自主机动条件下的实时定轨方法

中继卫星在跟踪自主机动用户目标时,由于机动轨道未知,需要利用中继卫星下传的星载GNSS(Global Navigations Satellite System,全球导航卫星系统)数据进行实时轨道确定与预报,为中继卫星跟踪提供实时的引导信息,以方便中继卫星快速捕获目标和连续稳定跟踪。针对该类用户目标的任务需求,讨论了基于星载GNSS数据自主机动条件下的实时定轨方法,建立了连续推力机动力学模型。以某一型号卫星的实测数据进行分析验证,并对轨道机动进行辨识,计算的机动加速度和机动时间与试验单位提供的结果一致。针对卫星不同机动情况,5min的观测数据定轨预报10min的弧段,最大位置误差小于8km,可以为中继卫星快速捕获提供高精度的引导信息。     

单通道测量条件下DORIS实时定轨方法研究

重点研究了单通道测量条件下的DORIS实时定轨方法。推导了实时定轨的扩展卡尔曼滤波（EKF）公式,仿真生成了47个测站的观测数据文件,分析了单通道测量条件下EKF滤波器的收敛性及其精度。仿真实验表明,仅有单个测站的观测数据时,滤波难以收敛;但在不同测站的观测数据切换时,滤波收敛效果显著。对于轨道高度为800km的卫星,初轨各轴位置误差小于500m、速度误差小于5m/s时,滤波平均收敛时间约55min;若各项系统误差能准确建模,实时轨道的位置精度将优于40cm。     

顾及轨道误差的GNSS卫星钟差实时估计策略优化

为提高GNSS卫星钟差实时估计精度，针对GNSS各卫星系统的轨道差异，分析各系统卫星轨道误差对钟差估计的影响，基于距离函数线性化二阶残余项的思想，提出了一种顾及轨道误差的权函数模型，以优化实时卫星钟差估计策略。利用全球均匀分布的IGS和iGMAS跟踪站的实时观测数据进行实验，并与GBM的事后精密钟差进行对比分析。结果表明： GPS精度提高率为6.47%，BDS精度提高率为6.46%，GLONASS精度提高率为7.42%，Galileo精度提高率为7.62%。     

嫦娥二号再拓展试验测定轨精度研究

基于＂嫦娥二号＂卫星再拓展试验的设计轨道,研究各种摄动力对轨道确定精度的影响,得出的结论是：若要达到km量级的轨道确定精度,必须考虑除天王星和海王星之外所有大行星以及日月的质点引力。文章进一步利用数值分析法研究再拓展任务的轨道确定精度,分析结果表明：基于目前的测控条件,使用30 d以上的测轨弧段可以得到稳定可靠的轨道解,而短弧（小于20 d）稳定轨道的获取需要VLBI（甚长基线干涉）测轨数据支持;当＂嫦娥二号＂距离地球700万km时,测控精度可优于30 km;虽然每天测轨弧段的增加可以改善轨道精度,但是当增加到8 h以上时,定轨精度将不再有明显改善。     

影响环月飞行器定轨精度的误差源分析

以我国正在实施的探月计划“嫦娥1号”工程为背案,在现有测控网分布、观测弧段以及尽可能接近真实情况的误差源等前提下,利用仿真模拟的方法对影响环月飞行器定轨精度的误差源进行了初步探讨和分析。重点考察了月球重力场误差、观测量精度、初始时刻的先验轨道误差以及观测资料类型等对环月飞行器定轨精度的影响。     

基于中继测量的环月探测器定轨能力分析

嫦娥四号月球探测拟首次实现月球背面的软着陆,测控与数传依赖地月L2平动点的中继卫星,并有望获取四程测量与星间测量数据。对基于中继测量的环月探测器测定轨能力进行了仿真分析,结果表明,中继卫星可较好地实现环月探测器连续跟踪;在定轨能力方面,中继卫星自身轨道精度是制约环月探测器定轨精度的重要因素,当跟踪弧段达到5h以上时,定轨精度趋于稳定,但轨道精度较中继卫星的轨道精度相差1个量级;对于星间链路测量,除中继卫星自身的轨道精度外,星钟的稳定性是制约定轨精度的另一个重要因素,如果辅助以每天1h的地基跟踪亦可实现优于百m的定轨精度。     

