基于扩展卡尔曼滤波的XPNAV-1卫星自主定轨算法研究

X射线脉冲星导航1号（XPNAV-1）是全球首颗脉冲星导航专用试验卫星。利用该卫星观测的单颗脉冲星数据，采用几何约束方法，能够有效抑制轨道误差增长，但存在长时间定轨发散问题。针对XPNAV-1卫星拓展试验任务及脉冲星导航后续发展需求，利用多颗脉冲星的观测数据，研究基于扩展卡尔曼滤波（EKF）的卫星自主定轨算法。首先，建立该卫星的轨道力学模型和观测方程；然后，详细论述EKF滤波算法和分段式定常系统（PWCS）的可观测性分析方法；最后，通过综合分析XPNAV-1卫星的观测数据、脉冲星对该卫星轨道的覆盖性以及系统状态的可观测性，进行自主定轨算法试验。试验结果表明，基于EKF的自主定轨算法滤波过程收敛，验证了该算法的合理性和有效性。     

联合北斗导航与星间链路的大椭圆卫星定轨方法

传统的地面测控和GNSS均无法实现HEO卫星全弧段的跟踪观测.在分析北斗导航信号及其星间链路信号对典型HEO的观测几何及覆盖特性的基础上,利用北斗导航及其星间链路对HEO测控支持形成互补的特点,提出了一种卫星导航与星间链路相结合的自主导航方法.对HEO定轨进行分段划分并基于EKF设计了卫星导航与星间链路数据融合定轨的自主导航算法.分析结果表明,本文提出的方法能够从全弧段上改善HEO的观测几何,定轨精度比仅使用卫星导航提高了2个数量级,并且仅需较少的星间链路资源.      

钟差和动力学参数联合约束下的北斗卫星轨道快速确定

受地球非球形引力、第三体摄动和太阳光压等摄动因素的影响,导航卫星位置存在长周期变化趋势,需要定期对导航卫星进行轨道机动,以保持卫星轨位和导航服务区.导航卫星机动后的定轨,特别是GEO卫星,其频繁轨控后的轨道快速确定问题,是制约卫星可用度和导航系统服务性能的重要因素.在基于伪距相位数据的轨道测定中,轨道与钟差的统计相关是制约卫星轨道快速确定的关键因素,特别是在观测弧段短的情况下,待估参数之间的相关性更强,动力学参数估计结果严重失真会导致轨道预报精度衰减明显.当卫星钟差与测站钟差通过外部手段高精度测定后,可以减少待估参数的估计,同时利用长弧定轨的动力学与运动学参数先验信息,对短弧定轨模式进行参数约束,卫星定轨精度将有很大的提升空间.通过钟差与力学参数的联合约束,实现了北斗卫星短弧快速定轨,解决了卫星机动后的轨道快速确定问题,SLR评估的卫星机动后4 h定轨外符视向精度优于0.71 m,比常规方法提高了3倍,预报1 h轨道视向精度为1.89 m,用户等效距离误差(UERE)精度达到1.85 m.     

基于机动力模型的GEO卫星恢复期间定轨

北斗卫星导航系统(BDS)中GEO卫星频繁的轨道机动对高精度、实时不间断的导 航服务需求提出了更高要求, 如何在短弧跟踪条件下提高GEO卫星轨道快速 恢复能力, 是提升导航系统服务精度的关键因素. 针对该问题, 本文提出了基 于机动力模型的动力学定轨方法, 尝试利用高精度的C波段转发式测距数据, 辅 以机动期间的遥测遥控信息建立机动力模型, 联合轨控前后的观测数据进行动 力学长弧定轨. 利用BDS中GEO卫星实测数据进行了定轨试验与分析, 结果表明, 恢复期间需要采用解算机动推力的定轨方法, 联合机动前、机动期间和机 动后4h数据定轨的轨道位置精度在20m量级, 径向精度优于2.5m. 该方 法克服了短弧跟踪条件下动力学法定轨和单点定位中的诸多问题, 提供了解决 GEO卫星机动后轨道快速恢复问题的技术方法.      

