用辐射传输方程改进算法反演LandSAT8海表温度的效果检验和适用条件分析

为检验辐射传输方程改进算法推广用于反演LandSAT8 海表温度(SST)的可行性及适用条件,本研究在修订算法部分参数的基础上,分别反演出算法改进前后的LandSAT8 SST并进行比较。MODIS SST验证表明改进算法对大气透过率偏差和SST偏差均有明显改善,除2019-08-21图像外,其他3景图像SST偏差在0.5℃左右;浮标SST验证表明改进算法在近岸海域对SST偏差改善效果同样显著,其平均偏差bias和均方根误差rmse分别减少到0.14、0.18℃,基本可以忽略不计;进一步研究发现,改进算法SST反演精度与研究海域大气透过率分布均匀程度呈显著的正相关关系,R²[bias(SST)]=0.920 7,R²[rmse(SST)]=0.934 0。使用改进算法遥感监测电厂温排水：嵩屿电厂表层海水温升羽流不明显;而后石电厂表层温升现象最显著,温升幅度和扩散影响范围最大,在其排水口附近存在稳定的高温水体(温升＞3℃);晋江电厂表层温升羽流呈扇形分布,流轴短,主要集中在排水口附近。     

HY1C/1D海表温度对Terra/Aqua产品的可替代性分析

通过卫星遥感获取的海表温度（SST）产品已经成为海洋和大气研究中的重要数据源,我国海洋水色遥感卫星（HY1C和HY1D）的海洋水色水温扫描仪（COCTS）具有两个热红外通道,可反演全球SST遥感产品。对比Terra和Aqua卫星的中分辨率成像光谱仪（MODIS）的SST产品,分析COCTS海表温度产品对MODIS相应产品的可替代性。比较了两种卫星的全球SST单日和月平均融合产品的图像空间结构,分析了匹配像元SST值的离散度,统计了HY1C/1D的误差结果,讨论了HY1C与HY1D产品的一致性、不同质量控制方案对SST产品影响以及遥感产品质量对昼夜SST变化研究影响等问题。结果表明,以2020年6月SST(Terra)为真值,HY1C白天SST的单日全球遥感产品的平均偏差、绝对偏差、均方根误差和相关系数分别为0.04℃、0.60℃、0.78℃和0.98,夜晚SST的单日全球遥感产品的平均偏差、绝对偏差、均方根误差和相关系数分别为-0.16℃、0.78℃、0.95℃和0.86。以2020年6月SST(Aqua)为真值,HY1D白天SST的单日全球遥感产品的平均偏差、绝对偏差、均方根误差和相...     

MODIS月平均海面温度在太平洋的检验与在南海的应用

使用由我国投放的位于太平洋海域的ARGO浮标表屡温度数据,对相应时相和海区的MODIS月平均海洋表面温度(SST)产品进行检验,验证结果表明,MODIS月平均SST产品的均方根误差为0.78℃,平均偏差为-0.37 ℃,二者的相关系数为0.994 5,因此,使用MODIS月平均SST数据对我国南海表层水温年变化规律进行...     

台湾海峡MODIS遥感SST的初步验证

海表层温度（SST）是一个决定海气相互作用以及生物栖息条件适宜性的海洋环境关键参数,可以通过卫星遥感手段获取,对检验锋面多发、水文条件复杂的近岸区域卫星遥感SST产品的真实性,具有重要意义．本文采用大型海洋环境多层监测浮标获取的SST数据对台湾海峡MODIS遥感SST产品进行检验．结果表明,MODIS遥感与实测SST数据具有很好的一致性,两者的均方根误差为0．5l℃,平均偏差为一0．02℃,平均绝对偏差为0．42℃,相关系数为0．988;MODIS遥感与实测SST数据之间可能存在季节性差异,均方根误差以夏季最大．     

基于星载微波辐射低频双极化通道观测数据的微波辐射传输模型

微波辐射传输方程是海洋-大气微波遥感的理论基础,本文基于晴空条件下AMSR-E 10.7GHz水平与垂直极化亮温数据,将平静海面的亮温观测结果与4种海水相对电容率模型和2种大气水汽吸收模型的计算结果进行比较,确定了海水相对电容率模型与水汽吸收模型,基于上述模型和实测亮温数据反演了风致各项同性海面发射率,其与已有的经验模型结果基本一致,由此建立了星载微波辐射传输模型;利用建立的辐射传输模型计算亮温与AMSR-E观测亮温分别反演了海表面温度与海表面风速,验证了所建微波传输模型的有效性。本文的研究结果可为星载微波辐射计亮温定标、海洋地球物理参数提取奠定基础。     