Intersatellite tracking methods for clustered geostationarysatellites

With the assumption that two satellites are placed in geostationary orbit at a small constant longitudinal separation, the feasibility of relative orbit determination by means of intersatellite tracking is studied analytically. Two types of tracking are examined: range-and-angle tracking and range-only tracking. Two-body orbital motion with first-order approximation of the relative orbital motion is assumed. The effect of solar radiation perturbation is evaluated numerically, and the study which neglects the perturbation is justified. The accuracy assessment of the relative orbit determination is given in general terms     

Improvement of Satellite Tracking Accuracy Using Optical Observations

A method to improve satellite tracking accuracy is presented and discussed theoretically and experimentally in terms of two parts: correction for errors of the tracking system and correction of satellite orbit predictions. In the first part, it is concluded that the pointing error of the tracking system can be determined accurately using data from stellar observations, so that correction is possible with an accuracy of about 0.001°. In the second part, it is shown that apparent errors of satellite orbital elements can be deduced from the optical observation of one orbit, and one can track the satellite after the correction with high accuracy for several subsequent orbits. The accuracy is 0.1-0.2 mrad or better for satellites at 1000 km altitude when given orbit prediction accuracy is approximately 1°.     

外测数据对流层折射误差修正及精度分析

针对对流层引起的航天器外测数据折射误差,基于对流层分段模型,以测站历史气象数据拟合折射衰减系数,建立测控站上空对流层折射率模型,并利用实测地面折射率对统计模型进行优化,进一步提高模型反映大气剖面的真实性.利用该模型对S频段多颗在轨卫星50多跟踪圈次的实测外测数据进行修正分析,并与微波辐射计实时修正结果进行比较,测距、测角、测速互差分别优于0.9m、0.02°、0.06 m/s.将该模型应用于卫星长管外测数据的实时修正,可提高轨道测量数据质量.     

基于多模型的低轨星座多目标跟踪传感器资源调度

针对低轨星座多目标持续跟踪传感器资源调度问题,首先将目标跟踪任务划分为高精度任务集合和低精度任务集合,并分析了跟踪任务状态转移过程;然后,为两任务集合分别建立了基于动态优先级的优化调度模型,提出了一种基于多模型的实时传感器调度算法。不同场景下仿真实验表明,所提算法较之以跟踪精度为优化目标和以跟踪精度为门限约束的方法具有更强的适用性,尤其对于目标分布较为集中的情况,其目标丢失率大大降低,尽管个别目标的跟踪误差略有增大。     

