广播星历旋转误差对低轨星载BDS-3/GPS实时精密定轨影响分析

基于LT-01A卫星星载BDS-3/GPS观测值进行了星载实时精密定轨研究,并重点分析了广播星历旋转误差对实时定轨精度的影响。通过赫尔默特转换评估了所选时段内GPS和BDS-3广播星历轨道旋转误差,显示BDS-3广播星历旋转误差可达-8.7 mas,平均量级较GPS大约2.5倍。BDS-3广播星历经旋转改正后,轨道切向、法向均方根(RMS)误差从25 cm左右提升至10 cm量级,提升幅度超过50%。因此,基于星载BDS-3以及BDS-3/GPS联合的实时定轨精度受BDS-3星历旋转误差影响严重,且主要作用于切向和法向。经过旋转改正后,单独BDS-3实时定轨在切向、法向、径向RMS分别为21.0 cm、10.7 cm及11.2 cm,其切向和法向精度比改正前分别提升15.0%和31.8%;BDS-3与GPS联合定轨进一步提升切向精度至19.4 cm。得益于BDS-3广播星历较高的精度,单BDS-3以及BDS-3/GPS联合的实时定轨在旋转改正前的三维RMS分别为31.9 cm和29.2 cm,较单GPS实时定轨分别提升9.1%和16.8%;添加旋转改正后,其定轨精度分别提升至26.7 cm和25.0 cm,较单GPS实时定轨分别提升22.6%和27.5%。

Data-Driven Heuristic Assisted Memetic Algorithm for Efficient Inter-Satellite Link Scheduling in the BeiDou Navigation Satellite System

Inter-satellite link(ISL)scheduling is required by the BeiDou Navigation Satellite System(BDS)to guarantee the system ranging and communication performance.In the BDS,a great number of ISL scheduling instances must be addressed every day,which will certainly spend a lot of time via normal metaheuristics and hardly meet the quick-response requirements that often occur in real-world applications.To address the dual requirements of normal and quick-response ISL schedulings,a data-driven heuristic assisted memetic algorithm(DHMA)is proposed in this paper,which includes a high-performance memetic algorithm(MA)and a data-driven heuristic.In normal situations,the high-performance MA that hybridizes parallelism,competition,and evolution strategies is performed for high-quality ISL scheduling solutions over time.When in quick-response situations,the data-driven heuristic is performed to quickly schedule high-probability ISLs according to a prediction model,which is trained from the high-quality MA solutions.The main idea of the DHMA is to address normal and quick-response schedulings separately,while high-quality normal scheduling data are trained for quick-response use.In addition,this paper also presents an easy-to-understand ISL scheduling model and its NP-completeness.A seven-day experimental study with 10080 one-minute ISL scheduling instances shows the efficient performance of the DHMA in addressing the ISL scheduling in normal(in 84 hours)and quick-response(in 0.62 hour)situations,which can well meet the dual scheduling requirements in real-world BDS applications.

岸基BDS-R海面测高及其观测值加权方法

随着北斗三号卫星导航系统(BDS-3)的全球组网完成,其反射信号在全球导航卫星系统反射测量(GNSS-R)海面测高领域的应用也更加广泛。为研究BDS-3 B1C反射信号码延迟海面测高性能,以及多星测高数据组合方法,进行了基于B1C码信号的双天线岸基北斗卫星导航系统反射测量(BDS-R)码延迟海面测高实验。利用自主研发的GNSS-R测高软件接收机对实验数据进行事后处理,将测高结果与岸基同步观测的雷达测高仪所测海面高度值进行对比分析,并基于反射信号信噪比(SNR)和卫星高度角加权的方法对多星测高观测值进行加权计算,评定BDS-R海面测高精度。结果表明:自主研发的GNSS-R测高软件接收机可用于海面测高,基于B1C码信号的BDS-R海面测高精度有达到分米级的可能性;根据10 s观测数据平滑可以得到,单颗卫星B1C码信号最优测高结果的均方根误差(RMSE)为0.634 m,平均绝对误差(MAE)为0.507 m,多星测高观测值加权组合最优结果的均方根误差为0.538 m,平均绝对误差为0.500 m,明显优于单星观测精度,最大可提升70%,最小可提升17%;针对同一信号多星GNSS-R测高数据加权方法,应用综合考虑卫星高度角和反射信号信噪比的加权模型优于其他加权模型,测高精度分别比信噪比分段模型、正弦函数模型、指数函数模型、等权模型提升9.4%、9.5%、20.5%、35.2%。

