单车单频BDS/GNSS周跳探测与修复模型

针对低成本单频接收机小周跳探测不敏感的问题，提出了一种基于双边累积和算法的周跳探测与修复方法。该方法基于历元间三差观测值常数项，利用CUSUM算法计算载波相位观测值微小变化的累积和统计量。通过模拟发现，该方法对小周跳具有极高的探测敏感性，同时针对北斗异构星座卫星都具有相同的探测与修复效果。实验表明本文方法相较于传统四阶多项式拟合法，对于连续7个历元密集1周周跳与连续5个历元密集3至5周周跳探测准确率提高30%以上，并且周跳修复成功率达到100%。     

基于站际历元二次差模型探测与修复周跳的新方法

周跳探测与修复是高精度动态GPS定位的关键技术之一,直接影响模糊度在航解算的效率。针对动态相对定位中周跳探测方法“三差法”的不足,提出一种基于站际历元二次差模型进行探测与修复周跳的新方法。首先对站际历元间二次差观测值进行粗差探测,以确定发生周跳的卫星以及周跳初值;然后基于残差平方和最小原则搜索周跳备选组合并修复周跳。理论分析和实验结果均表明,当有效共视卫星多于4颗时,大多数情况下,新方法可以准确定位并修复周跳。     

实时精密单点定位中周跳探测与修复的算法研究

提出了一种适用于实时GPS精密单点定位的周跳探测与修复的新算法。该算法步骤为：①利用M-W组合和电离层残差组合初步确定没有发生周跳和可能发生周跳的卫星;②利用当前历元与前一（或几个）历元的L1、L2和Lw观测值和第一步得出的没有发生周跳的卫星信息,采用基于历元间差分观测值的周跳处理模型对可能发生周跳的卫星进行周跳探测;③对第二步中周跳处理失败的卫星进行进一步的精化处理,以尽可能修复周跳。实验表明,新算法在实时GPS精密单点定位中可以准确地探测并修复周跳。     

双频组合法探测与修复周跳的补充

基于双频单站的探测与修复周跳的方法,把伪距历元差与相位历元差组合作为约束条件,利用双频载波相位观测值组合的方法联合进行周跳探测与修复,并主要针对周跳在频率比附近变化时此方法无法探测的缺点,根据具体实例的分析、总结,采用预先插入周跳法进行补充探测,并对产生的周跳进行了有效修复。     

历元间差分定位模型的粗差探测法探测周跳

假设前一历元的测站点为已知点,当前历元的测站点为未知点,当前历元和前一历元相同卫星的相位观测值取差作为观测值,观测值与当前历元点位坐标的函数关系式称为历元间差分定位模型.本文以历元间差分定位模型构造误差方程,进行最小二乘平差,提出应用Baarda数据探测法对差分观测值进行粗差探测,可准确确定观测值中的周跳.实际算例验证...     

利用历元间差分观测值进行参考站周跳探测与修复

载波观测量是高精度卫星导航定位及其相关应用的基础，其整周模糊度的正确解算是实现厘米级导航定位和纳米级授时的关键。周跳探测与修复直接影响整周模糊度解算的性能，尤其对于连续运行参考站网等高精度位置服务的核心基础设施，保证连续可靠的模糊度解算是实现高精度位置服务的重要保障。参考站接收机具有观测值精度高、静止等特点，且采样频率较高（一般为1 Hz），在较短的时间间隔内，电离层延迟、对流层延迟、硬件延迟等误差相关性较强。基于以上特点，本文将历元间差分法应用于参考站周跳探测与修复，结合参考站静止的特性，提出了一种适用于参考站的周跳探测与修复的方法。该方法无需进行观测值组合，同时避免了伪距噪声的影响，探测精度高，且单站各个频率可以单独探测，在周跳修复的过程中，考虑非整周粗差并进行剔除。试验表明，该方法可以准确地探测和修复1周的整周周跳，可以探测小数偏差大于0.1周的非整周粗差。     