A geopause satellite system concept

The forthcoming 10 cm range tracking accuracy capability holds much promise in connection with a number of Earth and ocean dynamics investigations. These include a set of earthquake-related studies of fault motions and the Earth's tidal, polar and rotational motions, as well as studies of the gravity field and the sea surface topography which should furnish basic information about mass and heat flow in the oceans. The state of the orbit analysis art is presently at about the 10 m level, or about two orders of magnitude away from the 10 cm range accuracy capability expected in the next couple of years or so. The realization of a 10 cm orbit analysis capability awaits the solution of four kinds of problems, namely, those involving orbit determination and the lack of sufficient knowledge of tracking system biases, the gravity field, and tracking station locations. The Geopause satellite system concept offers promising approaches in connection with all of these areas. A typical Geopause satellite orbit has a 14 hour period, a mean height of about 4.6 Earth radii, and is nearly circular, polar, and normal to the ecliptic. At this height only a relatively few gravity terms have uncertainties corresponding to orbital perturbations above the decimeter level. The orbit s, in this sense, at the geopotential boundary, i.e., the geopause. The few remaining environmental quantities which may be significant can be determined by means of orbit analyses and accelerometers. The Geopause satellite system also provides the tracking geometery and coverage needed for determining the orbit, the tracking system biases and the station locations. Studies indicate that the Geopause satellite, tracked with a 2 cm ranging system from nine NASA affiliated sites, can yield decimeter station location accuracies. Five or more fundamental stations well distributed in longitude can view Geopause over the North Pole. This means not only that redundant data are available for determining tracking system biases, but also that both components of the polar motion can be observed frequently. When tracking Geopause, the NASA sites become a two-hemisphere configuration which is ideal for a number of Earth physics applications such as the observation of the polar motion with a time resolution of a fraction of a day. Geopause also provides the basic capability for satellite-to-satellite tracking of drag-free satellites for mapping the gravity field and altimeter satellites for surveying the sea surface topography. Geopause tracking a coplanar, drag-free satellite for two months to 0.03 mm per second accuracy can yield the geoid over the entire Earth to decimeter accuracy with 2.5° spatial resolution. Two Geopause satellites tracking a coplanar altimeter satellite can then yield ocean surface heights above the geoid with 7° spatial resolution every two weeks. These data will furnish basic boundary condition information about mass and heat flows in the oceans which are important in shaping weather and climate.     

北斗实时精密轨道和钟差产品解算策略及精度评定

随着北斗卫星导航系统全球星座部署即将完成，其应用领域不断扩大，实时精密服务性能受到了极大关注。基于动力学精密定轨方法，设计了北斗卫星实时轨道、钟差算法流程和解算策略。利用不同频点信号，分别计算了BDS-2和BDS-3卫星的实时精密轨道和钟差，建立了完整的轨道和钟差精度评定方法，重点对解算的实时产品的精度进行了评定。结果表明：BDS-2和BDS-3实时精密轨道和钟差产品精度均可满足大部分实时用户的需求。对于B1IB3I频点，BDS-3 MEO卫星的实时轨道精度约为26cm，径向精度约为6cm，实时钟差精度约为0.45ns，且相较于BDS-2，性能更加稳定；对于B1CB2a频点，BDS-3 MEO卫星的实时轨道精度优于20cm，精度和稳定性较高。     

Orbit Determination Accuracies Using Satellite-to-Satellite Tracking

The results are reported of the ATS-6/GEOS-3 and the ATS-6 NIMBUS-6 satellite-to-satellite orbit determination experiments. NASA intends to use the tracking data relay satellite system for operational orbit determination of NASA satellites. Hence, in the near future, satellite-to-satellite tracking data will be routinely processed to obtain orbits. The satellite-to-satellite tracking system used in the ATS-6/NIMBUS-6 and ATS-6/GEOS-3 experiments performed with a resolution of 1 to 2 m in range and less than 1 mm/s in range rate for a 10-s averaging. A Bayesian least squares estimation technique utilizing independent ranging to the synchronous relay satellite was determined to be the most effective procedure for estimating orbits from satellite-to-satellite tracking data. The use of this technique yields estimates of user satellite orbits which are comparable in accuracy to what is usually obtained from ground based systems.     

双线程滑动窗口多系统GNSS超快精密定轨实现及评估

全球导航卫星系统（GNSS）超快精密定轨为GNSS实时应用提供了高精度空间基准。基于天地协同定位、导航与授时（PNT）网络服务中心实现了四系统GNSS卫星超快精密定轨,并对定轨结果进行精度评价。介绍了天地协同PNT网络的概念内涵以及网络服务中心部署的超快精密定轨软件架构和详细功能,并针对实时应用需求提出了一种双线程滑动窗口超快精密定轨策略。最后利用重叠弧段比较、与外部轨道产品比较以及卫星激光测距（SLR）检核3种方式对定轨结果进行了精度评价。结果表明,与武汉大学分析中心的最终事后精密轨道产品相比,四系统GNSS MEO卫星预报6 h弧段的径向均方根（RMS）误差整体在2~5 cm水平,BDS2 IGSO卫星最小一维RMS误差在10~15 cm水平;GPS和Galileo卫星的SLR检核残差均值在1~3 cm水平,标准差在3~6 cm水平,能够满足后续厘米级实时应用对空间基准的精度需求。     

