密定位中的完好性监测”、“多系统 GNSS 理论与算法”工作组成员、美国导航学会(ION GNSS+ 2022)“PNT中的机会信号先进处理方法”分会联合主席。



Researchgate: https://www.researchgate.net/profile/Kan_Wang21

SCOPUS: http://www.scopus.com/authid/detail.url?authorId=55621722900

研究领域

GNSS卫星定位导航、低轨卫星定轨定时、低轨增强定位导航、完好性监测

招生信息

   
招生专业
081001-通信与信息系统
070402-天体测量与天体力学
085400-电子信息
招生方向
低轨卫星定轨定时
卫星定位导航
完好性监测

教育背景

2010-08--2016-03   瑞士苏黎世联邦理工大学   理学博士
2004-10--2010-05   德国斯图加特大学   工学硕士
2003-09--2004-09   武汉大学   理学学士(2008年获得)

工作经历

工作简历

2024,01至今, 时间基准及应用重点实验室(中国科学院), 主任

2022,01至今, 中国科学院国家授时中心, 研究员

2021,05-2022,01, 中国科学院国家授时中心, 副研究员

2020,01-2021,04, 澳大利亚科廷大学, Research Fellow

2016,11-2020,01, 澳大利亚科廷大学, Research Associate

2010,08-2016,06, 瑞士苏黎世联邦理工大学, Scientific Assistant


社会兼职

2025, 西安市高层次人才(地方级领军人才)     

2025, 全球华人导航定位协会(CPGNSS)论坛“未来高精度GNSS”专题联合主席

2024, 陕西省三秦优才

2024, 中国天文学会会员

2024, SCI期刊Remote Sensing编委,专刊“低轨增强GNSS中的机会与挑战(Low Earth Orbit Enhanced GNSS: Opportunities and Challenges)” 客座编委

2024, 国际大地测量协会(IAG)Inter-Commission Committee on Theory (ICCT) 联合工作组“多系统GNSS理论与算法”(Joint Study Group (JSG) “Multi-GNSS theory and algorithms”)成员

2023, 星网低轨导航专家组成员

2023, 陕西省天文学会会员 

2022, 时间频率学报学科编委

2022, 美国导航学会(ION)GNSS+ 2022 会议分会“导航定位授时中的机会信号先进处理方法”(Advanced Processing of Signals of Opportunity for Positioning, Navigation and Timing)联合主席

2021, SCI期刊Remote Sensing专刊 “低轨增强下的导航定位授时服务(LEO-Augmented PNT service)”首席客座编委

2020, 国际大地测量协会(IAG)4.4.1工作组“精密定位中的质量控制与完好性监测(Quality control and Integrity Monitoring of Precise Positioning)”成员

2020, SCI杂志Remote Sensing专刊 “遥感中的定位与导航(Positioning and Navigation in Remote Sensing)” 客座编委

出版信息

SCI期刊论文:

      