GPS/INS紧组合的INS辅助周跳探测与修复

建立了GPS/INS紧组合定位模型,改正惯性器件误差及电离层折射误差,对不同组合观测量的误差影响进行了分析,构造不同观测值组合,提出了基于惯性信息辅助的GPS周跳自适应探测方法,分析了INS定位误差对周跳探测的影响,给出了周跳探测误报率及修复成功率评价指标,提出了一种周跳检测阈值自适应确定方法。利用实测组合导航试验数据验证本文的算法,文中模拟了不同的单历元多周跳及信号失锁条件,结果表明,在GPS信号完全失锁20 s内,该方法能准确检测和修复所有周跳,中断时间的延长降低了周跳修复的成功率;GPS信号部分失锁时,在模拟的90 s中断时段内仍能修复所有周跳;模拟了170历元的5 s间隔密集周跳,周跳探测成功率为100%,正确修复率为99.41%。     

模糊度直接求解算法用于GPS周跳的探测与修复

探测与修复周跳是GPS数据处理中的一个关键问题.针对CPS载波相位定位中出现的周跳问题,本文提出了一种新的周跳探测与修复的方法:首先组成双差相位观测方程,并根据观测文件中的近似坐标求得基线约束条件;随后利用基线约束条件直接求解各个历元的模糊度值,并依据历元间的模糊度变化来探测与修复周跳.通过编写应用程序和实例验证表明这...     

星载双频GPS二次周跳探测方法研究

在利用W-M宽巷组合进行周跳初步探测的基础上,加入了新方法进行二次周跳探测。该方法通过利用来自同颗GPS卫星的无电离层影响L3组合相位观测值在相邻历元间的变化量与dm级精度的先验轨道坐标,计算得出星载GPS接收机历元间的钟差变化值。对于存在周跳的载波相位观测值,其计算结果会与同历元其他无周跳观测值解算的钟差变化量存在较大差异。实验结果表明,二次探测可以发现新的周跳并对初步探测结果进行检核。     

一种面向GPS单频RTK的周跳探测算法

针对传统码-载波相位周跳探测方法应用于单频RTK时,存在的对小周跳不敏感、易受码观测噪声的影响等问题,本文提出一种多普勒观测值辅助的单频周跳探测方法。该方法将连续两个相邻历元多普勒观测值与载波相位差分观测值相结合,以构造实时周跳探测的多普勒-载波相位差分序列。然后应用假设检验方法,检测单频载波相位观测值是否存在周跳。实测数据分析表明:本文提出的方法能够准确探测单频载波相位观测数据中的小周跳,且该方法对周跳探测的灵敏度比传统码-相位差分序列方法更高,适用于单频RTK定位技术。      

A new automated cycle slip detection and repair method for a single dual-frequency GPS receiver

This paper develops a new automated cycle slip detection and repair method that is based on only one single dual-frequency GPS receiver. This method jointly uses the ionospheric total electron contents (TEC) rate (TECR) and Melbourne–Wübbena wide lane (MWWL) linear combination to uniquely determine the cycle slip on both L1 and L2 frequencies. The cycle slips are inferred from the information of ionospheric physical TECR and MWWL ambiguity at the current epoch and that at the previous epoch. The principle of this method is that when there are cycle slips, the MWWL ambiguity will change and the ionospheric TECR will usually be significantly amplified, the part of artificial TECR (caused by cycle slips) being significantly larger than the normal physical TECR. The TECR is calculated based on the dual-frequency carrier phase measurements, and it is highly accurate. We calculate the ionospheric change information (including TECR and TEC acceleration) using the previous epochs (30 epochs in this study) and use the previous data to predict the TECR for the epoch needing cycle slip detection. If the discrepancy is larger than our defined threshold 0.15 TECU/s, cycle slips are regarded to exist at that epoch. The key rational of method is that during a short period (1.0 s in this study) the TECR of physical ionospheric phenomenon will not exceed the threshold. This new algorithm is tested with eight different datasets (including one spaceborne GPS dataset), and the results show that the method can detect and correctly repair almost any cycle slips even under very high level of ionospheric activities (with an average Kp index 7.6 on 31 March 2001). The only exception of a few detected but incorrectly repaired cycle slip is due to a sudden increased pseudorange error on a single satellite (PRN7) under very active ionosphere on 31 March 2001. This method requires dual-frequency carrier phase and pseudorange data from only one single GPS receiver. The other requirement is that the GPS data rate ideally is 1 Hz or higher in order to detect small cycle slips. It is suitable for many applications where one single receiver is used, e.g. real-time kinematic rover station and precise point positioning. An important feature of this method is that it performs cycle slip detection and repair on a satellite-by-satellite basis; thus, the cycle slip detection and repair for each satellite are completely independent and not affected by the data of other satellites.     