导航卫星的地面站定轨算法

导航星座轨道的长期保持是星座导航系统运营管理的重要组成部分,而现有的导航卫星地面定轨算法又存在精度不高或计算量大不适合工程应用的问题。为此,研究了单向、被动测量模式的导航卫星地面定轨算法。基于单向伪距观测,将导航卫星钟差参数作为状态量,推导了滤波算法的状态方程、测量方程,并最终建立了滤波器模型。以不同轨道面的4颗GPS导航卫星为例进行了2天的仿真试验,考虑卫星的可见性仿真中加入了测量中断,并设计在测量恢复后重启滤波算法。仿真结果表明,4颗卫星的轨道位置估计精度可以达到米级,钟差随机偏差的估计精度可以达到纳秒级,并且在滤波中断后重启滤波器,仍然可以达到此估计精度,表明此定轨算法具有收敛性和稳定性。     

基于GNSS的高轨卫星定位技术研究

利用全球卫星导航系统(GNSS)进行导航定位具有全球、全天候、实时和高精度的优点,应用于高地球轨道(HEO)卫星的定位,能够提供精确的轨道和姿态确定,并且可以克服目前主要利用地面测控系统对HEO卫星进行定位的设备复杂、投资高等缺点,使得自主导航成为可能.本文对利用GNSS的高轨卫星定位相关技术进行了研究,分析了单一GNSS系统和多个GNSS组合系统的卫星可见性、动态性和几何精度因子(GDOP).通过仿真分析表明,利用组合GNSS系统并通过提高GNSS接收机灵敏度的方法,可以解决GNSS进行HEO卫星定位的相关问题,并能保证HEO卫星定位精度的要求.      

USB观测数据时标偏差影响分析与评估

USB系统是目前中国载人航天和月球探测任务的主要测控网.由于USB测量设备本身以及无线电信号传播媒介以及其他误差因素的影响,USB测量数据中包含了各种误差,需要在定轨时对观测数据进行误差修正.通常,例行的USB测量误差修正包括对流层折射修正、电离层延迟修正和通道延迟修正,但对定轨过程中可能影响观测数据计算精度的时标偏差并未作修正.针对USB测距测速观测数据,详细研究了观测数据时标偏差对观测值计算精度的影响,分析了误差影响特性,建立了相应的误差修正模型,并通过与卫星星历偏差对USB测距测速观测值计算精度影响特征的比较,发现时标偏差对测量的影响与轨道沿迹误差对观测计算值的影响等效,这使得在定轨过程中分离时标偏差的难度较大.提出了基于星载GPS定位数据分离时标偏差的方法,并利用某次任务的实测数据,分离出了该次任务中USB测量的时标偏差.最后针对目前USB数据时标偏差影响和观测误差量级相当的情况,建议将目前的观测时标精度提高到优于0.1ms的水平,使得时标偏差的影响降低到比观测误差小一个量级的水平.     

基于单站CCD漂移扫描光电设备的同步轨道目标测定轨

地基光电观测在同步轨道目标监测领域具有重要作用.为评估单站光电设备对同步轨道目标的实际测定轨能力,利用上海天文台佘山站1.56m望远镜,采用CCD漂移扫描光电技术,对3颗北斗同步卫星开展试验观测,基于卫星精密星历评估目标的测定轨外符精度.结果表明:同步轨道目标的天文定位在方位和俯仰方向上的外符精度均好于0.3";在单圈次观测情况下,尽管轨道预报精度较低,约为数千米量级,但是观测弧段内定轨精度可优于百米;在多圈次观测情况下,轨道改进效果显著,定轨精度优于50m,外推至4d的轨道预报精度为百米量级.此外,定量评估了每晚不同观测时间跨度下同步轨道目标的测定轨精度,为单站光电设备实际应用提供了参考.      

星载GPS低轨卫星几何法精密定轨研究

本文讨论了星载ＧＰＳ接收机为单频情形的代轨卫星几何法定轨,包括载波一相对定轨法和动态网定轨法,并利用Ｔｏｐｅｘ／Ｐｏｓｅｉｄｏｎ卫星星载ＧＰＳ实测数据中Ｌ１载波相位观测值进行验证,结果表明,载波相位相对定轨精度与地面基准站的观测质量有关,其三轨道位置精度为分米级;载波相位动态风定轨精度介于各基准站皮相位相对定轨之间,它相当于在各基准站相对定轨之间加权均衡,而且提高了定轨的可靠性。     

