量子定位系统技术发展及其对导弹武器发展的影响

针对现有导航技术的不足,特别是天基卫星导航技术（如GPS）易受到干扰和破坏,美英两国相续进行了量子定位系统技术的研究。分析了量子定位系统产生的背景,阐述了量子定位系统的概念,对量子定位系统进行了分类,分析了其特点,重点梳理了量子定位系统的发展轨迹,继而分析了量子定位系统对导弹武器发展的影响,最后给出总结。     

基于卫星授时控制器的设计与实现

针对一些小型试验场或舰船上的条件局限性,对授时、控制等参试设备提出了更高的要求,希望提供一种功能全面、携带方便的小型化设备,用以满足试验的多种需求.为解决这个问题,研制了新一代时统设备——卫星授时控制器.基于GPS（全球定位系统）/BDS-Ⅱ（“北斗”二代）卫星授时原理,采用功能较强的微控制器和可编程器件产生多种时频信号、控制信号和模拟导航信息,实现了定时、控制、接收和产生等多重功能,提高了设备的集成性、通用性和便携性;同时采用倍频、锁相、驯服等技术,使设备10 MHz频率源的准确度提高2个量级,卫星同步精度优于50 ns.该控制器已成功应用于移动测控站和舰船试验中,效果良好.     

基于RTS滤波的GPS+BDS非差非组合PPP/INS紧组合模型

GPS高精度定位技术在动态复杂环境中,其定位精度、可靠性和连续性因卫星信号频繁失锁而变差。为此,提出了采用基于RTS滤波(Rauch-Tung-Striebel Filter)的GPS+BDS非差非组合PPP(Precise Point Positioning)与INS(Inertial Navigation System)紧组合模型的策略来克服GPS在动态定位中的弱点。其中,采用GPS+BDS双系统观测数据,可提高PPP解算中的可用卫星数,改善星站间定位几何强度和提高PPP收敛速度;采用PPP/INS紧组合,利用INS的自主定位特性和短期高精度特性,可有效改善复杂环境下的定位精度和连续性;采用RTS滤波,可进一步提高PPP/INS紧组合性能。首先推导了GPS+BDS非差非组合函数模型、PPP/INS紧组合函数模型和RTS滤波函数模型,然后利用一组车载动态数据,对动态GPS PPP、GPS+BDS PPP、GPS/INS紧组合、GPS+BDS PPP/INS紧组合和基于RTS的GPS+BDS PPP/IMU紧组合的定位、测速和定姿性能进行分析。实验结果表明,该方案可有效提高定位(58%～72%)、测速(74%～82%)和定姿(4%～23%)精度,特别是对卫星失锁期间的定位性能改善尤为明显。     

基于机器人视觉的银网焊点定位技术研究

铅锌电池制作工艺过程中的银网焊接工序不仅存在肉眼识别不准确、出错率高的问题,而且劳动强度大、效率低。针对此工艺,提出一种基于机器人视觉的自动化焊点定位方法。系统以机器人搭载自动化焊接设备对焊点精确定位并焊接,采用畸变校正和机器人手眼标定完成了图像坐标系到机器人坐标系之间位置的精确变换,并运用Blob分析粗定位和基于形状的模板匹配精定位相结合的算法,有效地解决了噪声干扰、非线性光照干扰及银网变形引起的识别定位障碍,达到焊点识别定位精度高、生产效率高的目标。     

国家综合PNT体系中的罗兰C导航系统

根据国际、国内构建国家综合定位、导航和授时（PNT）体系和国外增强罗兰（Enhanced Loran-C navigation system，eLORAN）技术及其应用进展情况，分析讨论罗兰C导航系统（远程、低频、脉冲相位距离双曲线导航系统）的eLORAN现代化进程，探讨采用分布式局域eLORAN监测差分站技术，获取并发送实时发播时间改正、系统信号完整性以及地波二次相位因子（ASF）改正等相关信息到用户终端，提升罗兰C导航系统的PNT精度及其服务品质。此外，特别提出研制用户终端的小型化、模块化、智能化、芯片化工作，对拓展国产罗兰C系统应用和建设国家综合PNT体系的重要性。     