A cycle slip fixing method with GPS + GLONASS observations in real-time kinematic PPP

A key limitation of precise point positioning (PPP) is the long convergence time, which requires about 30 min under normal conditions. Frequent cycle slips or data gaps in real-time operation force repeated re-convergence. Repairing cycle slips with GPS data alone in severely blocked environments is difficult. Adding GLONASS data can supply redundant observations, but adds the difficulty of having to deal with differing wavelengths. We propose a single-difference between epoch (SDBE) method to integrate GPS and GLONASS for cycle slip fixing. The inter-system bias can be eliminated by SDBE, thus only one receiver clock parameter is needed for both systems. The inter-frequency bias of GLONASS satellites also cancels in the SDBE, so cycle slips are preserved as integers, and the LAMBDA method is adopted to search for cycle slips. Data from 7 days of 20 globally distributed IGS sites were selected to test the proposed cycle slip fixing procedure with artificial blocking of the signal; cycle slips were introduced for all un-blocked satellites at each epoch. For a 30-s sampling interval, the average success rate of fixing can be improved from 73 to 98 % by adding GLONASS. Even for a 180-s sampling interval, GPS + GLONASS can achieve a success rate of 81 %. A real-time kinematic PPP experiment was also performed, and the results show that using GPS + GLONASS can achieve continuous high-accuracy real-time PPP without re-convergence.     

基于多普勒辅助的电离层残差探测与修复周跳改进方法

针对典型周跳探测与修复方法中的电离层残差法当同一历元多个频点发生周跳时,无法准确探测及修复周跳的问题,提出了一种用多普勒辅助电离层残差法的周跳探测与修复的改进方法。基于实测及仿真数据,证明了该方法能够有效解决电离层残差法存在的上述问题,即使某一历元多个频点同时发生周跳,也可以准确探测周跳发生的位置、频点及相应数值,精度达到1周,有效提高了电离层残差法探测与修复周跳的准确性与可靠性。     

基于无几何电离层滤波模型的北斗三号系统相位周跳与中断修复方法

高精度位置服务依赖模糊度正确固定的载波相位观测值,而复杂环境的相位周跳和中断给模糊度固定和数据处理带来了巨大挑战。北斗三号系统向全球播发四频和五频信号,为提升周跳处理性能提供了机遇。本文建立了探测多频超宽巷周跳的伪距-相位无几何组合模型,以及探测窄巷周跳的相位-相位无几何组合模型,并以周跳探测成功概率最大为准则确定了多频最优超宽巷和窄巷组合。由于电离层延迟制约了数据中断和电离层变化剧烈情况下的窄巷周跳探测,进而建立了顾及电离层延迟的窄巷周跳探测滤波模型。试验结果表明,对30 s采样间隔,基于无几何组合模型探测周跳的成功率均优于96%;对于3 min的数据中断,基于无几何组合模型的周跳探测成功率仅为70%,但补偿电离层延迟的滤波模型将成功率提升至95%以上。     

A double-differenced cycle slip detection and repair method for GNSS CORS network