卫星编队飞行的相对轨道自主确定研究

为了研究卫星编队飞行相对轨道的自主确定,基于相对轨道根数建立编队卫星间的相对运动方程,利用测量所得到的星间距离和方位信息作为观测量。不同于目前广泛采用的扩展卡尔曼滤波算法,设计Unscented Kalman Filter(UKF)算法实现卫星编队飞行的相对轨道自主确定。仿真结果表明这种相对轨道自主确定方案能获得较高的定轨精度。     

星载GNSS确定GEO卫星轨道的积分滤波方法

采用星载全球导航卫星系统（GNSS）确定地球静止轨道（GEO）,以解决目前应用星载全球定位系统(GPS)时导航卫星可见性差的问题。以风云卫星为例,分析了未来的GNSS相对于GEO卫星的可见性,针对GEO轨道上导航接收机采样间隔较长的问题,综合轨道积分和卡尔曼滤波方法的优点,提出了确定GEO卫星轨道的积分滤波方法。并利用STK软件仿真产生所需数据,用MATLAB对提出的算法编程并进行仿真验证,结果表明,提出的方法性能优越,定轨精度较高。     

Orbit determination of BeiDou navigation satellite system maneuvered satellites based on instantaneous velocity pulses parameters

The BeiDou navigation satellite system (BDS) comprises geostationary earth orbit (GEO) satellites as well as inclined geosynchronous orbit (IGSO) and medium earth orbit (MEO) satellites. Owing to their special orbital characteristics, GEO satellites require frequent orbital maneuvers to ensure that they operate in a specific orbital window. The availability of the entire system is affected during the maneuver period because service cannot be provided before the ephemeris is restored. In this study, based on the conventional dynamic orbit determination method for navigation satellites, multiple sets of instantaneous velocity pulses parameters which belong to one of pseudo-stochastic parameters were used to simulate the orbital maneuver process in the orbital maneuver arc and establish the observed and predicted orbits of the maneuvered and non-maneuvered satellites of BeiDou regional navigation satellite system (BDS-2) and BeiDou global navigation satellite system (BDS-3). Finally, the single point positioning (SPP) technology was used to verify the accuracy of the observed and predicted orbits. The orbit determination accuracy of maneuvered satellites can be greatly improved by using the orbit determination method proposed in this paper. The overlapping orbit determination accuracy of maneuvered GEO satellites of BDS-2 and BDS-3 can improve 2–3 orders of magnitude. Among them, the radial orbit determination accuracy of each maneuvered satellite is basically better than 1 m. simultaneously, the combined orbit determination of the maneuvered and non-maneuvered satellites does not have a great impact on the orbit determination accuracy of the non-maneuvered satellites. Compared with the multi GNSS products (indicated by GBM) from the German Research Centre for Geosciences (GFZ), the impact of adding the maneuvered satellites on the orbit determination accuracy of BDS-2 satellites is less than 9 %. Furthermore, the orbital recovery time and the service availability period are significantly improved. When the node of the predicted orbit is traversed approximately 3 h after the maneuver, the accuracy of the predicted orbit of the maneuvered satellite can reach that of the observed orbit. The SPP results for the BDS reached a normal level when the node of the predicted orbit was 2 h after the maneuver.     

The influence of orbital maneuver on autonomous orbit determination of an extended satellite navigation constellation

The right ascension of the ascending node is unobservable if only the inter-satellite ranging is used for autonomous orbit determination (AOD) of an Earth navigation constellation. However, if an Earth-Moon libration point satellite is added to the Earth navigation constellation to construct an extended navigation constellation, all the orbital elements can be determined with only the inter-satellite ranging. Furthermore, the extended navigation constellation can provide navigation information for interplanetary probes. For such an extended navigation constellation, orbital control needs to be considered due to the instability of the libration-point satellite orbit. This study concerns the influence of satellite orbital maneuver on the AOD of the extended navigation constellation. An AOD method under orbital maneuver is proposed. A low thrust controller is designed to achieve libration point satellite autonomous orbit maintenance by using AOD results. A navigation constellation consisting of three GPS satellites and one libration point satellite are designed for simulation. The simulation results show that libration point satellites can achieve autonomous navigation and autonomous orbit maintenance by only using inter-satellite ranging information. The rotation drift error of the Earth navigation constellation is also suppressed.     