HJ-1B 卫星海表温度定量反演业务化算法研究——以中国北部海区为例

利用中国2008年9月发射的自主 HJ-1B 卫星热红外遥感影像数据,基于实测数据对已有海表温度反演的单窗算法进行了改进与简化,重新订正了大气透射率和大气平均作用温度估算方程,建立了基于实测数据验证的 HJ-1B 卫星海表温度定量反演业务化算法.将本算法与段四波等的改进算法用于实验海区海表温度的反演,反演结果与卫星同步实测海温数据的对比表明:本研究算法反演结果与现场同步实测海表温度平均误差约为0.76,℃段四波等改进算法反演结果平均误差约为1.09℃.本算法为 HJ-1B 卫星海表温度产品的业务化应用提供了便捷可行的方案     

利用Landsat数据反演近岸海水表层温度的大气校正算法

介绍了一种将大气效应考虑在内、利用Landsat TM、ETM+热红外数据进行近海岸海表水温反演的单窗算法.在该算法中,将地表气温、相对湿度等常规气象资料作为初始参数,根据对流层中大气温度随高度呈线性降低、水汽随高度呈指数衰减的规律,建立了估算平均大气温度及水汽含量的通用模式.通过与实测数据及MODIS Terra海表水温产品比较发现,该算法能够提高运用TM/ETM+TIR单波段数据进行近岸海表水温(SST)反演的精度:一方面,反演所得结果更接近于海表实际水温;另一方面,它在一定程度上剔除大气中的水汽对SST反演的影响,进而提高海表水温的温度对比度.该提出的大气校正算法只需地表大气温度及相对湿度资料,该算法也无需进行大气模式的界定.     

南海区域红外波段大气透过特征分析

利用MODTRAN大气辐射传输模型,输入我国南海区域大气廓线数据,对比分析气溶胶对红外波段大气透过特性的影响。研究表明,气溶胶、温度和季节对该波段在大气中传输均有一定影响;南海区域大气透过率随季节变化很大,夏季比冬季小10%以上,00时大气透过率略大于12时;采用近似国外模式大气带来的误差最大可达到50%以上。该研究结果充分说明:在红外波段大气透过率计算中引入实际大气廓线数据具有重要的军事和工程应用意义。     

基于最优插值和贝叶斯最大熵的海表温度融合方法研究

海表温度(sea surface temperature,SST)是影响全球气候的重要因素,在海洋科学研究中占有关键位置。论文基于MODIS红外、AMSR-2和HY-2A微波辐射计数据,分别利用最优插值和贝叶斯最大熵方法对SST数据进行融合,并用i Quam实测数据和Argo浮标数据对2015年SST融合数据进行检验。MODIS、AMSR-2、HY-2A辐射计SST的年平均空间覆盖率分别为15.0%,21.6%,22.0%,最优插值和贝叶斯最大熵融合SST产品的年平均空间覆盖率提高到98.6%和99.4%,融合产品空间覆盖率明显提高。与i Quam实测数据对比,最优插值和贝叶斯最大熵融合产品年平均偏差分别为0.07℃,0.04℃,均方根误差皆为0.78℃,其中3-7月最优插值融合产品的精度略优于贝叶斯最大熵融合产品,其它月份则相反;与Argo浮标数据对比,两种融合产品的均值偏差分别为0.06℃,0.01℃,均方根误差分别为0.77℃,0.75℃。整体上,贝叶斯最大熵融合产品的精度略优于最优插值融合产品,但计算成本较高。     

基于志愿观测船舶和浮标数据的SST日产品质量评价研究

选用浮标、志愿观测船舶(VOS)数据作为验证数据对MODIS Aqua,MODIS Terra,AVHRR-OI,OSTIA和RTG五种SST日产品进行了时相差异、近海SST偏差和SST偏差区域整体差异分析的质量评价,以期为日产品的后续应用提供依据。结果表明:不同分析方案得到结论基本一致,在时相差异方面,各季节及年度分析显示各日产品优劣特性相近,其中AVHRR-OI最优(年数据分析回归系数为0.973 6,R2为0.976 0,RMSE为0.71℃),RTG、MODIS Aqua和MODIS Terra次之,OSTIA最差(年数据分析回归系数为0.945 4,R2为0.943 7,RMSE为1.08℃);在近海区域,AVHRR-OI比其他日产品能更真实地反映海表温度状况,OSTIA最差(二者Grade分别为30和13);在海洋表面区域整体特性方面,AVHRR-OI日产品质量在研究区海域存在更少的高正值和低负值,且均值和RMSE也更理想(最低仅分别为0.40和0.59℃);而RTG和OSTIA则差于AVHRR-OI。     

