地球非球形对卫星轨道的长期影响及补偿研究

首先建立了地球非球形引力摄动模型,通过对地球非球形引力摄动对卫星轨道的长期影响分析发现,地球非球形引力摄动对卫星轨道升交点赤经和沿迹角的漂移量与时间成近似线性关系;然后推导了通过主动偏置半长轴和倾角的方法来补偿摄动长期影响的计算公式,设计了基于仿真的地球非球形引力摄动补偿方法;最后对GlobalStar星座卫星进行仿真与试验.结果表明,设计的补偿方法是可行的,摄动补偿后在地球非球形引力摄动作用下卫星轨道的长期稳定性得到了很好的保持.     

卫星沿轨道运动对地面覆盖带外沿轨迹的确定

根据单参数平面曲线族包络线求解原理,给出了卫星沿轨道运动对地面覆盖带外沿轨迹的解,井讨论了地球旋转对地面覆盖带的影响。     

地球站天线与卫星天线极化取向对准的计算方法

本文给出了接收通信卫星线极化辐射信号时地球站天线极化取向角的计算公式。使用线极化辐射的通信系统中,地球站天线极化取向随其地理位置而变化。本文利用坐标变换方法导出了实用的计算公式。在地球站的架设、调整中,只要利用所公布的卫星定点经度位置和卫星天线波束指向角数据,加上所架设地球站的地面经纬度,便可算出极化角取向。本文给出的公式不仅用于电视接收站,还可适用于通信地球站。     

对地观测卫星姿态非线性控制方法

针对对地观测卫星姿态控制系统 ,着重考虑干扰、噪声对卫星姿态稳定度的影响。忽略耦合和挠性部件影响 ,也不考虑敏感器和执行机构的动态特性 ,针对卫星定向模式的主调节器设计问题构造了一种简单实用的非线性控制器 ,并分析和验证了该非线性控制器的有效性。     

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.      

高精度UT1-UTC差分预报方法研究

针对卫星导航所需的高精度地球定向参数(EOP)中的UT1-UTC预报问题,提出了基于双差分LS+AR的UT1-UTC参数预报方法。对UT1-UTC观测数据进行跳秒检测、固体地球带谐潮汐项改正,然后对改正后的UT1-UTC数据进行双差分处理,增强数据平稳性;采用最小二乘拟合(LS)与自回归(AR)分析方法对差分处理后的数据进行分析与预报;对预报结果进行逆差分处理与潮汐项改正外推、跳秒恢复,获取高精度的UT1-UTC预报值。通过与国际EOP_PCC预报结果对比表明,UT1-UTC短期预报精度与EOP_PCC较优的预报精度相当,其中1天UT1-UTC预报精度优于0.03ms,优于EOP_PCC预报结果。介绍了北京航天飞行控制中心的UT1-UTC每日例行预报情况。     

地-月L2点中继星月球近旁转移轨道设计

位于地月L2点周期轨道的中继星将首次为"嫦娥4号"月球背面着陆探测任务提供通信中继服务。中继星转移轨道设计是中继任务实施的关键环节。针对中继星转移轨道存在转移时间、近月点高度和halo轨道振幅等约束条件,系统研究了基于月球近旁的地月L2点转移轨道设计方法。首先基于限制性三体模型,分析了halo轨道族与着陆点可见性关系;然后将月球近旁转移轨道分为地月直接转移段和地月动平衡点附近周期轨道拟流形入轨转移段,采用带有状态约束的微分修正算法对这两段轨道进行拼接,得到了从地球附近至目标轨道族的月球近旁转移轨道;最后,针对南族halo轨道分析了halo轨道振幅和月球飞越高度对转移轨道设计的影响,以及转移轨道的入轨相位分布。仿真结果表明:月球近旁转移轨道设计方案具备工程上的可行性与优越性。该方案可以为实际工程任务和应用提供参考。     

Analytical solutions for Earth discontinuous coverage of satellite constellation with repeating ground tracks

This paper presents an analytical model for calculating the Earth discontinuous coverage of satellite constellation with repeating ground tracks by integrating and extending the application of coverage region and route theory. Specifically, the visibility condition for a ground point is represented as a coverage region in the two-dimension map of visibility properties, and the trajectories of satellites with circular orbits and repeating ground tracks are converted to several inclined lines in t...     

Earth observation from space – The issue of environmental sustainability

Remote sensing scientists work under assumptions that should not be taken for granted and should, therefore, be challenged. These assumptions include the following:1. Space, especially Low Earth Orbit (LEO), will always be available to governmental and commercial space entities that launch Earth remote sensing missions.2. Space launches are benign with respect to environmental impacts.3. Minimization of Type 1 error, which provides increased confidence in the experimental outcome, is the best way to assess the significance of environmental change.4. Large-area remote sensing investigations, i.e. national, continental, global studies, are best done from space.5. National space missions should trump international, cooperative space missions to ensure national control and distribution of the data products.At best, all of these points are arguable, and in some cases, they're wrong. Development of observational space systems that are compatible with sustainability principles should be a primary concern when Earth remote sensing space systems are envisioned, designed, and launched. The discussion is based on the hypothesis that reducing the environmental impacts of the data acquisition step, which is at the very beginning of the information stream leading to decision and action, will enhance coherence in the information stream and strengthen the capacity of measurement processes to meet their stated functional goal, i.e. sustainable management of Earth resources. We suggest that unconventional points of view should be adopted and when appropriate, remedial measures considered that could help to reduce the environmental footprint of space remote sensing and of Earth observation and monitoring systems in general. This article discusses these five assumptions in the context of sustainable management of Earth's resources. Taking each assumption in turn, we find the following:(1) Space debris may limit access to Low Earth Orbit over the next decades.(2) Relatively speaking, given that they're rare event, space launches may be benign, but study is merited on upper stratospheric and exospheric layers given the chemical activity associated with rocket combustion by-products.(3) Minimization of Type II error should be considered in situations where minimization of Type I error greatly hampers or precludes our ability to correct the environmental condition being studied.(4) In certain situations, airborne collects may be less expensive and more environmentally benign, and comparative studies should be done to determine which path is wisest.(5) International cooperation and data sharing will reduce instrument and launch costs and mission redundancy. Given fiscal concerns of most of the major space agencies – e.g. NASA, ESA, CNES – it seems prudent to combine resources.     

低轨天基信息定向分发区域分割编码控制方法

为提高低轨指向性信息分发链路的频谱利用效率,从天基分发平台与地面用户的相对位置关系入手,建立了分发指向、编码增益与信道传输容量的量化关系。在此基础上,提出一种低轨天基信息定向分发区域分割编码控制方法,该方法针对不同信息分发区域,采用最小均方误差(MMSE)作为区域分割准则选择编码方式,既提升了信道传输效率也便于工程实现。最后,本文通过仿真分析了方法的效能和性能影响因素,并与现有自适应编码方法进行了对比,验证了本方法的有效性和可靠性。