  1. Su H., Wang K.*, Jia H., Sun B., Yang X. (2026) Orbit prediction with pre-planned maneuver accelerations using an adaptive IME strategy. Measurement Science and Technology, 37(19), 196302. doi: 10.1088/1361-6501/ae6529
  2. Xie W., Wang K.*, Fu W., Li M., Du S., Yang X. (2026) TDCP-assisted undifferenced multi-GNSS real-time satellite clock estimation. GPS Solutions, 30, 122. doi: 10.1007/s10291-026-02087-9
  3. Sun Y., Li P.*, Zhang L.*, Wu Z., Yuan J., Wei M., Wu M., Wang K., Shu B., Huang G., Zhang Q. (2026) LEO-augmented Real-Time Kinematic with different multi-GNSS/multi-frequency combinations. Advances in Space Research, 77(10), 10161-10174. doi: 10.1016/j.asr.2026.02.051
  4. Chen B., Wang K.*, Liu J., Yang X. (2026) Integrity Monitoring of LEO Satellite POD under Poor Observation Continuities: Simulated scenarios using Sentinel-6A data. Measurement Science and Technology, 37(13), 135004. doi: 10.1088/1361-6501/ae554c
  5. Wu M., Wang K.*, Xie W., Chen B., Wang J., El-Mowafy A., Yang X. (2026) Impact on the Bias Propagation in the Integrity Monitoring of Filter-Based Real-Time LEO Satellite Clock Determination. Advances in Space Research, 77(7): 7509-7522. doi: 10.1016/j.asr.2026.02.024
  6. Wei C., Wang K.* (2026) Characteristics of probability distribution and fitting accuracy for LEO satellite ephemeris. GPS Solutions, 30, 67. doi: 10.1007/s10291-026-02032-w
  7. Liu J., Wang J., Wang K.*, Xie W., Wu M., El-Mowafy A., Yang X. (2026) Real-Time Estimation of LEO Satellite Clocks Using a Combination of Low- and High-Frequency Clock Solutions. NAVIGATION: Journal of the Institute of Navigation, 73(1), navi.739. doi: 10.33012/navi.739
  8. Wei C., Shao K., Gu D.*, Wang K. (2025) Calibration of Spaceborne Accelerometer through Satellite Dynamic Precise Orbit Determination: Enhancements and Evaluations. Aerospace Science and Technology, 171, 111601. doi: 10.1016/j.ast.2025.111601
  9. Xie W., Wang K.*, Fu W., Li M., El-Mowafy A., Yang X. (2025) Accelerating convergence of real-time multi-GNSS satellite clock estimation with ultra-rapid predicted GNSS satellite clocks constrained. Measurement Science and Technology, 37(2), 026302. doi: 10.1088/1361-6501/ae2d87
  10. Ye Z., Wang K.*, Wei C., Chen B., Wang J., Wu M. (2025) The impact of LEO satellite hardware delays on LEO-augmented precise point positioning. GPS Solutions, 30, 43. doi: 10.1007/s10291-025-01995-6
  11. Xie W., Wang K.*, Wu M., Li M., Yang X. (2025) On the multi-GNSS real-time PPP time transfer assisted by predicted receiver clocks. Measurement Science and Technology, 36(11), 116304. doi: 10.1088/1361-6501/ae1a10
  12. Allahvirdi-Zadeh A.*, El-Mowafy A., Wang K. (2025) Network-based precise orbit determination of broadband LEO satellites using Doppler-shift measurements. GPS Solutions, 30, 16. doi: 10.1007/s10291-025-01963-0
  13. Xie W., Wang K.*, Lai W., Wu M., Li M., Yang X. (2025) LEO-Enhanced Multi-GNSS Real-Time PPP Time Transfer. Remote Sensing, 17(21), 3549. doi: 10.3390/rs17213549
  14. Liu J., Wang K.*, El-Mowafy A., Wei C., Yang X. (2025) Dilution of Precision for LEO satellite precise orbit and clock determination. Advances in Space Research, 76(8), 4336-4348. doi: 10.1016/j.asr.2025.07.061
  15. Elsayed H.*, El-Mowafy A., Allahvirdi-Zadeh A., Wang K. (2025) Fast Protection Level for Precise Positioning Using PPP-RTK with Robust Adaptive Kalman Filter. Remote Sensing, 17(17), 2924. doi: 10.3390/rs17172924