利用南大洋漂流浮标数据评估AMSR-E SST

利用AOML(Atlantic Oceanographical and Meteorological Laboratory)SVP漂流浮标的海表面温度数据,针对30°S以南的南大洋海域,对目前主要使用的微波遥感产品(AMSR-E,Ad-vanced Microwave Scanning Radiometer for the Earth Observing System)反演的SST进行了较为系统的评估。结果表明,AMSR-E SST比浮标数据偏冷,偏差为-0.01℃,标准差为0.70℃。夏季的偏差为0.004℃,标准差为0.64℃;冬季的偏差为-0.06℃,标准差为0.75℃,冬季的偏差和标准差较大。温差ΔT受流速影响,随着流速的增大而减小,且这种趋势在夏季更为显著。具备托伞结构的浮标与总体情况基本一致,而无托伞结构的浮标受流速的影响要大一些。同时,温差ΔT受水汽的影响,随着水汽的增加而减小,且这种影响在冬季更大一些。进一步对4个穿极和绕极浮标的追踪分析表明,温差ΔT受大洋海流系统的影响显著。在海流大的大西洋边界流和南极绕极流中,温差ΔT的不确定性要明显大于总体情况。     

Generation of high resolution sea surface temperature using multi-satellite data for operational oceanography

In the present article, we introduce a high resolution sea surface temperature(SST) product generated daily by Korea Institute of Ocean Science and Technology(KIOST). The SST product is comprised of four sets of data including eight-hour and daily average SST data of 1 km resolution, and is based on the four infrared(IR) satellite SST data acquired by advanced very high resolution radiometer(AVHRR), Moderate Resolution Imaging Spectroradiometer(MODIS), Multifunctional Transport Satellites-2(MTSAT-2) Imager and Meteorological Imager(MI), two microwave radiometer SSTs acquired by Advanced Microwave Scanning Radiometer 2(AMSR2), and Wind SAT with in-situ temperature data. These input satellite and in-situ SST data are merged by using the optimal interpolation(OI) algorithm. The root-mean-square-errors(RMSEs) of satellite and in-situ data are used as a weighting value in the OI algorithm. As a pilot product, four SST data sets were generated daily from January to December 2013. In the comparison between the SSTs measured by moored buoys and the daily mean KIOST SSTs, the estimated RMSE was 0.71°C and the bias value was –0.08°C. The largest RMSE and bias were 0.86 and –0.26°C respectively, observed at a buoy site in the boundary region of warm and cold waters with increased physical variability in the Sea of Japan/East Sea. Other site near the coasts shows a lower RMSE value of 0.60°C than those at the open waters. To investigate the spatial distributions of SST, the Group for High Resolution Sea Surface Temperature(GHRSST) product was used in the comparison of temperature gradients, and it was shown that the KIOST SST product represents well the water mass structures around the Korean Peninsula. The KIOST SST product generated from both satellite and buoy data is expected to make substantial contribution to the Korea Operational Oceanographic System(KOOS) as an input parameter for data assimilation.     

3套不同的SST再分析数据与中国近海浮标观测的对比研究

基于自然资源部浮标数据,通过分析均值差、均方根误差、相关系数和标准差偏差4个统计量,检验了2018年7月1日至8月6日全时段及该时段内3个台风（1808号台风“玛利亚”、1810号台风“安比”、1812号台风“云雀”）过境期间,3套海表面温度（Sea Surface Temperature,SST）再分析资料（OISST、OSTIA SST、RTG SST）在中国近海区域的可靠性。对比结果表明,在全时段内,3套SST再分析资料都能在一定程度上反映中国近海SST的基本状况,其中OSTIA SST资料同浮标实测SST数据的均值差为0.12℃、相关系数为0.94,均优于OISST资料（均值差为–0.85℃、相关系数为0.90）和RTG SST资料（均值差为–0.17℃、相关系数为0.86）。通过对比单个浮标数据发现,相较约80%的MF浮标实测SST数据,OSTIA SST资料都显著优于RTG SST资料和OISST资料,具有较高的可信度。在台风过境期间,较之RTG SST资料和OISST资料,OSTIA SST资料同大部分浮标实测数据的均值差绝对值及均方根误差更小、相关系数更大,表明在高海况条件下,OSTIA SST资料能更真实地反映中国近海SST的基本状况。     