Near real-time BDS GEO satellite orbit determination and maneuver analysis with reversed point positioning

The Geostationary Earth Orbit (GEO) satellite is a crucial part of the BeiDou Navigation Satellite System (BDS) constellation. However, due to various perturbation forces acting on the GEO satellite, it drifts gradually over time. Thus, frequent orbit maneuvers are required to maintain the satellite at its designed position. During the orbit maneuver and recovery periods, the orbit quality of the maneuvered satellite computed with broadcast navigation ephemeris will be significantly degraded. Furthermore, the conventional dynamic Precise Orbit Determination (POD) approach may not work well, because of a lack of publicly available satellite information for modeling the thrust forces. In this paper, a near real-time approach free of thrust forces modeling is proposed for BDS GEO satellite orbit determination and maneuver analysis based on the Reversed Point Positioning (RPP). First, the station coordinates and receiver clock offsets are estimated by GPS/BDS combined Single Point Positioning (SPP) with single-frequency phase-smoothed pseudorange observations. Then, with the fixed station coordinates and receiver clock offsets, the RPP method can be conducted to determine the GEO satellite orbits. When no orbit maneuvers occur, the proposed method can obtain orbit accuracies of 0.92, 2.74, and 8.30?m in the radial, along-track, and cross-track directions, respectively. The average orbit-only Signal-In-Space Range Error (SISRE) is 1.23?m, which is slightly poorer than that of the broadcast navigation ephemeris. Using four days of GEO maneuvered datasets, it is further demonstrated that the derived orbits can be employed to characterize the behaviors of GEO satellite maneuvers, such as the time span of the maneuver as well as the satellite thrusting accelerations. These results prove the efficiency of the proposed method for near real-time GEO satellite orbit determination during maneuvers.     

Guidepost-based autonomous orbit determination method for GEO satellite

Guidepost-based navigation system is a novel autonomous orbit determination method for the GEO satellite. The system is achieved by using the camera imaging function to obtain the guidepost images and the GNSS signal receiver to obtain the pseudoranges between the GEO and the navigation satellites. Due to the high altitude of GEO satellite and the time-varying sunlight condition in the space environment, it may be difficult to obtain object image points and the distance measurements of GNSS because of the weak visibility of the guideposts. To deal with the problem, a novel integrated orbit determination system is presented. The Earth landmarks, the in-orbit spacecraft and GNSS navigation satellites whose line-of-sights and the distance can be easily obtained are used at the same time as information for the GEO satellite navigation based on the observability conditions analysis. The observability of the GEO satellite navigation system is analyzed through the physical observability, the mathematical observability and the engineering observability through the observing geometry, the rank of observability matrix and the Cramer-Rao lower bound (CRLB) respectively. Besides, the maximum correntropy unscented Kalman filter (MCUKF) algorithm is applied to improve the estimation stability of the system in the presence of non-Gaussian noises. The simulation indicates the feasibility of the proposed scheme.     

利用GPS接收机的精确轨道确定技术

利用GPS接收机的导航信息精确确定接收机载体航天器的轨道根数.给出了为确保10 m量级的定轨精度所必需的精确坐标系变换与时间系统变换公式,提出了采用GPS接收机的导航信息与摄动运动方程式外推的组合导航方法,以保证接收机天线被短期遮挡时导航仍能正常运行.     

Orbit determination and prediction of GEO satellite of BeiDou during repositioning maneuver

In order to establish a continuous GEO satellite orbit during repositioning maneuvers, a suitable maneuver force model has been established associated with an optimal orbit determination method and strategy. A continuous increasing acceleration is established by constructing a constant force that is equivalent to the pulse force, with the mass of the satellite decreasing throughout maneuver. This acceleration can be added to other accelerations, such as solar radiation, to obtain the continuous acceleration of the satellite. The orbit determination method and strategy are illuminated, with subsequent assessment of the orbit being determined and predicted accordingly. The orbit of the GEO satellite during repositioning maneuver can be determined and predicted by using C-Band pseudo-range observations of the BeiDou GEO satellite with COSPAR ID 2010-001A in 2011 and 2012. The results indicate that observations before maneuver do affect orbit determination and prediction, and should therefore be selected appropriately. A more precise orbit and prediction can be obtained compared to common short arc methods when observations starting 1 day prior the maneuver and 2 h after the maneuver are adopted in POD (Precise Orbit Determination). The achieved URE (User Range Error) under non-consideration of satellite clock errors is better than 2 m within the first 2 h after maneuver, and less than 3 m for further 2 h of orbit prediction.