Optical Calibration of Geostationary Satellite Tracking Systems

A precise calibration method for range and angle observation has been developed for eliminating the systematic error of tracking systems, thus improving the accuracy of orbit determination for geostationary satellites. The principle of calibration is based on an orbit determination employing a point of optical angle observation in addition to radio tracking observation, in which we estimate observation bias parameters simultaneously with orbital elements, including the effects of geodetic mismodelings. As shown by an actual calibration experiment in our ground station, orbit determinations is sufficiently accurate that the error of predicting satellite range falls within a few meters at four days after the day of orbit determination.     

Power beaming providing a space power infrastructure

A study based on two levels of technology maturity, which applies to the power beaming concept to four planned satellite constellations, is described. The analysis shows that with currently available technology, power beaming can provide mass savings to constellations to orbits ranging from low-Earth orbit to geosynchronous orbit. Two constellations, a space surveillance and tracking system and space-based radar, can be supported with current technology. The other two constellations, a space-based laser array and a boost surveillance and tracking system, will require power and transmission system improvements before their break-even specific mass is achieved. A doubling of SP-100 conversion efficiency from 10 to 20% would meet or exceed break-even for these constellations     

基于我国深空站三向测量模式的数据精度分析

为了验证我国深空站三向测量模式的正确性,以同步星跟踪试验中的测量数据为基础,建立了站间同步修正算法和三向测量观测模型,通过与同步卫星的精密星历反算测量值比较,得到了测量数据的标定参数,结果表明,我国深空站测控能够实现dm级的测量精度,明显优于“嫦娥二号”测量的水平;同时利用测量数据进行定轨策略分析,最终实现了10 m量级的同步卫星定轨精度.分析结果为“嫦娥三号”探测器实施有效测控提供了依据.     

轨道预测辅助GPS载波跟踪技术用于低轨道卫星定位研究

针对低轨道卫星及其特定的运动环境,研究了星载GPS接收机载波跟踪问题。基于卫星轨道可模化、可预测的特性,提出了利用预测卫星轨道计算多普勒频移,并用于辅助载波环路跟踪的新方法。该方法有效地降低了低轨道卫星GPS信号跟踪中的动态,从而在跟踪过程中可以采取降低环路阶数、减小环路带宽、增加预检测积分时间这几种措施来提高环路跟踪弱信号的能力,有助于提高低轨道卫星的定位性能。     

Sustained data recording system based on disk array

Most sustained data recording systems in many real-time fields are based on tape equipments. We have developed an innovative sustained data recording system based on disk array which consists of Array Controller Module (ACM), String Controller Module (SCM) and Main Controller Module (MCM). This system has a better performance and higher reliability than the traditional tape recorder and can be used conveniently in many areas of data recording, storing, playback, and remote backup. This novel recording system has been used in radar data recorder for spacecraft orbit tracking and satellite remote sensing data recording successfully.     

基于非差模型的GPS卫星实时钟差估计精度分析

通过分析实时钟差估计的解算过程,实现了基于非差模型的GPS卫星实时钟差估计,利用区域和全球数据、最终和实时轨道分别求解实时钟差,并将其结果与IGS实时钟差产品进行对比,分析GPS卫星实时钟差产品的精度。算例表明:采用IGS最终轨道产品实时解算卫星钟差,平均钟差精度达到0.2ns;采用IGS实时轨道产品实时解算卫星钟差,平均钟差精度达到0.25ns;IGS实时钟差产品平均钟差精度达到0.2ns以内。实时估计的钟差和IGS实时钟差产品精度差异有很大一部分是由于双方采用的钟差解算策略不同造成的,IGS实时钟差产品和IGS实时轨道产品是同一软件求解得到,符合性更好,且两种实时钟差产品在精度评定时选择IGS最终钟差产品为参考,这对IGS实时钟差产品的评估也会有利。