GPS/Galileo/BDS-3广播星历精度分析

为了分析当前GPS(Global Positioning System)、Galileo(Galileo Navigation Satellite System)和BDS-3(Beidou Navigation Satellite System with Global Coverage)广播星历的精度,详细分析研究了各种偏差改正及消除方法,并尽可能地消除了系统误差和粗差对评估结果的影响。选取2021-11-01/12-31共61天MGEX(multi-GNSS experiment)发布的多系统混合广播星历与武汉大学分析中心发布的事后精密星历数据进行实验,对GPS、Galileo和BDS-3近期广播星历精度进行对比分析,实验结果表明:3个系统广播星历整体精度由高到低依次是Galileo、BDS-3和GPS,其空间信号测距误差的RMS(root mean square)分别优于0.17、0.25和0.37 m,整体轨道精度的RMS分别优于0.17、0.12和0.25 m,BDS-3广播星历的轨道精度最高,钟差误差的RMS分别优于0.15、0.23和0.27 m,Galileo广播星历的钟差精度最高。对于GPS卫星的广播星历,blockⅢA卫星钟差和轨道精度均优于其他GPS类型卫星。

不同IGS分析中心BDS-3实时精密轨道和钟差产品精度评估

以2022-11连续7 d的精密星历作为参考,对5家机构(CAS、CNES、GFZ、SHA和WHU)提供的BDS-3实时精密产品进行精度评估。结果表明,目前CAS可提供的BDS-3卫星实时精密产品数量最多,但MEO卫星钟差精度最低,超过0.4 ns;GFZ播发的IGSO卫星产品质量最差,径向轨道误差超过30 cm,钟差精度大于0.8 ns;WHU的产品数据质量最好,径向轨道误差优于4 cm,钟差精度约0.16 ns,但其可用卫星数仅19颗。在定位端,对各机构的实时精密产品进行双频无电离层动态实时PPP定位性能对比,结果显示,CNES、SHA、WHU实时产品定位精度处于同一水平,水平、高程方向总体定位误差约为0.2 m。综合考虑可用卫星数及实时产品数据质量,推荐实时PPP用户使用CNES或SHA实时产品。

GPS/BDS组合导航系统的精密单点定位模型

为了改善单卫星导航系统由于卫星数量较少,导致定位误差高的问题,设计全球定位系统(GPS)/北斗卫星导航系统(BDS)组合导航系统的精密单点定位模型:线性组合处理GPS与BDS的伪距和载波相位观测值,并构建GPS/BDS组合导航系统的组合观测值;接下来利用协方差成形自适应卡尔曼滤波方法,对组合导航系统导航过程中的卫星钟差、电离层延迟等误差实施滤波;再利用滤波处理后组合导航系统的广播星历,获取卫星轨道以及钟差;然后利用经验模型修正对流层延迟,获取相位观测值与伪距的综合改正数;最后利用综合改正数修正组合导航系统的观测方程,构建精密单点定位模型。实验结果表明,GPS/BDS组合导航系统采用所构建模型进行精密单点定位,不同方向定位误差均低于10 cm,证明了提出模型的有效性。

Design of Space-based PNT System Based on BeiDou Navigation Satellite System

BeiDou navigation satellite system(the BeiDou system) is the only PNT(Positioning, Navigation and Tim-ing) resource in China that has coverage of the globe and near-Earth space and provides continuous high-precision,low-cost positioning, navigation and timing solutions for users in a unified spatio-temporal benchmark. As an importantspatio-temporal benchmark transmission system, the BeiDou system is the most important resource for the nationalPNT system to provide a PNT capability under a unified spatial-temporal benchmark. This paper proposes the con-cept, composition and development model of the space-based PNT system design based on the BeiDou system withall its space characteristics, as well as the advantages of the system. It opens up a new direction for the construction ofChina's PNT system and expands a new horizon in the research of a PNT system in China.