  16. Chen B., Wang K.*, El-Mowafy A., Yang X. (2025) The Effect of Observation Discontinuities on LEO Real-Time Orbital Prediction Accuracy and Integrity. NAVIGATION: Journal of the Institute of Navigation, 72(3), navi.708. doi: 10.33012/navi.708
  17. Wang J., Wu M.*, Wang K., Zou M., Yang X. (2025) Influencing factors on real-time determination of LEO satellite clocks. Measurement Science and Technology, 36(6), 066315. doi: 10.1088/1361-6501/adddd0
  18. Allahvirdi-Zadeh A.*, El-Mowafy A., Wang K. (2025) Doppler Positioning Using Multi-Constellation LEO Satellite Broadband Signals as Signals of Opportunity. NAVIGATION: Journal of the Institute of Navigation, 72(2), navi.691. doi: 10.33012/navi.691
  19. Xie W., Wang K.*, Wang J., Chen B., Wu M., El-Mowafy A., Yang X. (2025) Impact of ISB stochastic models on LEO satellite clock estimation with onboard multi-GNSS observations. Measurement Science and Technology, 36(4), 046313. doi: 10.1088/1361-6501/adc7a7
  20. Wang Y.*, Sun B., Wang K., Yang X., Zhang Z., Zhang M., Wu M. (2025) Influences of Discontinuous Attitudes on GNSS/LEO Integrated Precise Orbit Determination Based on Sparse or Regional Networks. Remote Sensing, 17(4), 712. doi: 10.3390/rs17040712
  21. Elsayed H., El-Mowafy A.*, Allahvirdi-Zadeh A., Wang K. (2025) A Combination of Classification Robust Adaptive Kalman Filter with PPP-RTK to Improve Fault Detection for Integrity Monitoring of Autonomous Vehicles. Remote Sensing, 17(2), 284. doi: 10.3390/rs17020284
  22. Wu M., Wang K.*, Wang J., Xie W., Liu J., Chen B., Ge Y., El-Mowafy A., Yang X. (2024) Impact of Latency and Continuity of GNSS Products on Filter-Based Real-Time LEO Satellite Clock Determination. Remote Sensing, 16(22), 4315. doi: 10.3390/rs16224315
  23. Xie W., Wang K.*, Fu W., Cui B., Yang X. (2024) Regional multi-station real-time time transfer using an undifferenced multi-GNSS network solution. GPS Solutions, 28, 198. doi: 10.1007/s10291-024-01744-1
  24. Xie W., Su H., Wang K.*, Liu J., Wu M., Zou M., El-Mowafy A., Yang X. (2024) Real-time LEO satellite clock estimation with predicted LEO satellite orbits constrained. GPS Solutions, 28, 172. doi: 10.1007/s10291-024-01723-6 
  25. Wang K.*, Sun B., El-Mowafy A., Yang X. (2024) High-Precision Time Transfer and Relative Orbital Determination Among LEO Satellites in Real Time. NAVIGATION: Journal of the Institute of Navigation, 71 (3), navi.659. doi: 10.33012/navi.659
  26. Liu J., Wang K.*, El-Mowafy A., Yang X. (2024) PCO and hardware delay calibration for LEO satellite antenna downlinking navigation signals. Measurement Science and Technology, 35, 086314. doi: 10.1088/1361-6501/ad48a2
  27. Xie W., Wang K.*, Fu W., Xie S., Cui B., Li M. (2024) Real-Time Estimation of BDS-3 Satellite Clock Offset with Ambiguity Resolution Using B1C/B2a Signals. Remote Sensing, 16(10), 1666. doi: 10.3390/rs16101666
  28. Wu M., Wang K.*, Wang J., Liu J., Chen B., Xie W., Zhang Z., Yang X. (2024) Real-Time LEO Satellite Clocks Based on Near-Real-Time Clock Determination with Ultra-Short-Term Prediction. Remote Sensing, 16(8), 1326. doi: 10.3390/rs16081326
  29. Bezcioglu M., Yigit C.O.*, Dindar A.A., El-Mowafy A., Wang K. (2024) High-rate Single-Frequency Precise Point Positioning (SF-PPP) in the detection of structural displacements and ground motions. Structural Engineering and Mechanics, 89(6), 589-599. doi: 10.12989/sem.2024.89.6.589
