| FY-3B/VIRR海表温度算法改进及精度评估 |
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| 引用本文: | 王素娟,崔鹏,张鹏,冉茂农,陆风,王维和.FY-3B/VIRR海表温度算法改进及精度评估[J].应用气象学报,2014,25(6):701-710. |
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| 作者姓名: | 王素娟 崔鹏 张鹏 冉茂农 陆风 王维和 |
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| 作者单位: | 1.国家卫星气象中心,北京 100081 |
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| 基金项目: | 国家自然科学基金项目(41075021,41175023),中国气象局关键技术集成与应用项目(CMAGJ2014M66) |
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| 摘 要: | 该文介绍了卫星观测海表温度 (SST) 算法的发展历程,给出了所用SST算法的回归模型,并在FY-3B/VIRR业务SST算法的基础上进行了改进。基于NOAA-19/AVHRR匹配数据集,进行多算法建模分析及精度评估,白天最优算法为非线性SST (NL) 算法,夜间最优算法为三通道SST (TC) 算法,最优算法的确定与NESDIS/STAR一致。建立2012年8月—2013年3月FY-3B/VIRR匹配数据集,并在此基础上进行多算法回归建模及精度评估,白天和夜间的最优均为NL算法,分析发现夜间TC算法采用匹配数据集版本2(MDB_V2) 时,3.7 μm通道存在类似百叶窗的条带现象。以2012年10—12月FY-3B/VIRR匹配数据集计算回归系数,以2013年1—3月独立样本进行精度评估,与浮标SST相比,NL算法白天和夜间的均方根误差分别为0.41℃和0.43℃。与日平均最优插值海温 (OISST) 相比,NL算法白天和夜间的均方根误差分别为1.45℃和1.5℃; 选择与OISST偏差在2℃以内的样本,NL算法白天和夜间均方根误差分别为0.82℃和0.84℃。
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| 关 键 词: | FY-3B气象卫星 可见光红外扫描辐射计 (VIRR) 海表温度 算法 |
| 收稿时间: | 2014-03-12 |
The Improvement of FY 3B/VIRR SST Algorithm and Its Accuracy |
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| Wang Sujuan,Cui Peng,Zhang Peng,Ran Maonong,Lu Feng and Wang Weihe.The Improvement of FY 3B/VIRR SST Algorithm and Its Accuracy[J].Quarterly Journal of Applied Meteorology,2014,25(6):701-710. |
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| Authors: | Wang Sujuan Cui Peng Zhang Peng Ran Maonong Lu Feng and Wang Weihe |
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| Affiliation: | 1.National Satellite Meteorological Center, Beijing 1000812.Beijing Huayun Shinetek Satellite Application Engineering Technology Company Limited, Beijing 100081 |
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| Abstract: | The evolution of sea surface temperature (SST) algorithms is introduced and a set of SST regression formalisms are given. Some improvements are made based on operational SST algorithm from FY-3B meteorological satellite visible and infrared radiometer (VIRR) data. On matching algorithm, quality controlled in situ data from the in situ quality monitor (iQUAM) is used to improve the input data precision of regression. Fields of matchup database (MDB) are enlarged to provide the convenience for error analysis. Pixels with "confident clear" flag in FY-3B/VIRR cloud mask (CLM) products are matched up to form gross matchups, and then tightly filtered by some tests to form tight matchups, which make the sample selection more reasonable. On regression algorithm, based on least-square regression used for the early operational SST product, the robust regression is developed, and its performance is tested by NOAA-19/AVHRR MDB of 2010. It shows that the precision of SST is increased by 21% in daytime with split-window non-linear SST (NL) algorithm and 30% in nighttime with triple-window MC (TC) algorithm. On retrieval algorithm, the spatial uniformity test and climate reference test are introduced, the unidentified cloud (especially at night) is excluded and the SST retrieval precision is improved.A set of SST regression formalisms are tested based on NOAA-19/AVHRR 2010 MDB. It shows NL is the best algorithm for daytime while TC is the best algorithm for nighttime, which is accordant with NESDIS/STAR. The monthly MDB is created from FY-3B/VIRR measurements paired with coincident SST measurements from buoys data.The same regression analysis method is also used on FY-3B/VIRR MDB. Comparing three daytime SST algorithms and five nighttime SST algorithms, the best algorithm to retrieve FY-3B/VIRR SST is NL both in daytime and nighttime. It shows for FY-3B/VIRR nighttime TC, the contribution of 3.7 μm band is smaller than split-window bands, and the calibration of 3.7 μm band has stripe phenomenon. A three-month MDB from October to December in 2012 is used to derive coefficients. An independent MDB from January to March in 2013 is used to access the accuracy of the best NL algorithm for FY-3B/VIRR. Based on matchup analyses, the root mean square error (RMSE) between FY-3B/VIRR SST and in situ SST is 0.41℃ (NL_D) and 0.43℃ (NL_N). Compare with Daily Optimum Interpolation SST (OISST), the RMSE of FY-3B/VIRR SST is 1.45℃ (NL_D) and 1.5℃ (NL_N). When the absolute difference between FY-3B/VIRR SST and OISST is within 2℃, the RMSE is 0.82℃ (NL_D) and 0.84℃ (NL_N). |
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| Keywords: | FY 3B meteorological statellite visible and infrared radiometer(VIRR) sea surface temperature algorithm |
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