Fliegel H F, Gallini T E. Solar force modeling of BlockⅡR global positioning system satellites[J]. Journal of Spacecraft and Rockets, 1996, 33(6): 863-866.
[2]
Colombo O L. The dynamics of global positioning orbits and the determination of precise ephemerides[J]. Journal of Geophysical Research, 1989, 94(B7): 9 167-9 182.
[3]
Beutler G, Brockmann E, Gurtner W, et al. Extended orbit modeling techniques at the CODE processing center of the International GPS Service for geodynamics (IGS): Theory and initial results[J]. Manuscript Geodaetica, 1994, 19: 367-386.
[4]
Springer T A, Beutler G, Rothacher M. A new solar radiation pressure model for GPS satellites[J]. GPS Solutions, 1999, 2(3): 50-62.
[5]
Dach R, Brockmann E, Schaer S, et al. GNSS processing at CODE: Status report[J]. Journal of Geodesy, 2009, 83: 353-365.
[6]
Bar-Sever Y E, Russ K M. New and Improved Solar Radiation Models for GPS Satellites Based on Flight Data[R]. Pasadena, California: Jet Propulsion Laboratory, 1997.
[7]
Bar-Sever Y E, Kuang D. New Empirically Derived Solar Radiation Pressure Model for Global Positioning System Satellites[R]. Pasadena, California: Interplanetary Network Progress Report, 2004: 42-159.
[8]
Ziebart M, Dare P. Analytical solar radiation pressure modelling for GLONASS using a pixel array[J]. Journal of Geodesy, 2001, 75: 587-599.
[9]
Rodriguez-Solano C J, Hugentobler U, Steigenberger P. Adjustable box-wing model for solar radiation pressure impacting GPS satellites[J]. Advances in Space Research, 2012, 49: 1 113-1 128.
[10]
Rodriguez-Solano C J, Hugentobler U, Steigenberger P. Improving the orbits of GPS block ⅡA satellites during eclipse seasons[J]. Advances in Space Research, 2013, 52: 1 511-1 529.
[11]
Montenbruck O, Steigenberger P, Hugentobler U. Enhanced solar radiation pressure modeling for Galileo satellites[J]. Journal of Geodesy, 2015, 89(3):287-297, doi:10.1007/s00190-014-0774-0.
[12]
Hu Xiaogong. A new modeling of solar radiation pressure[J]. Progress in Astronomy, 1998, 16(1): 8-16. [胡小工. 太阳辐射压模型计算的新进展[J]. 天文学进展, 1998, 16(1): 8-16.]
[13]
Jiang Guojun. Comparison of Solar Radiation Pressure Models for GPS Satellites and Research on Precise Orbit Determination of GPS Satellite in Regional Network[D]. Shanghai: Shanghai Astronomical Observatory, Chinese Academy of Sciences, 1998. [姜国俊. GPS卫星太阳光压模型的比较和GPS区域网定轨问题研究[D]. 上海:中国科学院上海天文台, 1998.]
[14]
Chen Junping, Wang Jiexian. Solar radiation pressure models for the GPS satellites[J]. Acta Astronomica Sinica, 2006, 47(3): 310-319. [陈俊平,王解先. GPS定轨中的太阳辐射压模型[J]. 天文学报, 2006, 47(3): 310-319.]
[15]
Song Xiaoyong, Mao Yue, Jia Xiaolin. Analysis of the parameter of BERNESE radiation force model by statistic method[J]. Science of Surveying and Mapping, 2009, 34(3): 25-27. [宋小勇,毛悦,贾小林. BERNESE光压模型参数的统计分析[J]. 测绘科学, 2009, 34(3): 25-27.]
[16]
Yang Yang, Dong Xurong, Liu Li, et al. Research for ground orbit determination of navigation satellite based on solar pressure macroscopic model[J]. Journal of Academy of Equipment, 2012, 23(6): 71-75. [杨洋,董绪荣,柳丽,等. 基于光压宏观模型的导航卫星地基定轨研究[J]. 装备学院学报, 2012, 23(6): 71-75.]