  30. Wang K.*, El-Mowafy A., Cheng F., Yang X. (2024) LEO Augmentation in Large-Scale Ionosphere-Float PPP-RTK Positioning. Journal of Surveying Engineering, 150(2), 04024001. doi: 10.1061/JSUED2.SUENG-1414
  31. Zhang Z., Sun B.*, Wang K., Han X., Yang H., Wang G., Wu M., Wang Y., Geng C., Yang X. (2023) Sub-Nanosecond UTC Dissemination Based on BDS-3 PPP-B2b Service. Remote Sensing, 16(1), 43. doi: 10.3390/rs16010043
  32. Wang K.*, Su H., El-Mowafy A., Yang X. (2023) Prediction and ephemeris fitting of LEO navigation satellites orbits computed at the antenna phase center. Measurement, 224, 113935. doi: 10.1016/j.measurement.2023.113935
  33. Elsayed H.*, El-Mowafy A., Wang K. (2023) A new method for fault identification in real-time integrity monitoring of autonomous vehicles positioning using PPP-RTK. GPS Solutions, 28, 32. doi: 10.1007/s10291-023-01569-4
  34. Wang K.*, El-Mowafy A., Yang X. (2023) LEO satellite clock modelling and its benefits in LEO kinematic POD. Remote Sensing, 15(12), 3149. doi: 10.3390/rs15123149
  35. Mi X., Allahvirdi-Zadeh A., El-Mowafy A., Huang Z., Wang K., Zhang B.*, Yuan Y. (2023) Absolute and relative POD of LEO satellites in formation flying: Undifferenced and uncombined approach. Advances in Space Research, 72(4): 1070-1080. doi: 10.1016/j.asr.2023.05.024
  36. Wu M., Wang K.*, Liu J., Zhu Y. (2023) Relativistic effects of LEO satellite and its impact on clock prediction. Measurement Science and Technology, 34(9), 095005. doi: 10.1088/1361-6501/acd545
  37. Mi X., Zhang B.*, El-Mowafy A., Wang K., Yuan Y. (2023) Undifferenced and uncombined GNSS time and frequency transfer with integer ambiguity resolution. Journal of Geodesy, 97, 13. doi: 10.1007/s00190-022-01689-8
  38. Wang K.*, Liu J., Su H., El-Mowafy A., Yang X. (2023) Real-Time LEO Satellite Orbits based on Batch Least-Squares Orbit Determination with Short-Term Orbit Prediction. Remote Sensing, 15(1), 133. doi: 10.3390/rs15010133
  39. Elsayed H.*, El-Mowafy A., Wang K. (2022) Bounding of correlated double-differenced GNSS observation errors using NRTK for precise positioning of autonomous vehicles. Measurement, in Press. doi: 10.1016/j.measurement.2022.112303
  40. Mi X., Zhang B.*, El-Mowafy A., Wang K., Yuan Y. (2022) On the potential of undifferenced and uncombined GNSS time and frequency transfer with integer ambiguity resolution and satellite clocks estimated. GPS Solutions, in Press. doi: 10.1007/s10291-022-01363-8
  41. Wang K.*, Sun B., Qin W., Mi X., El-Mowafy A., Yang X. (2022) A method of real-time long-baseline time transfer based on the PPP-RTK. Advances in Space Research, in Press. doi: 10.1016/j.asr.2022.10.062
  42. Wang K.*, El-Mowafy A., Yang X. (2022) URE and URA for predicted LEO satellite orbits at different altitudes. Advances in Space Research, 70(8), 2412-2423. doi: 10.1016/j.asr.2022.08.039
  43. El-Mowafy A.*, Wang K. (2022) Integrity monitoring for kinematic precise point positioning in open-sky environments with improved computational performance. Measurement Science and Technology, 33, 085004. doi: 10.1088/1361-6501/ac5d75 
  44. Wang K., El-Mowafy A., Wang W., Yang L., Yang X. (2022) Integrity Monitoring of PPP-RTK Positioning; Part II: LEO Augmentation. Remote Sensing, 14(7), 1599. doi: 10.3390/rs14071599
  45. Allahvirdi-Zadeh A.,Awange J., El-Mowafy A., Ding T., Wang K.* (2022) Stability of CubeSat Clocks and their impacts on GNSS Radio Occultation. Remote Sensing, 14(2), 362. doi: 10.3390/rs14020362