The difficulty to detect and repair cycle slip of carrier phase measurements is a key limit for continuously high accuracy of GNSS positioning and navigation services. We propose an automated cycle slip detection and repair method for data preprocessing of a CORS network. The method jointly uses double-differenced (DD) geometry-free (GF) combination and ionospheric-free observation corrected for the computed geometrical distance (IF-OMC) to estimate the cycle slips in dual-frequency observations. The DD GF combination, which is only affected by the ionospheric residual, can be used to detect cycle slips with high reliability except for special pairs such as (77, 60) on GPS L1/L2 frequencies. The detection principle of the IF-OMC observable is such that there is a large discontinuity related to the previous epoch when cycle slips occur at the present epoch. The disadvantages of these two combinations can be overcome employing the proposed detection method. The cycle slip pair (77, 60) has no effect on the GF combination, while a change of 14.65 m is derived from GPS L1/L2 observations using the IF-OMC algorithm. Using pre-determined station coordinates as precise values, we found that the accuracy of the DD IF-OMC combination was 18 mm for a 200-km CORS baseline. Therefore, cycle slips in dual-frequency observations can be correctly and uniquely determined using DD GF and IF-OMC equations. The proposed method was verified by adding simulated cycle slips in observations collected from the CORS network under a quiet ionosphere and shown to be effective. Moreover, the method was assessed with observations made during intense ionospheric activity, which generated extensive cycle slips. The results show that the algorithm can detect and repair all cycle slips apart from two exceptions relating to long data gaps.     

惯导辅助的无电离层与宽巷组合周跳探测与修复方法

由于卫星信号被遮挡、低信噪比或接收机运动等原因,载波相位观测值较正常值会发生周跳。为解决这一问题,基于精密单点定位与惯导组合系统,提出了一种有效的惯导辅助周跳探测与修复方法。该方法基于无电离层（ionospheric free,IF）组合与宽巷（wide lane,WL）组合,利用惯导短时高精度信息代替伪距消除站星几何距离,结合历元间差、星间差等建立惯导辅助的IF组合模型和惯导辅助的WL组合模型。惯导辅助的IF组合模型不受电离层延迟影响,但无法探测特殊比例周跳,惯导辅助的WL组合模型波长较长,却无法探测双频等周周跳,两者的综合使用实现了优势互补。实验结果表明,该方法不仅能有效探测出各种大、小、双频等周和特殊比例周跳,而且在一定卫星信号中断时间内能实现周跳瞬时校正。     

星地双向时差测量系统周跳探测与修复算法

随着空间时间频率基准的精度越来越高,需要与之匹配的空间时频传递技术. 基于载波相位的星地双向时差测量方法可以实现更高的时间频率传递精度,但对于复杂的星地环境,由于航天器飞行动态高,时频传递链路的传输频率高,载波多普勒效应大,更容易出现粗差和周跳. 基于此,研究一种适合高动态环境下的星地双向时差测量系统载波相位周跳探测与修复方法,提出一种适用于三频组合模式的双向周跳探测与修复方法. 该方法联合双频码相 (MW)组合法可以实现不同类型周跳的探测与修复,对于上下行三条微波链路均可探测出周跳的存在并实现毫米级周跳修复精度. 进一步对基于载波相位测量的星地双向时差测量系统的星地时间同步性能进行分析,在经过周跳探测与修复,以及链路时延数据处理,其星地时间同步精度优于0.3×10–12 s.      

Cycle slip detection and repair of undifferenced single-frequency GPS carrier phase observations

Cycle slip detection and repair is an important issue in the GPS data processing. Different methods have been developed to detect and repair cycle slips on undifferenced , single- or double-differenced observations. The issue is still crucial for high-precision GPS positioning, especially for the undifferenced GPS observations. A method is proposed to fix cycle slips based on the generalized likelihood ratio (GLR) test. The method has a good performance on cycle slip fixing of undifferenced carrier phase observations on individual frequencies, either on L1 or on L2, without making a linear combination among the observables. The functional model is a piecewise cubic curve fitted to a number of consecutive data using the least squares cubic spline approximation (LS-CSA). For fixing the cycle slips, an integer estimation technique is employed to determine the integer values from the float solution. The performance of the proposed method is then compared with the existing two methods using simulated data. The results on a few GPS data sets with sampling rate of 1 Hz or higher confirm that this method can detect and correct all simulated cycle slips regardless of the size of the cycle slip or the satellite elevation angle. The efficacy of the method is then investigated on the GPS data sets with lower sampling rates of 5, 10, and 30 s. The results indicate that the proposed method always performs the best for the data sets considered. This is thus an appropriate method for cycle slip detection and repair of single-frequency GPS observations.