复杂测量环境下BDS-3/GPS组合RTK测量性能分析

为比较分析城市道路观测环境下BDS-3/GPS组合RTK测量性能,探讨一种基于卡尔曼滤波算法的RTK测量模型。在统一BDS-3/GPS组合RTK测量时空基准的基础上,建立RTK观测方程模型,利用LAMBDA算法快速确定双差整周模糊度,并基于卡尔曼滤波算法求解RTK观测方程模型测量结果;基于Visual Studio 2020平台,运用C/C++编程语言,设计和开发RTK数据处理软件(KalRTK),并比较分析BDS-3/GPS组合RTK测量结果。通过城市道路实测数据分析结果表明,BDS-3系统沿东西向跟踪卫星能力要略弱于GPS系统;BDS-3/GPS组合RTK测量的平面精度与高程精度均优于1.6cm,点位精度优于2.2cm,与GPS双频RTK测量精度基本相当,但优于BDS-3双频RTK测量精度。

BeiDou Regional Navigation Satellite System Completed

As the 16th BeiDou navigation satellite was successfully launched into space at 23:33 Beijing Time from the Xichang Satellite Launch Center (XSLC) on October 25, 2012, China completed the construction of the BeiDou Regional Navigation Satellite System that starts to officially provide services for most parts of the Asia-Pacific region from December 27. The 16th BeiDou navigation satellite, the last one for the regional BeiDou system, was developed by China Academy of Space Technology under CASC.

China Launches the 11th BeiDou Satellite in Navigation Satellite System

China launched the 11th BeiDou navigation satellite in their BeiDou Navigation Satellite System.The satellite was launched from the Xichang Satellite Launch Center in Sichuan Province on a LM-3C rocket at 0:12 on February 25 (Beijing time) and was put into the predetermined transfer orbit successfully.The geostationary satellite is the first BeiDou navigation satellite launched in 2012 for the

Networking of BeiDou Navigation Satellite System Accelerated with Two New Members

At 4:50 on April 30, China's LM-3B/I rocket, an improved type based on LM-3B, made its debut at the Xichang Satellite Launch Center and successfully sending the 12th and 13th BeiDou Navigation Satellite System satellites into the planned transfer orbit in space. It was the first time that China launched two BeiDou satellites with one rocket. It was

多普勒积分辅助BDS三频周跳探测

针对单频多普勒积分对低采样率数据周跳探测精度较低的问题,提出一种基于北斗卫星导航系统(BDS)三频观测数据的多普勒积分辅助伪距相位组合的周跳探测方法:利用多普勒积分计算历元间伪距变化量,大大减弱多路径效应的影响;并通过选择最优的三频组合系数构造宽巷相位和窄巷伪距组合周跳检测量,提高多普勒积分对低采样率数据的周跳探测精度。实验结果表明,提出的组合方法可以弥补各自的周跳探测盲点,对于不同采样率数据,不仅能有效探测和修复大小周跳、连续周跳和不敏感周跳,还可以准确地辨别1个周期以上的周跳和粗差,具有良好的周跳探测性能。

基于PSO-Elman神经网络BDS导航卫星钟差预报

卫星钟差是导航定位系统定位精度的重要影响因子之一.针对北斗卫星导航系统(BDS)精密钟差预报性能寻优问题,提出一种基于粒子群优化(PSO)算法优化Elman神经网络的钟差预报模型方法(PSO-Elman模型),以解决Elman神经网络局部最优问题对钟差预报结果的影响.首先对钟差产品进行预处理;然后通过PSO算法迭代寻优确定Elman神经网络权值、阈值的初始值,并将进行预处理之后的序列数据进行训练建模;再采用武汉大学国际GNSS服务(IGS)数据分析中心(WHU)提供的BDS精密钟差产品数据进行钟差预测;最后将预测结果还原为预报钟差.结果表明:对比于二次多项式(QP)模型、附加周期项多项式(SA)模型、灰色(GM)模型,PSO-Elman模型精度分别提高90.7%、84.2%、81.6%,稳定度提高85.3%、76.3%、36.1%.实验表明:PSO-Elman模型在1~12 h短期预报模拟结果的预报精度和稳定性有显著提高,验证了提出方法的可行性.