  46. Wang K.*, El-Mowafy A., Qin W., Yang X. (2021) Integrity Monitoring of PPP-RTK Positioning; Part I: GNSS-based IM Procedure. Remote Sensing, 14(1), 44. doi: 10.3390/rs14010044
  47. Su H.*, Yang T., Wang K., Sun B., Yang X. (2021) Evaluation of Precipitable Water Vapor Retrieval from Homogeneously Reprocessed Long-Term GNSS Tropospheric Zenith Wet Delay and Multi-Technique. Remote Sensing, 13(21), 4490. doi: 10.3390/rs13214490
  48. Allahvirdi-Zadeh A., Wang K.*, El-Mowafy A. (2021) Precise Orbit Determination of LEO Satellites Based on Undifferenced GNSS Observations. Journal of Surveying Engineering, 148(1), 03121001. doi: 10.1061/(ASCE)SU.1943-5428.0000382
  49. Wang K., El-Mowafy A.* (2021) LEO satellite clock analysis and prediction for positioning applications. Geo-spatial Information Science, in Press, June 2021. doi: 10.1080/10095020.2021.1917310
  50. Wang K.*, El-Mowafy A., Rizos C., Wang J. (2021) SBAS DFMC service for Road Transport: Positioning and integrity monitoring with a new weighting model. Journal of Geodesy, 95(3), 29. doi: 10.1007/s00190-021-01474-z
  51. Allahvirdi-Zadeh A., Wang K.*, El-Mowafy A. (2021) POD of small LEO satellites based on precise real-time MADOCA and SBAS-aided PPP corrections. GPS Solutions, 25,31. doi: 10.1007/s10291-020-01078-8
  52. Wang K.*, El-Mowafy A. (2021) Effect of biases in integrity monitoring for RTK positioning. Advances in Space Research, 67(12): 4025-4042.doi: 10.1016/j.asr.2021.02.032
  53. Wang K., El-Mowafy A.*, Rizos C. (2021) Integrity monitoring for precise orbit determination of LEO satellites. GPS Solutions, 26(1), 32. doi: 10.1007/s10291-021-01200-4
  54. Wang K.*, El-Mowafy A. (2020) Proposed orbital products for positioning using mega-constellation LEO satellites. Sensors 20(20), 5806. doi: 10.3390/s20205806
  55. Wang K.*, Allahvirdi-Zadeh A., El-Mowafy A., Gross J.N. (2020) A Sensitivity Study of POD Using Dual-Frequency GPS for CubeSats Data Limitation and Resources. Remote Sensing 12(13), 2107. doi:10.3390/rs12132107
  56. Wang K.*, El-Mowafy A., Rizos C., Wang J. (2020) Integrity Monitoring for Horizontal RTK Positioning: New Weighting Model and Overbounding CDF in Open-Sky and Suburban Scenarios. Remote Sensing, 12(7):1173. doi: 10.3390/rs12071173
  57. Wang K.*, Teunissen P.J.G., El-Mowafy A. (2020) The ADOP and PDOP: Two complementary diagnostics for GNSS positioning. Journal of Surveying Engineering, 146(2): 04020008. doi: 10.1061/(ASCE)SU.1943-5428.0000313
  58. Wu J., Wang K.*, El-Mowafy A. (2020) Preliminary performance analysis of a prototype DFMC SBAS service over Australia and Asia-Pacific. Advances in Space Research, 66(6):1329-1341. doi: 10.1016/j.asr.2020.05.026
  59. Hassan T., El-Mowafy A., Wang K.* (2020) A Review of System Integration and Current Integrity Monitoring Methods for Positioning in Intelligent Transport Systems. IET Intelligent Transport Systems, 15(1):43-60. doi: 10.1049/itr2.12003
  60. Wang K., Chen P.*, Teunissen P.J.G. (2019) Single-epoch, single-frequency multi-GNSS L5 RTK under high-elevation masking. Sensors 19(5):1066. doi: 10.3390/s19051066
  61. Wang K.*, Khodabandeh A., Teunissen P.J.G. (2019) Precision analysis of troposphere sensing using GPS single-frequency signals. Advances in Space Research, 61(1):148-159. doi: 10.1016/j.asr.2018.09.006
