RGPS在交会对接中的应用

在伪距差分算法中， 目标飞行器的绝对导航误差通过方向余弦影响相对导航精度， 同时由于线性化观测方程引起的模型误差减小， 使其精度随相对距离减小而提高。仿真结果表明位置差分可以用于相对距离大于２００ｍ 阶段， 伪距差分可以用于相对距离２００ｍ 以内阶段， 两种方法的相对速度精度都需要提高。     

一种高效卫星赋形波束用圆极化馈源

本文介绍了一种賦形波束天线用的圆极化馈源。讨论了形成賦形波束的多馈源天线的特殊问题,通过理论及其实验以及它们的相互比较,说明了十字膜片馈源对于解决这类问题的适用性。比较了不同种类馈源对天线覆盖区增益的影响,从而进一步证明了十字膜片馈源的优点。     

磁带机运转对星载CCD相机成像的影响

利用Ｌａｇｒａｎｇｅ方程,建立了磁带轮转动和卫星姿态振动相互影响的仿真模型,并用数值计算方法计算了卫星的姿态振动,仿真分析了对星载线阵ＣＣＤ成像质量的影响。     

SOM神经网络在卫星电源系统故障诊断中的应用

研究了自组织特征映射（SOM）神经网络的结构及学习算法，提出了利用SOM神经网络对输入样本的“聚类”作用，实现对故障模式的分类，并据此对故障进行诊断的新方法，通过对某卫星电源系统故障的诊断实例，验证了该方法是有效可行的，能对卫星电源系统的故障进行准确的实时诊断。     

32颗GPS卫星星座空间覆盖特性建模与仿真

GPS卫星要准确完成定位功能可见卫星数应不少于4颗.通过建立针对低轨、中高轨和大椭圆轨道目标卫星的GPS信号空间几何覆盖模型,利用Matlab计算针对低轨、中高轨和大椭圆轨道的可见卫星数,对目前美国32颗GPS卫星星座的空间覆盖特性进行仿真.仿真结果显示,32颗GPS卫星星座不仅可以对低轨目标实现全轨道覆盖,而且对中高轨和大椭圆轨道也有所覆盖,大大扩展了24颗GPS卫星星座的空间应用.     

Evaluating the feasibility of GPS measurements of SSH on board a ship along the Portuguese West Coast

Aiming to validate coastal altimetry data, an exploratory experiment was carried out, using a survey ship with onboard GPS and motion compensation systems. The ship navigation plan followed a track as coincident as possible with the passage of two altimetry satellites, Envisat and Jason-1, along the Portuguese coast, in June 2007.     

星间链路天线相对姿态的地面模拟

星间链路天线的相对姿态模拟为星间链路的测试验证提供近真实的动态姿态环境,是星间链路系统地面测试的重要组成部分。建立多个坐标系统将两颗卫星天线的位置和姿态联系起来,利用卫星星历将天线的相对姿态表示为一颗卫星天线在另一颗卫星天线坐标系中的方向向量,利用两个二轴转台实现此方向向量,最终通过控制转台的转角模拟卫星天线的相对姿态变化。同时计算天线波束的方向,分析了两颗卫星的可见性。天线相对姿态的模拟为星间链路的建立和保持提供动态测试环境。     

基于四路信号处理的载波锁相环

载波跟踪环是独立导航接收机中最为脆弱的部分,在一定载噪比下,影响载波跟踪环跟踪门限的主要因素是动态应力。科斯塔斯锁相环是最常用的载波跟踪环之一,由于频率牵引范围的限制,其对动态应力非常敏感,该频率牵引范围由最大相位牵引范围决定。传统科斯塔斯锁相环是基于两路信号处理进行载波相位锁定的,其相位牵入范围仅为［-π/2,π/2］。文章提出了一种基于四路信号处理的科斯塔斯锁相环,增加的两路信号分别与原来两路相位相差π/4,其相位牵入范围可以达到［-3π/4,3π/4］,较传统方式提高了1/2。仿真结果显示文中提出的设计方法能够明显提高环路的动态性能     

整星零动量小卫星偏置飞行姿态解耦控制

研究了采用反作用飞轮为执行机构的整星零动量卫星绕Ｘ轴大角度偏置飞行模式的姿态解耦控制问题。首先给出卫星姿态运动学和动力学模型，然后在控制作用中引入非线性项对姿态动力学模型线性化，进一步对线性模型进行状态反馈解耦和极点配置。最后，给出了数学仿真算例和仿真结果。     

Protecting Earth-orbiting spacecraft against micro-meteoroid/orbital debris impact damage using composite structural systems and materials: An overview

Spacecraft that are launched to operate in Earth orbit are susceptible to impacts by meteoroids and pieces of orbital debris (MMOD). The effect of a MMOD particle impact on a spacecraft depends on where the impact occurs, the size, composition, and speed of the impacting object, the function of the impacted system. In order to perform a risk analysis for a particular spacecraft under a specific mission profile, it is important to know whether or not the impacting particle (or its remnants) will exit the rear of an impacted spacecraft wall. A variety of different ballistic limit equations (BLEs) have been developed for many different types of structural wall configurations. BLEs can be used to optimize the design of spacecraft wall parameters so that the resulting configuration is able to withstand the anticipated variety of on-orbit high-speed impact scenarios. While the level of effort exerted in studying the response of metallic multi-wall systems to high speed particle impact is quite substantial, the extent of the effort to study composite material and composite structural systems under similar impact conditions has been much more limited. This paper presents an overview of the activities performed to assess the resiliency of composite structures and materials under high speed projectile impact. The activities reviewed will be those that have been aimed at increasing the level of protection afforded to spacecraft operating in the MMOD environment, and more specifically, on those activities performed to mitigate the mechanical and structural effects of an MMOD impact.