Evaluation on real-time dynamic performance of BDS in PPP,RTK, and INS tightly aided modes

Since China’s BeiDou satellite navigation system (BDS) began to provide regional navigation service for Asia-Pacific region after 2012, more new generation BDS satellites have been launched to further expand BDS’s coverage to be global. In this contribution, precise positioning models based on BDS and the corresponding mathematical algorithms are presented in detail. Then, an evaluation on BDS’s real-time dynamic positioning and navigation performance is presented in Precise Point Positioning (PPP), Real-time Kinematic (RTK), Inertial Navigation System (INS) tightly aided PPP and RTK modes by processing a set of land-borne vehicle experiment data. Results indicate that BDS positioning Root Mean Square (RMS) in north, east, and vertical components are 2.0, 2.7, and 7.6?cm in RTK mode and 7.8, 14.7, and 24.8?cm in PPP mode, which are close to GPS positioning accuracy. Meanwhile, with the help of INS, about 38.8%, 67.5%, and 66.5% improvements can be obtained by using PPP/INS tight-integration mode. Such enhancements in RTK/INS tight-integration mode are 14.1%, 34.0%, and 41.9%. Moreover, the accuracy of velocimetry and attitude determination can be improved to be better than 1?cm/s and 0.1°, respectively. Besides, the continuity and reliability of BDS in both PPP and RTK modes can also be ameliorated significantly by INS during satellite signal missing periods.     

Displacement monitoring performance of relative positioning and Precise Point Positioning (PPP) methods using simulation apparatus

Besides the classical geodetic methods, GPS (Global Positioning System) based positioning methods are widely used for monitoring crustal, structural, ground etc., deformations in recent years. Currently, two main GPS positioning methods are used: Relative and Precise Point Positioning (PPP) methods. It is crucial to know which amount of displacement can be detected with these two methods in order to inform their usability according to the types of deformation. Therefore, this study conducted to investigate horizontal and vertical displacement monitoring performance and capability of determining the direction of displacements of both methods using a developed displacement simulator apparatus. For this purpose, 20 simulated displacement tests were handled. Besides the 24?h data sets, 12?h, 8?h, 4?h and 2?h subsets were considered to examine the influence of short time spans. Each data sets were processed using GAMIT/GLOBK and GIPSY/OASIS scientific software for relative and PPP applications respectively and derived displacements were compared to the simulated (true) displacements. Then statistical significance test was applied. Results of the experiment show that using 24?h data sets, relative method can determine up to 6.0?mm horizontal displacement and 12.3?mm vertical displacement, while PPP method can detect 8.1?mm and 19.2?mm displacements in horizontal and vertical directions respectively. Minimum detected displacements are found to grow larger as time spans are shortened.     

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.     

大口径超轻型反射镜定位和支撑方案研究

地球静止轨道光学遥感器的发展以及遥感器分辨率的不断提高,使得光学遥感器的口径越来越大,大口径反射镜正在成为制约遥感器性能、质量和研制成本的关键因素。本文主要围绕2m口径的超轻型反射镜开展研究,分析了定位和支撑系统的主要功能,提出了适合大口径、超轻型反射镜的定位和支撑系统方案,分析了该方案的基本原理和实现形式。     

基于我国VLBI网航天器定位归算仿真分析

结合我国VLBI观测网现状,通过仿真计算分析了观测时延噪声与系统差、预报轨道偏差和测距误差等对航天器定位归算的影响。结果表明,仅利用VLBI跟踪时附加飞行器地心距约束有利于压制定位点的弥散。 3站 VLBI跟踪的定位解是有偏估计,4站跟踪时要求所加约束的误差应与预报轨道偏差相当,若过大将起不到压制定位点弥散的良好效果,若过小则会在定位结果中引入系统偏差。时延与测距的观测噪声主要引起定位点序列的弥散。若观测量存在系统差则将引起定位结果的系统性偏差,而且定位点序列会发生渐近线性趋势跳变。同时,这也可以作为观测量是否存在系统差的判据。另外,若某时刻前后VLBI跟踪站存在3、4站变更,定位点序列有时发生趋势变化。分析结论对于我国后续探月和萤火计划等工程实践具有借鉴意义。