  62. El-Mowafy A.*, Imparato D., Rizos C., Wang J., Wang K. (2019) On hypothesis testing in RAIM algorithms: generalized likelihood ratio test, solution separation test and a possible alternative. Measurement Science and Technology, 30(7):075001. doi: 10.1088/1361-6501/ab1836
  63. Wang K., Chen P.*, Zaminpardaz S., Teunissen P.J.G. (2019) Precise Regional L5 Positioning with IRNSS and QZSS: stand-alone and combined. GPS Solutions 23:10. doi: 10.1007/s10291-018-0800-4
  64. Wang K., Chen P.*, Teunissen P.J.G. (2018) Fast phase-only positioning with triple-frequency GPS. Sensors 18(11):3922. doi: 10.3390/s18113922
  65. Wang K.*, Khodabandeh A., Teunissen P.J.G., Nadarajah N. (2018) Satellite-clock modeling in single-frequency PPP-RTK processing. Journal of Surveying Engineering, 144(2): 04018003. doi: 10.1061/(ASCE)SU.1943-5428.0000252
  66. Wang K., Khodabandeh A.*, Teunissen P.J.G. (2018) MSE-impact of PPP-RTK ZTD estimation strategies. Advances in Space Research 61(12): 2955-2971. doi: 10.1016/j.asr.2018.04.012
  67. Wang K.*, Khodabandeh A., Teunissen P.J.G. (2018) Five-frequency Galileo long-baseline ambiguity resolution with multipath mitigation. GPS Solutions 22:75. doi: 10.1007/s10291-018-0738-6
  68. Zaminpardaz S., Wang K., Teunissen P.J.G.* (2018) Australia-First High-Precision Positioning Results with New Japanese QZSS Regional Satellite System. GPS Solutions 22:101. doi: 10.1007/s10291-018-0763-5
  69. Nadarajah N., Khodabandeh A., Wang K., Choudhury M., Teunissen P.J.G.* (2018) Multi-GNSS PPP-RTK: from large- to small-scale networks. Sensors 18(4):1078. doi: 10.3390/s18041078
  70. Wang K.*, Khodabandeh A., Teunissen P.J.G. (2017) A study on predicting network corrections in PPP-RTK processing. Advances in Space Research 60(7):1463-1477. doi: 10.1016/j.asr.2017.06.043
  71. Wang K.*, Rothacher M. (2015) GNSS triple-frequency geometry-free and ionosphere-free track-to-track ambiguities. Advances in Space Research 55(11): 2668-2677. doi: 10.1016/j.asr.2015.02.028
  72. Glaser S.*, Fritsche M., Sosnica K., Rodriguez-Solano C.J., Wang K., Dach R., Hugentobler U., Rothacher M., Dietrich R. (2015) A consistent combination of GNSS and SLR with minimum constraints. Journal of Geodesy 89(12): 1165-1180. doi: 10.1007/s00190-015-0842-0
  73. Glaser S.*, Fritsche M., Sosnica K., Rodriguez-Solano C.J., Wang K., Dach R., Hugentobler U., Rothacher M., Dietrich R. (2015) Errtum to: A consistent combination of GNSS and SLR with minimum constraints. Journal of Geodesy 89(12): 1181-1182. doi: 10.1007/s00190-015-0853-x
  74. Fritsche M.*, Sosnica K., Rodriguez-Solano C.J., Steigenberger P., Wang K., Dietrich R., Dach R., Hugentobler U., Rothacher M. (2014) Homogeneous reprocessing of GPS, GLONASS and SLR observations. Journal of Geodesy 88(7): 625-642. doi:10.1007/s00190-014-0710-3
  75. Wang K.*, Rothacher M. (2013) Ambiguity resolution for triple-frequency geometry-free and ionosphere-free combination tested with real data. Journal of Geodesy 87 (6): 539-553. doi: 10.1007/s00190-013-0630-7
  76. Wang K.*, Rothacher M. (2013) Stochastic modeling of high-stability ground clocks in GPS analysis. Journal of Geodesy 87(5): 427-437. doi: 10.1007/s00190-013-0616-5
  77. Varga P., Krumm F., Riguzzi F.*, Doglioni C., Süle B., Wang K., Panza G.F. (2012) Global pattern of earthquakes and seismic energy distributions: Insights for the mechanisms of plate tectonics. Tectonophysics 530-531: 80-86. doi:10.1016/j.tecto.2011.10.014