BDS/GPS新型铷原子钟长期特性分析

铷原子钟具有体积小、功耗低等显著优势,被广泛应用于导航卫星。基于星载铷钟技术发展迅速、BDS和GPS新型铷钟性能尚未得到全面分析的研究现状,对两大系统自2017年后发射的16颗星的铷钟进行了长期特性分析。以GFZ中心提供的BDS精密钟差和IGS中心的GPS最终钟差产品为数据基础,根据卫星钟工作原理确定了各表征部分的分析方法。系统特性方面,通过最小二乘拟合计算了卫星钟的短中期漂移率与频率准确度;随机特性方面,对逐日拟合残差序列进行了计算与长期变化趋势分析,通过重叠Hadamard偏差计算了卫星钟稳定度,分析了不同时段的主导噪声类型;周期特性方面,利用频谱分析方法计算了卫星钟长期表征的主周期项,综合轨道误差和运行等因素分析了周期项可能原因。结果表明:BDS/GPS新型铷原子钟的频率准确度达到10-12量级,秒漂和日漂分别达到10^(-19)和10^(-14)量级,万秒稳定度介于1.82×10^(-14)~2.98×10^(-14)之间,天稳定度普遍达到10^(-15)量级,逐日拟合残差精度达到0.1 ns~0.2 ns;所有卫星钟差序列周期特性显著,前三个主周期近似为卫星轨道周期的1倍、2倍和3倍左右。

BDS空间信号的连续性和可用性评估

为了及时评估北斗卫星导航系统(BDS)的空间信号(SIS)可用性和连续性,采用2020-10-01至2021-10-01共1 a的BDS广播星历数据,对BDS中的地球静止轨道卫星(GEO)、倾斜地球同步轨道卫星(IGSO)和中圆地球轨道卫星(MEO)3类卫星进行了可用性和连续性评估。结果表明:3类卫星的单星可用性最优为0.993,平均可用性达到0.991,但也存在如C07、C14号卫星的可用性未达到预期标准(0.98)的现象;SIS的连续性评估中,除个别卫星未达到规范的标准要求外,指数模型和滑窗算法计算的GEO卫星达到0.995,IGSO和MEO均达到0.998;指数模型计算的BDS中GEO、IGSO和MEO卫星的平均连续性分别为0.99729、0.99926、0.99958,而滑窗算法计算得到的平均连续性分别为0.99627、0.99917、0.99939,2种方法计算的BDS 3类卫星的整体连续性分别为0.99914和0.99885,指数模型较滑窗算法计算的SIS连续性偏差不大,与全球定位系统(GPS)相比存在一定差距,总体达到系统设计的指标要求。最后对比分析指数模型算法与滑窗算法,验证了指数模型可用于短期连续性统计。

BDS-2/BDS-3非组合观测模型的中距离相对定位

为了弥补北斗三号全球卫星导航系统(BDS-3)全星座、多频率相对定位以及组合定位方式相关研究的不足,提出一种BDS-2/BDS-3非组合观测模型的中距离相对定位方法:对BDS-3四频和北斗卫星导航(区域)系统(BDS-2)/BDS-3组合双频观测数据,采用多频载波相位观测数据非组合模型进行相对定位解算;分析BDS-2/BDS-3组合的定位性能,并与BDS-2三频、全球定位系统(GPS)双频解算结果进行对比;然后选取4条不同长度基线进行不同系统相对定位解算,对54km基线充分考虑大气延迟误差的影响,并对定位性能进行分析。实验结果表明,BDS-3收敛速度相较于BDS-2有一倍的提升,并略优于GPS,定位精度相较BDS-2可提升大约40%,但略低于GPS;BDS-2/BDS-3组合模式收敛速度最快、定位精度最高,相较GPS在天顶(U)方向可有8.3%的提升,与BDS-3相比在U方向可有22.1%的提升;BDS-2/BDS-3双频组合定位性能优于GPS、BDS-2和BDS-3多频定位结果。

不同方法的BDS-3多频单点测速对比分析

针对北斗三号卫星导航系统(BDS-3)不同测速方法在不同环境下的测速性能缺乏全面评估的问题,提出一种BDS-3多频单点测速对比分析方法:利用BDS-3静态和动态数据,对比分析基于载波相位差分、多普勒、伪距差分方法的BDS-3不同频点静态和动态测速性能。实验结果表明:静态环境下,载波相位差分测速精度最好,可达到mm/s量级,伪距差分测速精度最差,为cm/s至dm/s量级;动态环境下,多普勒和载波相位差分测速的精度较好,水平方向可达到cm/s量级,高程方向约为1 dm/s,伪距差分测速误差较大;对不同频点的测速结果分析表明,BDS-3系统B1I、B1C、B2a、B2b、B3I等5个频点的测速精度基本在同一个量级。

