Orbit and clock products for quad-system satellites with undifferenced ambiguity fixing approach

IF 9 1区 地球科学 Q1 ENGINEERING, AEROSPACE
Jiaqi Wu, Xingxing Li, Yongqiang Yuan, Keke Zhang, Xin Li, Jiaqing Lou, Yun Xiong
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引用次数: 0

Abstract

Integer Ambiguity Resolution (IAR) can significantly improve the accuracy of GNSS Precise Orbit Determination (POD). Traditionally, the IAR in POD is achieved at the Double Differenced (DD) level. In this contribution, we develop an Un-Differenced (UD) IAR method for Global Positioning System (GPS)+ BeiDou Navigation Satellite System (BDS) + Galileo navigation satellite system (Galileo)+ Global'naya Navigatsionnaya Sputnikovaya Sistema (GLONASS) quad-system POD by calibrating UD ambiguities in the raw carrier phase and generating the so-called carrier range. Based on this method, we generate the UD ambiguity-fixed orbit and clock products for the Wuhan Innovation Application Center (IAC) of the International GNSS Monitoring and Assessment System (iGMAS). One-year observations in 2020 from 150 stations are employed to investigate performance of orbit and clock products. Notably, the UD Ambiguity Resolution (AR) yields more resolved integer ambiguities than the traditional DD AR, scaling up to 9%, attributable to its avoidance of station baseline formation. Benefiting from the removal of ambiguity parameters, the computational efficiency of parameter estimation undergoes a substantial 70% improvement. Compared with the float solution, the orbit consistencies of UD AR solution achieve the accuracy of 1.9, 5.2, 2.8, 2.1, and 2.7 cm for GPS, BeiDou-2 Navigation Satellite System (BDS-2), BeiDou-3 Navigation Satellite System (BDS-3), Galileo, and GLONASS satellites respectively, reflecting enhancements of 40%, 24%, 54%, 34%, and 42%. Moreover, the standard deviations of Satellite Laser Ranging (SLR) residuals are spanning 2.5–3.5 cm, underscoring a comparable accuracy to the DD AR solution, with discrepancies below 5%. A notable advantage of UD AR lies in its capability to produce the Integer Recovered Clock (IRC), facilitating Precise Point Positioning (PPP) AR without requiring additional Uncalibrated Phase Delay (UPD) products. To assess the performance of quad-system kinematic PPP based on IRC, a network comprising 120 stations is utilized. In comparison to the float solution, the IRC-based PPP AR accelerates convergence time by 31% and enhance positioning accuracy in the east component by 54%.
采用无差别模糊固定方法的四系统卫星轨道和时钟产品
整数模糊分辨率(IAR)可显著提高全球导航卫星系统精确定位(POD)的精度。传统上,POD 中的 IAR 是在双差分 (DD) 水平上实现的。在本论文中,我们通过校准原始载波相位中的 UD 模糊度并生成所谓的载波范围,为全球定位系统(GPS)+ 北斗导航卫星系统(BDS)+ 伽利略导航卫星系统(Galileo)+ 全球轨道导航卫星系统(GLONASS)四系统 POD 开发了一种非差分(UD)IAR 方法。基于这种方法,我们为国际全球导航卫星系统监测和评估系统(iGMAS)武汉创新应用中心(IAC)生成了 UD 模糊性固定轨道和时钟产品。为研究轨道和时钟产品的性能,采用了来自150个站点的2020年一年期观测数据。值得注意的是,UD模糊度分辨率(AR)比传统的DD模糊度分辨率产生了更多的整数模糊度,比例高达9%,这归功于其避免了台站基线形成。由于消除了模糊参数,参数估计的计算效率大幅提高了 70%。与浮动解相比,UD AR 解法对 GPS、北斗二号卫星导航系统(BDS-2)、北斗三号卫星导航系统(BDS-3)、伽利略卫星和格洛纳斯卫星的轨道一致性精度分别达到了 1.9、5.2、2.8、2.1 和 2.7 厘米,提高了 40%、24%、54%、34% 和 42%。此外,卫星激光测距(SLR)残差的标准偏差在 2.5-3.5 厘米之间,表明其精度与 DD AR 解决方案相当,差异低于 5%。UD AR 的一个显著优势在于它能够生成整数恢复时钟 (IRC),从而为精确点定位 (PPP) AR 提供便利,而无需额外的未校准相位延迟 (UPD) 产品。为了评估基于 IRC 的四系统运动 PPP 性能,使用了一个由 120 个站点组成的网络。与浮动解决方案相比,基于 IRC 的 PPP AR 可将收敛时间缩短 31%,并将东分量的定位精度提高 54%。
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来源期刊
CiteScore
19.40
自引率
6.20%
发文量
25
审稿时长
12 weeks
期刊介绍: Satellite Navigation is dedicated to presenting innovative ideas, new findings, and advancements in the theoretical techniques and applications of satellite navigation. The journal actively invites original articles, reviews, and commentaries to contribute to the exploration and dissemination of knowledge in this field.
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