一种新的星载GPS定轨滤波算法

针对传统EKF(Extended Kalman Filtering)算法应用于星载GPS(Global Positioning System)低轨卫星定轨时系统噪声方差初值不易确定的问题,提出了一种新的定轨滤波算法.该算法在非线性方程线性化过程中,在前一时刻滤波估值点进行线性化,从而得到扰动方程,并将该扰动方程引入到传统EKF进行滤波处理.该算法与传统EKF分别应用在星载GPS低轨卫星的定轨中,通过比较,结果表明改进的算法在一定程度上抑制了由于系统噪声方差阵选取偏差较大而引起的滤波发散现象,且对于系统噪声方差的初值选取有较强的鲁棒性.      

用于识别两颗故障卫星的RAIM算法

提出了一种可以识别两颗故障卫星的接收机自主完好性监测算法.将最优奇偶矢量法应用于两颗故障卫星识别,指出由于故障偏差可能会抵消而使得正确识别率较低.对最优奇偶矢量法进行了改进,利用对单颗卫星故障敏感的最优奇偶矢量对所有可能的两颗故障卫星组合分别构造两个新的奇偶矢量,用于两颗故障卫星的检测和识别.计算机仿真结果显示,改进后的算法与直接利用最优奇偶矢量法相比,可以显著提高两颗故障卫星正确识别率,识别率可超过90%.同时,改进算法的奇偶矢量构造方法简单,计算量将减少90%以上,更有利于工程实现.      

一种星载GPS接收天线

根据星载 GPS接收天线的主要技术要求 ,给出了谐振式四臂螺旋天线用于星载 GPS天线的设计思路与设计过程 ,并给出了最后的测试结果。结果表明 :该天线具有十分优良的圆对称半球波束特性、良好的广角圆极化特性和优良的阻抗匹配 ,结构紧凑 ,集成度高 ,并通过了环境鉴定试验 ,为星载 GPS应用提供了一种性能优良的天线     

局部可观测理论在INS/GPS机动对准中的应用

从研究INS/GPS(Inertial Navigation System/Global Positioning System)组合系统的姿态角误差可观测性出发,首次将局部可观测性理论应用于INS/GPS组合系统,定量地计算出各种不同机动方式的局部可观测矩阵的条件数,找到了提高姿态角误差可观测性的最佳机动方式.研究结果表明,通过载体做正弦水平机动飞行可以提高姿态角误差局部可观测性,使空中对准时间明显减少,姿态角误差大大降低.当对准时间为120 s时,东北天向姿态角误差的均值分别为12.34″,12.19″和-28.31″,它们的均方根值分别为0.97″,1.05″和0.62″.      

基于双GPS接收机的精密定向研究

GPS定位系统除了可以进行定位、测速和授时外 ,还可以利用两个或多个GPS测量值进行方位测量和三轴姿态测量。文章对利用两块GPSOEM板同步接收的载波相位观测量来精密测定方位进行了深入研究。首先利用载波相位的双差观测方程 ;再根据两个天线间距离已知这个条件 ,对方位和俯仰进行二维搜索 ,并采用了模糊度函数作为搜索的判断依据 ;最后根据最小二乘计算出两个天线的基线矢量 ,从而最终计算出精密的方位值和俯仰角。经过大量的试验表明 ,该算法是切实可行的 ,在 5m基线下 ,方位精度达到 0 0 8°,而且定向时间一般只需 1min左右     

GPS/INU/DM组合定位导航技术在ITS中的应用

 介绍了智能交通系统(ITS,Intelligent Transport Systems)的基本思想,阐述了GPS/INU/DM(Global Positioning System/Inertial Navigation Unit/Digital Map)组合定位导航技术在ITS中的应用,以及提高组合定位导航精度及可靠性的几种技术措施.该组合定位导航是将卫星定位技术、惯性导航定位技术以及计算机技术融合在一起的新型技术,具有全方位、全天候、防遮挡的功能.ITS中利用组合导航技术可实现道路交通管理"自动化"、车辆行驶"智能化",具有良好的实用价值,应用前景广泛.     