BDS授时性能分析与接收机DCB估计

为了进一步研究北斗卫星导航系统(BDS)的授时性能,对北斗三号(BDS-3)多模式授时性能进行分析,给出采用时间群延迟参数的授时处理方法:指出BDS-3播发的导航信号较北斗二号(BDS-2)增加了B1C、B2a和B2b等民用频点,去掉了性能较差的B2I,并在原有时间群延迟(TGD)参数的基础上增加了TGDB1Cp、TGDB2ap和TGDB2bI等参数,为导航用户提供新频点的延迟改正;然后提出一种特殊情况下的单站接收机差分码偏差(DCB)估计方法,采用连续60 d的观测数据进行BDS-3多模式授时分析。实验结果表明:单频授时精度(RMS)BDS-3较BDS-2提升约5 ns,单频模式受未消除电离层延迟影响严重;单频差分(电离层格网)模式较单频模式有较大改善,相同频点提高约4 ns;双频模式和三频模式表现最优,授时精度优于1ns;全部授时精度优于BDS-3公布的20ns;最后验证估计的接收机DCB在30 d内变化稳定,标准差(STD)不超过0.2 ns。

TESLA-Based Authentication for BeiDou Civil Navigation Message

Due to the civil BeiDou navigation system is open,unauthenticated,and non-encrypted,civilian BeiDou navigation signals may have great security loopholes during transmission or reception.The main security loophole here is spoofing attacks.Spoofing attacks make the positioning or timing results of BeiDou civilian receivers wrong.Such errors may cause a series of security problems,which lays a serious hidden danger for Bei-Dou satellite information security.This article proposes an anti-spoofing method for BeiDou navigation system based on the combination of SM commercial cryptographic algorithm and Timed Efficient Stream Loss-tolerant Authentication(TESLA)for spoofing attacks.In this solution,we use the SM3 algorithm to generate a TESLA key chain with time information,and then use the key in the key chain to generate the message authentication code for the BeiDou D2 navigation message.The message authentication code is inserted into a reserved bit of the D2 navigation message.In addition,this solution uses the SM2 algorithm to protect and encrypt time information in the TESLA key chain to prevent key replay attacks in TESLA.The experimental results tested on the experimental platform built in this paper show that this scheme reduces the possibility of the BeiDou navigation system being deceived and enhances the safety of the BeiDou navigation system.

Modeling and Prediction of Inter-System Bias for GPS/BDS-2/BDS-3 Combined Precision Point Positioning

The combination of Precision Point Positioning(PPP)with Multi-Global Navigation Satellite System(MultiGNSS),called MGPPP,can improve the positioning precision and shorten the convergence time more effectively than the combination of PPP with only the BeiDou Navigation Satellite System(BDS).However,the Inter-System Bias(ISB)measurement of Multi-GNSS,including the time system offset,the coordinate system difference,and the inter-system hardware delay bias,must be considered for Multi-GNSS data fusion processing.The detected ISB can be well modeled and predicted by using a quadratic model(QM),an autoregressive integrated moving average model(ARIMA),as well as the sliding window strategy(SW).In this study,the experimental results indicate that there is no apparent difference in the ISB between BDS-2 and BDS-3 observations if B1I/B3I signals are used.However,an obvious difference in ISB can be found between BDS-2 and BDS-3 observations if B1I/B3I and B1C/B2a signals are used.Meanwhile,the precision of the Predicted ISB(PISB)on the next day of all stations is about 0.1−0.6 ns.Besides,to effectively utilize the PISB,a new strategy for predicting the PISB for MGPPP is proposed.In the proposed strategy,the PISB is used by adding two virtual observation equations,and an adaptive factor is adopted to balance the contribution of the Observed ISB(OISB)and the PISB to the final estimations of ISB.To validate the effectiveness of the proposed method,some experimental schemes are designed and tested under different satellite availability conditions.The results indicate that in open sky environment,the selective utilization of the PISB achieves almost the same positioning precision of MGPPP as the direct utilization of the PISB,but the convergence time of MGPPP is reduced by 7.1%at most in the north(N),east(E),and up(U)components.In the blocked sky environment,the selective utilization of the PISB contributes to more significant improvement of the positioning precision and convergence time than that in the open sky environment.Compared with the direct utilization of the PISB,the selective utilization of the PISB improves the positioning precision and convergence time by 6.7%and 12.7%at most in the N,E,and U components,respectively.