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  5. 邹敏,刘嘉伟,谢威,王侃,武美芳,杨旭海(2024)基于卡尔曼滤波的低轨卫星实时运动学定轨及预报分析。时间频率学报,47(4),277-285
  6.  邹敏,王侃,武美芳,陈贝希,韦春博(2024)ARM架构下的低轨卫星实时定轨精度及运算效率分析。测绘科学,49(9),18-29
  7. 王锦乾,武美芳,王侃,刘嘉伟,杨旭海,邹敏(2024)面向导航增强的低轨卫星钟差确定及预报方法研究,导航定位与授时, 11(3),119-127
  8. Wang K., Su H., El-Mowafy A., Yang X. (2024) Gaps in real-time GNSS satellite clocks and their impacts on LEO satellite POD. In Proc. ION GNSS+ 2024, Baltimore, Maryland, USA, September 2024, pp. 2363-2378. doi: 10.33012/2024.19831
  9. Allahvirdi-Zadeh A., El-Mowafy A., Wang K. (2024) Leveraging Future LEO Constellations for the Precise Orbit Determination of Lower Small Satellites. In Proc. ION ITM 2024, Long Beach, California, January 2024, pp. 756-769. doi: 10.33012/2024.19485
  10. Chen B., Wang K., El-Mowafy A., Yang X. (2024) Real-Time GNSS Satellite SISRE and its Integrity for LEO Satellite Precise Orbit Determination. In Proc. ION ITM 2024, Long Beach, California, January 2024, pp. 807-820. doi: 10.33012/2024.19488
  11. El-Mowafy A., Wang K., Li Y., Allahvirdi-Zadeh A. (2023) The impact of orbital and clock errors on positioning from LEO constellations and proposed orbital solutions. Arch. Photogramm. Remote Sens. Spatial Inf. Sci., XLVIII-1/W2-2023, 1111–1117. doi:10.5194/isprs-archives-XLVIII-1-W2-2023-1111-2023.
  12. Zhou H., Sun B., Sun L., Zhao L., Zhang Z., Wang G., Wang K., Yang X. (2023) Accuracy Analysis of BeiDou-3/GPS Real-Time Precise Common View Time Transfer Based on Carrier-Phase. In China Satellite Navigation Conference (CSNC 2024) Proceedings, pp. 432-444. Lecture Notes in Electrical Engineering, vol 1094. Springer, Singapore.  doi: 10.1007/978-981-99-6944-9_38
  13. Su H., Wang K., Yang X. (2023) Improving LEO satellite onboard SPP orbits with dynamic models. In Proc. ION GNSS+ 2023, Denver, CO, USA, 11-15 September 2023, pp. 2310-2318. doi: 10.33012/2023.19461
  14. Wang K., El-Mowafy A., Yang X. (2023) Integer Ambiguity Resolution in Multi-GNSS Constellation GNSS for LEO satellite POD. In Proc. ION GNSS+ 2023, Denver, CO, USA, 11-15 September 2023, pp. 2319-2329. doi: 10.33012/2023.19462
  15. Wang K., El-Mowafy A., Su H., Yang X. (2023) On the Very Short and Very Long LEO Satellite Orbit Prediction. In Proc. ION ITM 2023, Long Beach, California, January 2023, pp. 725-735. doi: 10.33012/2023.18665