钛合金摇臂零件的精密加工技术

归纳总结了钛合金摇臂的数控精密加工技术,工艺基准的选择,加工路线的安排,关键工序和典型特征的加工等.     

月球卫星精密定轨

随着空间应用需求的日益增大,深空探测已成为现实,而月球显然是人类走向深空的首选目标。发射月球探测器通常分3个阶段,其运动状态分别对应3种不同类型的轨道:近地停泊轨道、地月转移轨道和绕月轨道。月球是1个慢自转天体且无大气,就轨道解而言这些因素导致环月卫星的运动与地球卫星有所差别。本文针对月球探测任务的特点,从月球与地球的差别入手,在仔细分析月球卫星的受力状况前提下,着重阐述月球探测器在环月段精密定轨的方法原理和具体实现过程。     

Comparative analysis of four different single-frequency PPP models on positioning performance and atmosphere delay retrieval

Single-frequency precise point positioning (SF-PPP) has attracted increasing attention due to its high precision and cost effectiveness. With various strategies to handle the dominant error, i.e., ionosphere delay, the ionosphere-float (IF), ionosphere-free-half (IFH), ionosphere-corrected (IC), and ionosphere-weighted (IW) SF-PPP models are certain to possess different characteristics and performance levels. This study is dedicated to assessing and comparing the four models from model characteristics, positioning performance, and atmosphere delay retrieval. The model comparison shows that IC and IW models are full-rank while IF and IFH models have a rank deficiency of size one that will result in biased estimations, which means the better solvability of IC and IW models. The experiments are carried out based on the 7-day Global Positioning System (GPS) observations collected at 57 global Multi-GNSS Experiment (MGEX) stations and Global Ionosphere Map (GIM) products. The results indicate that the IW model can accelerate SF-PPP convergence and achieve higher positioning accuracy compared to the other three SF-PPP models, especially in kinematic mode. With convergence criteria of 0.25 m in horizontal and 0.5 m in vertical, the east/north/up convergence times of IW model are 0.5/15.0/25.0 min and 0.5/16.0/36.5 min for static and kinematic modes, respectively. The IW model is able to achieve an instantaneous positioning accuracy of 0.28/0.35/0.75 m. In addition, a real kinematic test also demonstrates the best positioning solutions of IW model. Regarding troposphere delay retrieval, the IF, IFH, and IW models obtain a comparable daily accuracy of 3.0 cm on average, while the IC model achieves the worst accuracy of 8.0 cm. For precise ionosphere delay estimation, IW model only needs an average initialization time of 34.3 min, but a longer initialization time of 51.6 min is required for IF model. The daily precision of ionosphere delay estimation for IW model can reach up to 10.8 cm. At the present accuracy of GIM products, it is suggested that the IW model should be adopted for SF-PPP first due to its superior performance in positioning and atmosphere delay retrieval.     

Application of CCD drift-scan photoelectric technique on monitoring GEO satellites

Geosynchronous Earth Orbit (GEO) satellites are widely used because of their unique characteristics of high-orbit and remaining permanently in the same area of the sky. Precise monitoring of GEO satellites can provide a key reference for the judgment of satellite operation status, the capture and identification of targets, and the analysis of collision warning. The observation using ground-based optical telescopes plays an important role in the field of monitoring GEO targets. Different from distant celestial bodies, there is a relative movement between the GEO target and the background reference stars, which makes the conventional observation method limited for long focal length telescopes. CCD drift-scan photoelectric technique is applied on monitoring GEO targets. In the case of parking the telescope, the good round images of the background reference stars and the GEO target at the same sky region can be obtained through the alternating observation of CCD drift-scan mode and CCD stare mode, so as to improve the precision of celestial positioning for the GEO target. Observation experiments of GEO targets were carried out with 1.56-meter telescope of Shanghai Astronomical Observatory. The results show that the application of CCD drift-scan photoelectric technique makes the precision of observing the GEO target reach the level of 0.2″, which gives full play to the advantage of the long focal length of the telescope. The effect of orbit improvement based on multi-pass of observations is obvious and the prediction precision of extrapolating to 72-h is in the order of several arc seconds in azimuth and elevation.