期刊文献+
任意字段
题名或关键词
题名
关键词
文摘
作者
第一作者
机构
刊名
分类号
参考文献
作者简介
基金资助
栏目信息

Quality control of AIRS total column ozone data within tropical cyclones

Quality control of AIRS total column ozone data within tropical cyclones
原文传递
导出
摘要 The Atmospheric Infrared Sounder (AIRS) provides infrared radiance observations twice daily, which can be used to retrieve total column ozone with high spatial resolution. However, it was found that almost all of the ozone data within typhoons and hurricanes were flagged to be of bad quality by the AIRS original quality control (QC) scheme. This determination was based on the ratio of total precipitable water (TPW) error divided by TPW value, where TPW was an AIRS retrieval product. It was found that the difficulty in finding total column ozone data that could pass AIRS QC was related to the low TPW employed in the AIRS QC algorithm. In this paper, a new two-step QC scheme for AIRS total column ozone is developed. A new ratio is defined which replaces the AIRS TPW with the zonal mean TPW retrieved from the Advanced Microwave Sounding Unit. outliers when the new The first QC step is to remove ratio exceeds 33%. Linear regression models between total column ozone and mean potential vorticity are subsequently developed with daily updates, which are required for future applications of the proposed total ozone QC algorithm to vortex initialization and assimilation of AIRS data. In the second QC step, observations that significantly deviate from the models are further removed using a biweighting algorithm. Numerical results for two typhoon cases and two hurricane cases show that a large amount of good quality AIRS total ozone data is kept within Tropical Cyclones after implementing the proposed QC algorithm. The Atmospheric Infrared Sounder (AIRS) provides infrared radiance observations twice daily, which can be used to retrieve total column ozone with high spatial resolution. However, it was found that almost all of the ozone data within typhoons and hurricanes were flagged to be of bad quality by the AIRS original quality control (QC) scheme. This determination was based on the ratio of total precipitable water (TPW) error divided by TPW value, where TPW was an AIRS retrieval product. It was found that the difficulty in finding total column ozone data that could pass AIRS QC was related to the low TPW employed in the AIRS QC algorithm. In this paper, a new two-step QC scheme for AIRS total column ozone is developed. A new ratio is defined which replaces the AIRS TPW with the zonal mean TPW retrieved from the Advanced Microwave Sounding Unit. outliers when the new The first QC step is to remove ratio exceeds 33%. Linear regression models between total column ozone and mean potential vorticity are subsequently developed with daily updates, which are required for future applications of the proposed total ozone QC algorithm to vortex initialization and assimilation of AIRS data. In the second QC step, observations that significantly deviate from the models are further removed using a biweighting algorithm. Numerical results for two typhoon cases and two hurricane cases show that a large amount of good quality AIRS total ozone data is kept within Tropical Cyclones after implementing the proposed QC algorithm.
作者 Yin LIU Xiaolei ZOU
机构地区 Center of Data Assimilation for Research and Application Key Laboratory of Meteorological Disaster of Ministry of Education Earth System Science Interdisciplinary Center
出处 《Frontiers of Earth Science》 CSCD 2016年第2期222-235,共14页 地球科学前沿(英文版)
关键词 AIRS total column ozone total precipitablewater mean potential vorticity quality control AIRS total column ozone, total precipitablewater, mean potential vorticity, quality control
分类号 P444 [天文地球—大气科学及气象学] X51 [环境科学与工程—环境工程]
  • 相关文献

参考文献23

  • 1Aumann H H, Chahine M T, Gautier C, Goldberg M D, Kalnay E, McMillin L M, Revercomb H, Rosenkranz P W, Smith W L, Staelin D H, Strow L L, Susskind J (2003). AIRS/AMSU/HSB on the Aqua mission: design, science objectives, data products, and processing systems. IEEE Trans Geosci Rem Sens, 41(2): 253-264. 被引量:1
  • 2Bamet C, Manning E, Rosenkranz P, Strow L, Susskind J (2007). AIRS- team Retrieval for Core Products and Geophysical Parameters. AIRS Level 2 ATBD Version 4.0, JPL D-17006, 231 pp. 被引量:1
  • 3Bian J, Gettelman A, Chen H, Pan L L (2007). Validation of satellite ozone profile retrievals using Beijing ozonesonde data. J Geophys Res, 112(D6): D06305. 被引量:1
  • 4Carrier M, Zou X, Lapenta W M (2007). Identifying cloud-uncontami- nated AIRS spectra from cloudy FOV based on cloud-top pressure and weighting functions. Mon Weather Rev, 135(6): 2278 -2294. 被引量:1
  • 5Danielsen E F (1968). Stratospheric-tropospheric exchange based on radio-activity, ozone, and potential vorticity. J Atmos Sci, 25(3): 502-518. 被引量:1
  • 6Davis C, Low-Nam S, Shapiro M A, Zou X, Krueger A J (1999). Direct retrieval of wind from Total Ozone Mapping Spectrometer (TOMS) data: examples from FASTEX. Q J R Meteorol Soc, 125(561): 3375-3391. 被引量:1
  • 7Divakarla M, Bamet C, Goldberg M, Maddy E, Irion F, Newchurch M, Liu X, Wolf W, Flynn L, Labow G, Xiong X, Wei J, Zhou L (2008). Evaluation of Atmospheric Infrared Sounder ozone profiles and total ozone retrievals with matched ozonesonde measurements, ECMWF ozone data, and Ozone Monitoring Instrument retrievals. J Geophys Res, 113(D15): D15308. 被引量:1
  • 8Eyre J R (1989). Inversion of cloudy satellite sounding radiances by nonlinear optimal estimation. I: Theory and simulation for TOVS. Q J R Meteorol Soc, 115(489): 1001-1026. 被引量:1
  • 9Jang K I, Zou X, De Pondeca M S F V, Shapiro M, Davis C, Krueger A (2003). Incorporating TOMS ozone measurements into the prediction of the Washington, D.C., winter storm during 2425. 被引量:1
  • 10Lanzante J R (1996). Resistant, robust and nonparametric techniques for the analysis of climate data: theory and examples, including applications to historical radiosonde station data. Int J Climatol, 16 (11): 1197 -1226. 被引量:1
Frontiers of Earth Science
2016年 第2期

相关作者

内容加载中请稍等...

相关机构

内容加载中请稍等...

相关主题

内容加载中请稍等...

浏览历史

内容加载中请稍等...
;
使用帮助 返回顶部