  16. Wang K., Yang X., El-Mowafy A. (2022) Visibility of LEO Satellites under Different Ground Network Distributions. In Proc. ION GNSS+ 2022, Denver, Colorado, USA, September 2022, pp. 2478-2491. doi: 10.33012/2022.18391
  17. El-Mowafy A., Wang K., Allahvirdi-Zadeh A. (2022) The potential of LEO mega-constellations in aiding GNSS to enable positioning in challenging environments. In Proc. FIG Congress 2022, Warsaw, Poland, 11-15 September 2022
  18. Allahvirdi-Zadeh A., El-Mowafy A., Wang K. (2022) Precise Orbit Determination of CubeSats Using Proposed Observations Weighting Model. In: International Association of Geodesy Symposia. Springer, Berlin, Heidelberg. https://doi.org/10.1007/1345_2022_160
  19. Wang K., El-Mowafy A., Rizos C. (2022) Bridging clock gaps in Mega-constellation LEO satellites. In Proc. ION ITM 2022, January 2022, pp. 881-892. doi: 10.33012/2022.18246
  20. 刘嘉伟,孙保琪,韩蕊,张喆,王侃,袁海波,杨旭海(2022)GNSS多系统RTK授时性能分析。导航定位与授时,10(3), 49-58.
  21. 刘嘉伟,孙保琪,张喆,王源昕,武美芳,王侃,杨旭海(2022)全球网北斗三号卫星跟踪情况及数据质量分析。时间频率学报,46(1), 49-59.
  22. Wang K., El-Mowafy A., Khaki M., Sutherland T., Rubinov E. (2020) Assessment of the New DFMC and PPP services of the second-generation SBAS in the Mining and Urban environments. In Proc. IGNSS Symposium, No. 49, 5-7 February 2020, Sydney, Australia
  23. Wang K., El-Mowafy A., Wu J. (2020) Integrity Monitoring Using ARAIM in Bridging DFMC SBAS Outages for Road Transport. In Proc. ION GNSS+ 2020, September, 2020, pp. 2430-2439. doi: 10.33012/2020.17659
  24. El-Mowafy A., Wang K. (2019) Second Generation SBAS – Performance Analysis and Bridging Positioning and Integrity Monitoring during SBAS Outages in the Urban Environment. In Proc. ION GNSS+ 2019, Miami, Florida, September 2019, pp. 2842-2854. doi: 10.33012/2019.16923
  25. Glaser S., Fritsche M., Sosnica K., Rodriguez-Solano C.J., Wang K., Dach R., Hugentobler U., Rothacher M., Dietrich R. (2015) Validation of Components of Local Ties. In: van Dam T. (eds) REFAG 2014. International Association of Geodesy Symposia, vol 146. Springer, Cham. pp. 21-28. doi: 10.1007/1345_2015_190
  26. Wang K., Meindl M., Geiger A., Rothacher M., Scaramuzza M., Troller M., Truffer P. (2014) Assessment of Single-difference Ionospheric Residuals in a Regional Network for GBAS. In Proc. ION GNSS+ 2014, Tampa, Florida, USA, September 8 - 12, 2014, pp. 2384-2393

合作情况

参与欧洲空间局(European Space Agency)、瑞士空间局(Swiss Space Office)、澳大利亚研究委员会(Australian Research Council)等的国际项目十余个,承担国家自然基金国家级海外人才项目、面上项目、中国科学院国际伙伴项目等。