基于最优插值方法的微波-红外辐射计数据融合全球海面温度网格产品

A new 0.1° gridded daily sea surface temperature(SST) data product is presented covering the years 2003–2015. It is created by fusing satellite SST data retrievals from four microwave(Wind Sat, AMSR-E, ASMR2 and HY-2 A RM)and two infrared(MODIS and AVHRR) radiometers(RMs) based on the optimum interpolation(OI) method. The effect of including HY-2 A RM SST data in the fusion product is studied, and the accuracy of the new SST product is determined by various comparisons with moored and drifting buoy measurements. An evaluation using global tropical moored buoy measurements shows that the root mean square error(RMSE) of the new gridded SST product is generally less than 0.5℃. A comparison with US National Data Buoy Center meteorological and oceanographic moored buoy observations shows that the RMSE of the new product is generally less than 0.8℃. A comparison with measurements from drifting buoys shows an RMSE of 0.52–0.69℃. Furthermore, the consistency of the new gridded SST dataset and the Remote Sensing Systems microwave-infrared SST dataset is evaluated, and the result shows that no significant inconsistency exists between these two products.     

基于变分理论的AVHRR海表温度反演应用及效果评估

基于变分理论算法实现了METOP-A卫星AVHRR传感器探测数据的海洋表面温度变分反演,进行了连续1个月的海表温度反演试验,并分别从全球、分纬度带和天气系统活跃区域3个方面,将变分反演结果（VAR SST）与利用统计回归方法反演相同卫星得到的海表温度产品（GBL SST）、其他海温融合产品（OISST）及实际浮标观测数据等进行一系列评估。从全球评估指标看出,以OISST为参照,VAR SST要优于GBL SST;以浮标观测为参照,VAR SST略逊于GBL SST,而且VAR SST还改进了GBL SST随时间波动大的缺点;从分纬度带对比看出,在与OISST对比时,VAR SST在低纬度地区和北半球中纬度地区的质量要优于GBL SST,海温反演精度较高。研究还表明,由于变分方法考虑了大气状态的变化,能够更加有效订正卫星遥感过程中大气的削弱作用,从而反演出精度更高的海表温度,尤其在天气系统较为复杂的区域效果明显。     

多源星载辐射计SST数据对比分析

基于2018年4种红外辐射计(MODIS-Aqua,MODIS-Terra,VIIRS和AVHRR)的SST数据和3种微波辐射计(GMI,WindSat和AMSR2)的SST数据,分析了7种星载辐射计SST数据的全球覆盖情况,利用Argo数据对7种辐射计SST数据进行了真实性检验,并开展了微波产品、红外产品和Argo的...     

Examination of the merged sea surface temperature using wavelet analysis

In the previous study, merged sea surface temperature (SST) dataset called “New Generation SST” has been produced from several infrared and microwave satellite SSTs through an objective mapping. Here we examine the merged SST by comparison with moored buoy SST at 1 m depth, which is treated as true sea surface temperature. Comparison between wavelet spectra of merged and buoy SSTs shows that the former have larger amplitudes than those of the latter, which is partly explained as an aliasing effect due to TRMM Microwave Imager (TMI) aboard Tropical Rainfall Measuring Mission (TRMM) sampling on merged products. Coherency between wavelet-decomposed merged and buoy SSTs has high values in autumn and low ones in winter to spring. In winter, phase differences between them are positive, meaning that wavelet components of merged SST lag those of buoy SST. Reasons for delay and low coherency are: (1) seasonal components of merged SSTs are strongly affected by a lack of infrared SSTs due to clouds in winter, and (2) small-scale oceanic features, undetectable by coarse-resolution microwave SSTs, are blurred by the merging process. Improvements of merging methodology are discussed with regard to present study results.     

Algorithm and validation of sea surface temperature observation using MODIS sensors aboard terra and aqua in the western North Pacific

A regional algorithm to estimate SST fields in the western North Pacific, where small oceanographic disturbance are often found, has been developed using Moderate Resolution Imaging Spectroradiometers (MODIS) aboard Terra and Aqua. Its associated algorithm, which includes cloud screening and SST estimation, is based on an algorithm for the Global Imager (GLI) aboard Advanced Earth Observing Satellite-II (ADEOS-II) and is tuned for MODIS sensors. For atmospheric correction, we compare Multi-Channel SST (MCSST), Nonlinear SST (NLSST), Water Vapor SST (WVSST) and Quadratic SST (QDSST) techniques. For NLSST, four first-guess SSTs are investigated, including the values for MCSST, climatology with two different spatial resolutions, and near-real-time objective analysis. The results show that the NLSST method using high-resolution climatological SST as a first-guess has both good quality and high efficiency. The differences of root-mean-square error (RMSE) between the NLSST models using low-resolution climatology and those using high-resolution climatology are up to 0.25 K. RMSEs of the new algorithm are 0.70 K/0.65 K for daytime (Aqua/Terra) and 0.65 K/0.66 K for nighttime, respectively. Diurnal warming and the stratification of the ocean surface layer under low wind are discussed.