[17]
Chen Qiuli, Chen Zhonggui, Wang Haihong. Modeling and analysis of solar radiation pressure for GPS satellites[J]. Spacecraft Engineering, 2013, 22(2): 98-103. [陈秋丽,陈忠贵,王海红. GPS卫星光压摄动建模发展与启示[J]. 航天器工程, 2013, 22(2): 98-103.]
[18]
Chen Qiuli, Wang Haihong, Chen Zhonggui. Method of modeling solar radiation pressure based on attitude control law of navigation satellites[C]∥4 th China Satellite Navigation Conference(CSNC). Wuhan, 2013. [陈秋丽,王海红,陈忠贵. 基于导航卫星姿态控制规律的光压摄动建模方法[C]∥第四届中国卫星导航学术年会. 武汉, 2013.]
[19]
Chen Qiuli, Wang Haihong, Chen Zhonggui. Analysis modeling and verification of solar radiation pressure for navigation satellite[J]. Chinese Space Science and Technology, 2014, 4: 16-23. [陈秋丽,王海红,陈忠贵. 导航卫星高精度太阳光压摄动分析建模及验证[J]. 中国空间科学技术, 2014, 4: 16-23.]
[20]
Arnold D, Dach R, Beutler G, et al. Impact of GNSS orbit modelling on reference frame[C]∥IAG Commission 1 Symposium 2014: Reference Frames for Applications in Geosciences (REFAG2014). Luxembourg, 2014.
[21]
Huang Hai, Li Jianwen, Luo Fulong. A new solar radiation pressure for BeiDou navigation system satellites[C]∥5 th China Satellite Navigation Conference(CSNC). Nanjing, 2014. [黄海,李建文,罗福龙. 北斗卫星太阳光压建模[C]∥第五届中国卫星导航学术年会. 南京, 2014.]
[22]
Feng Weidong, Guo Xiangyu, Qiu Hongxing, et al. A study of analytical solar radiation pressure modeling for BeiDou navigation satellites based on ray tracing method[C]∥China Satellite Navigation Conference(CSNC) 2014 Proceedings: Volume II, Springer, Lecture, Notes in Electrical Engineering, 2014, 304: 425-435.
[23]
Tan Hongli, Li Xiaojie, Wu Shan, et al. Analyze the solar radiation pressure in the transition of yaw steering mode to orbit normal mode[C]∥5 th China Satellite Navigation Conference(CSNC). Nanjing, 2014. [谭红力,李晓杰,吴杉,等. 导航卫星动态偏航转零偏航状态的太阳光压分析[C]∥第五届中国卫星导航学术年会. 南京, 2014.]
[24]
Mao Yue, Song Xiaoyong, Wang Wei, et al. IGSO satellite orbit determining strategy analysis with the yaw-steering and orbit-normal attitude control mode switching[J]. Geomatics and Information Science of Wuhan University, 2014, 39(11): 1 352-1 356. [毛悦,宋小勇,王维,等.IGSO姿态控制模式切换期间定轨策略研究[J]. 武汉大学学报:信息科学版, 2014, 39(11): 1 352-1 356.]
[25]
Kaplan E D, Hegarty C. Understanding GPS Principles and Applications[M]. London: London Artech House Inc., 2005.
[26]
Liu Lin. Orbital Mechanics of Artificial Earth Satellite[M] .Beijing:Higher Education Press, 1992. [刘林.人造地球卫星轨道力学[M]. 北京:高等教育出版社, 1992.]
[27]
Zhao Qunhe, Wang Xiaoya, He Bing, et al. The solar radiation pressure modeling on high-altitude Earth orbit satellite[C]∥5 th China Satellite Navigation Conference(CSNC). Nanjing, 2014. [赵群河,王小亚,何冰,等. 高轨卫星的太阳辐射压模型建立[C]∥第五届中国卫星导航学术年会. 南京, 2014.]
[28]
Fliegel H F, Gallini T E. Global positioning system radiation force model for geodetic applications[J]. Journal of Geophysical Research, 1992, 97(B1): 559-568.
