Elevation compensation method and accuracy assessment for COSMIC-2 tropospheric delay

doi:10.13474/j.cnki.11-2246.2025.0916

Abstract

Abstract: In response to the underestimation of COSMIC-2-retrieved zenith tropospheric delay (ZTD)caused by missing near-surface data,this study firstly employs elevation-based scaling factors derived from the ERA5 dataset,then applies a negative exponential model to correct the COSMIC-2 ZTD,and finally validates the correction accuracy using radiosonde measurements and GNSS ZTD data from the crustal movement observation network of China (CMONOC)across China during 2020—2022.The results indicate that,after applying the correction,the mean RMSE of the COSMIC-2 ZTD decreases by 30.95 and 32.48 cm when compared to the radiosonde and GNSS ZTD references,respectively.Moreover,a month-by-month assessment for 2022 shows that the corrected COSMIC-2 ZTD RMSE stabilizes within a range of 2～8 cm.These findings demonstrate the suitability of the negative exponential elevation model for enhancing COSMIC-2 ZTD data over China,providing reliable tropospheric delay corrections that benefit both GNSS navigation and atmospheric water-vapor monitoring.

Key words: zenith tropospheric delay, elevation scaling factor, negative exponential elevation model, COSMIC-2 radio occultation, ERA5 reanalysis data

CLC Number:

P228

WU Angdao, TANG Xu. Elevation compensation method and accuracy assessment for COSMIC-2 tropospheric delay[J]. Bulletin of Surveying and Mapping, 2025, 0(9): 98-104.

References

[1] GLEISNER H, RINGER M A, HEALY S B.Monitoring global climate change using GNSS radio occultation[J].NPJ Climate and Atmospheric Science, 2022, 5: 6.
[2] KUO Y H, WEE T K, SOKOLOVSKIY S, et al.Inversion and error estimation of GPS radio occultation data[J].Journal of the Meteorological Society of Japan Ser II, 2004, 82(1B): 507-531.
[3] HEALY S B, THÉPAUT J N.Assimilation experiments with CHAMP GPS radio occultation measurements[J].Quarterly Journal of the Royal Meteorological Society, 2006, 132(615): 605-623.
[4] HO S P, ANTHES R A, AO C O, et al.The COSMIC/FORMOSAT-3 radio occultation mission after 12 years: accomplishments, remaining challenges, and potential impacts of COSMIC-2[J].Bulletin of the American Meteorological Society, 2020, 101(7): E1107-E1136.
[5] 章迪.GNSS对流层天顶延迟模型及映射函数研究[J].测绘学报, 2022, 51(9): 1984.
[6] 韦廖军, 莫懦, 任晓斌, 等.基于改进注意力机制CNN-ATT的区域性ZTD预测模型[J].导航定位与授时, 2024, 11(3): 85-100.
[7] 王倩倩.IF组合PPP及反距离加权法解算ZTD的精度分析[J].测绘与空间地理信息, 2023, 46(11): 84-86.
[8] 白子仪, 徐莹, 冯健, 等.基于机器学习的NWP ZTD长短期预测模型[J].导航定位学报, 2024, 12(4): 34-44.
[9] 李宗勋, 朱葛, 林泽荣.一种基于多项式函数的中国区域ZTD垂直改正模型[J].测绘科学, 2023, 48(10): 20-27.
[10] 胡方鑫, 叶世榕, 罗佳, 等.COSMIC-2近实时廓线反演对流层延迟及其质量分析[J].导航定位学报, 2024, 12(5): 27-35.
[11] 王大钊, 白伟华, 孙越强, 等.GNSS掩星探测大气反演算法的对比[C]//中国空间科学学会空间探测专业委员会第二十六届全国空间探测学术研讨会会议论文集.琼海:[s.n.], 2013: 613-620.
[12] 陈永潮.北半球区域对流层延迟模型研究[D].南京: 东南大学, 2017.
[13] 屈凯锋.中国大陆测站天顶对流层延迟模型[J].工程勘察, 2021, 49(7): 64-69.
[14] 谢劭峰, 潘清莹, 黄良珂, 等.中国区域ZTD、ZWD高程缩放因子的时空特性分析[J].大地测量与地球动力学, 2021, 41(12): 1211-1215.
[15] 陈冰, 龚绍琦, 张存杰, 等.COSMIC掩星大气水汽廓线的质量分析[J].地理与地理信息科学, 2021, 37(4): 37-44.