Page 257 - 《高原气象》2025年第6期
P. 257
6 期 王诗涵等:FY-3E/GNOS和COSMIC-2掩星数据质量对比分析 1665
2692. DOI: 10. 5194/amt-12-2679-2019. 7522/j. issn. 1000-0534. 2020. 00098.
Liao M, Zhang P, Yang G L, et al, 2016. Preliminary validation of 容娜, 杨胜朋, 王金成, 等, 2023. 基于 GNSS 掩星资料对往返平飘
the refractivity from the new radio occultation sounder GNOS/FY- 式探空温度观测的质量评估[J]. 高原气象, 42(1): 221-232.
3C[J]. Atmospheric Measurement Techniques, 9: 781-792. DOI: 10. 7522/j. issn. 1000-0534. 2022. 00025. Rong N, Yang S
DOI: 10. 5194/amt-9-781-2016. P, Wang J C, et al, 2023. Quality assessment of round-trip float‐
Rocken C, Anthes R, Exner M, et al, 1997. Analysis and validation ing sounding temperature observations based on GNSS radio oc‐
of GPS/MET data in the neutral atmosphere[J]. Journal of Geo‐ cultation data[J]. Plateau Meteorology, 42(1): 221-232. DOI:
physical Research: Atmospheres, 102(D25): 29849-29866. 10. 7522/j. issn. 1000-0534. 2022. 00025.
DOI: 10. 1029/97JD02400. 王耀兴, 张秋昭, 沈震, 2021. COSMIC掩星反演湿温廓线质量的时
Sokolovskiy S V, 2001. Tracking tropospheric radio occultation sig‐ 空分析[J]. 武汉大学学报(信息科学版), 46(6): 887-894.
nals from low Earth orbit[J]. Radio Science, 36(3): 483-498. Wang Y X, Zhang Q Z, Shen Z, 2021. Spatiotemporal analysis
DOI: 10. 1029/1999RS002305. of the quality of COSMIC occultation-derived temperature and
Xu X, Zou X L, 2020. Comparison of MetOp-A/-B GRAS radio oc‐ humidity profiles[J]. Journal of Wuhan University (Information
cultation data processed by CDAAC and ROM[J]. GPS Solu‐ Science Edition), 46(6): 887-894. DOI: 10. 13203/j. whu‐
tions, 24(1): 34-49. DOI: 10. 1007/s10291-019-0949-5. gis20190051.
Yang S P, Zou X L, 2021. Relationships of along-the-track local varia‐ 徐晓华, 张纪满, 罗佳, 等, 2022. FY-3C 无线电掩星折射率廓线的
tions of GPS RO impact parameter to strong local vertical gradi‐ 反演及验证[J]. 武汉大学学报(信息科学版), 47(1): 36-44.
ent of wet refractivity in the tropics[J]. Science China Earth Sci‐ DOI: 10. 13203/j. whugis20190361. Xu X H, Zhang J M, Luo
ences, 64(11): 2015-2026. doi: 10. 1007/s11430-020-9795-2. J, et al, 2022. Retrieval and validation of refractivity profiles
Zou X L, Zeng Z, 2006. A quality control procedure for GPS radio oc‐ from FY-3C radio occultation data[J]. Journal of Wuhan Universi‐
cultation data[J]. Journal of Geophysical Research: Atmo‐ ty (Information Science Edition), 47(1): 36-44. DOI: 10.
spheres, 111(D2): D02112. DOI: 10. 1029/2005JD005846. 13203/j. whugis20190361.
黄晓龙, 吴薇, 许剑辉, 等, 2023. ERA5-Land降水再分析资料在中 徐晓华, 朱洲宗, 罗佳, 2020. 利用 IGRA2 探空数据和 COSMIC 掩
国西南地区的适用性评估[J]. 高原气象, 42(6): 1562-1575. 星资料对 FY-3C 掩星中性大气产品进行质量分析[J]. 武汉大
DOI: 10. 7522/j. issn. 1000-0534. 2023. 00012. Huang X L, Wu 学学报(信息科学版), 45(3): 384-393. Xu X H, Zhu Z Z,
W, Xu J H, et al, 2023. Applicability evaluation of ERA5-Land Luo J, 2020. Quality analysis of FY-3C radio occultation neutral
precipitation reanalysis data in Southwest China[J]. Plateau Mete‐ atmosphere products using IGRA2 sounding data and COSMIC
orology, 42(6): 1562-1575. DOI: 10. 7522/j. issn. 1000-0534. occultation data[J]. Journal of Wuhan University (Information
2023. 00012. Science Edition), 45(3): 384-393. DOI: 10. 13203/j. whu‐
廖蜜, 张鹏, 毕研盟, 等, 2015. 风云三号气象卫星掩星大气产品精 gis20180490.
度 的 初 步 检 验[J]. 气 象 学 报 , 73(6): 1131-1140. Liao M, 殷延安, 杨胜朋, 2023. 基于不同背景场的云内 COSMIC 掩星资料
Zhang P, Bi Y M, et al, 2015. Preliminary validation of the at‐ 的偏差分析[J]. 高原气象, 42(5): 1351-1360. DOI: 10. 7522/
mospheric occultation products of FY-3 meteorological satellites j. issn. 1000-0534. 2022. 00098. Yin Y A, Yang S P, 2023. Bias
[J]. Acta Meteorologica Sinica, 73(6): 1131-1140. DOI: 10. characteristics of COSMIC RO data within clouds based on differ‐
11676/qxxb2015. 072. ent background fields[J]. Plateau Meteorology, 42(5): 1351-
刘雨萌, 赵林, 李照国, 等, 2025. 一种偏差校正方法在青藏高原夏 1360. DOI: 10. 7522/j. issn. 1000-0534. 2022. 00098.
季 CMIP6 降水数据订正中的应用评估[J]. 高原气象, 44(1): 赵定池, 潘晓滨, 晋鹏, 等, 2016. COSMIC 后期的掩星折射率资料
16-31. DOI: 10. 7522/j. issn. 1000-0534. 2024. 00046. Liu Y 误差特性分析[J]. 气象与环境科学, 39(4): 30-37. Zhao D C,
M, Zhao L, Li Z G, et al, 2025. Evaluation of a bias correction Pan X B, Jin P, et al, 2016. Error characteristic analysis of re‐
method for CMIP6 precipitation data adjustment in the summer fractivity from COSMIC occultation data during the later period
over the Tibetan Plateau[J]. Plateau Meteorology, 44(1): 16- [J]. Meteorological and Environmental Sciences, 39(4): 30-37.
31. DOI: 10. 7522/j. issn. 1000-0534. 2024. 00046. DOI: 10. 16765/j. cnki. 1673-7148. 2016. 04. 005.
孟恬, 杨胜朋, 程华, 2021. GPS掩星观测误差和边界层高度的判别 邹晓蕾, 2012. GPS 无线电掩星资料特点[J]. 气象科技进展, 2(5):
[J]. 高原气象, 40(5): 1189-1201. DOI: 10. 7522/j. issn. 1000- 49-54. DOI: 10. 3969/j. issn. 2095-1973. 2012. 05. 007. Zou X
0534. 2020. 00098. Meng T, Yang S P, Cheng H, 2021. Identifi‐ L, 2012. Characteristics of GPS radio occultation data[J]. Ad‐
cation of GPS occultation observation errors and boundary layer vances in Meteorological Science and Technology, 2(5): 49-54.
heights[J]. Plateau Meteorology, 40(5): 1189-1201. DOI: 10. DOI: 10. 3969/j. issn. 2095-1973. 2012. 05. 007.
