基于神经网络的二类水体大气校正

以MERIS高光谱影像为数据源,根据现有大气传输模型和大气校正方法,探索了适合于内陆湖泊二类水体的高光谱遥感影像大气校正方法。在6S辐射传输模型的基础上,构建了基于神经网络的二类水体大气校正算法。通过构建输入卫星辐亮度直接提取离水反射率的模型,无需同步气溶胶参数,即可实现大气校正。对2010年8月9日的MERIS影像进行大气校正,并将校正后的遥感反射率与准同步实测离水反射率进行对比分析,结果表明,大气校正过程有效去除了大气效应的影响,经过大气校正的13个波段的平均相对误差分布在10%～40%,得到了与实测值相近的水体遥感反射率。     

近海Ⅱ类水体的MODIS影像大气校正方法

利用光谱辐射传输理论对Gordon大气校正算法进行了修正，提出用解析的方法分离红外波段748nm和869nm的离水辐射量与气溶胶的贡献，实现对近海Ⅱ类水体的大气校正，使之更适用于我国高悬浮泥沙和高气溶胶浓度海区。海上准同步实测数据表明，本文算法的校正精度比传统方法高，且能适用于影像中找不到理想Ⅰ类水体的情况，解决了近海水色数据大气校正问题。     

鄱阳湖HJ-1A/B卫星CCD影像大气校正研究

以准同步的Terra/MODIS反演的气溶胶为辅助,采用FLAASH模型对2009-10-24鄱阳湖HJ-1A/B卫星CCD影像进行大气校正处理。结果表明,大气影响可以被有效去除,在水体遥感反射率较高的红、绿波段,大气校正精度较高,平均相对误差分别为13.4%和9.8%;而在水体遥感反射率较低的近红外、蓝波段,大气校正精度较低,这可能与波段不同的信噪比和陆地邻近像元效应有关。     

利用MODIS数据和查找表的城区TM影像大气校正

影像大气校正精度的关键参数为气溶胶光学厚度,而城区大气条件复杂,对城区TM影像采用统一的大气参数进行大气校正,势必难以获得令人满意的校正精度。因此,本文提出了一种基于MODIS数据和查找表的大气校正算法,首先应用6S模型离线计算建立不同气溶胶光学厚度的大气校正系数查找表,然后基于MODIS数据反演气溶胶光学厚度,最后基于查找表和气溶胶光学厚度数据对长沙城区TM影像进行了逐像元大气校正。结果表明:基于查找表的校正算法与6S模型在线计算算法的校正精度接近,能够较好地进行大气校正;在水体区校正精度最高,而在城区校正精度相对较低。     

星载激光雷达气溶胶数据辅助的近岸浑浊水体大气校正研究

提出了一种星载激光雷达CALIOP气溶胶数据辅助的MODIS/Aqua水色数据大气校正方法,并在长江口及其邻近浑浊水体区域进行了实验。通过与实测光谱数据的对比分析说明,本文方法能在一定程度上避免如近红外波段离水辐亮度为零的假设的不合理性,摆脱对实测数据的依赖,有效地反演离水辐亮度,修复SeaDAS软件中短波红外-近红外联合大气校正算法中短波红外波段引起的产品的条带问题。     

暗目标法的Himawari-8静止卫星数据气溶胶反演

Himawari-8(H8)是由日本气象厅发射的新一代静止气象卫星,可实现10 min/次的高频次对地观测,搭载的AHI(Advanced Himawari Imager)传感器设置有与MODIS暗目标气溶胶反演算法所需的类似波段。本文参考暗目标算法构建了针对该卫星传感器的陆地气溶胶反演算法:首先,通过基于地基站点观测数据的精确大气校正,统计得到短波红外与可见光波段的地表反射率比值关系,将此作为先验知识用于地—气解耦时的反射率估计;然后,初步假设大陆型气溶胶类型,利用辐射传输模型建立查找表;最后,通过模拟与卫星观测的表观反射率误差最小实现气溶胶光学厚度反演解算。选取2016年5月覆盖京津冀地区的观测数据进行测试,将反演结果与对应时间的MODIS气溶胶光学厚度产品进行对比验证,空间分布趋势一致、相关性较高,相关系数R达到0.852;通过与地基观测网AERONET站点实测数据对比验证,所有站点的相关系数R~2均大于0.88,精度较高。利用反演的高时间分辨率产品,分析了京津冀地区的大气空间分布和日变化情况,结果表明:采用暗目标法对H8静止卫星陆地气溶胶光学厚度反演具有一定的潜力和可行性,能反映气溶胶的高时间变化信息,有望成为大气环境污染变化监测新的重要手段。     

HJ-1A/B卫星CCD影像辅助的MODIS水色大气校正产品质量改进

针对我国近岸高浑浊水体区域MODIS短波红外波段大气校正产品中存在的信号饱和及条带问题,利用神经网络模型,采用准同步的HJ-1A/B卫星CCD影像及实测遥感反射率数据对MODIS/Terra水色遥感大气校正产品进行了质量改进。改进后结果与MODIS/Terra遥感反射率产品相比,平均相对误差为13.3%,信号饱和区域修复结果与实测数据各波段平均相对误差为28.2%。结果表明,该方法在保证结果精度的情况下,能有效地修复MODIS/Terra水色波段因为信号饱和而产生的数据空白区域,同时也能较好地解决MODIS/Terra大气校正产品中的条带问题。     

基于HY-1C卫星CZI影像的多类型内陆水体大气校正及水质参数反演

海洋一号C星(HY-1C)上搭载的海岸带成像仪(CZI)在内陆水体水色遥感应用方面具有较大潜力。目前,HY-1C CZI影像在内陆水体的大气校正和水质反演研究较少,仍然需要解决适用于不同类型内陆水体的大气校正和水质参数建模等问题。因此,本研究在华北平原的小浪底水库、官厅水库、丹江口水库、白龟山水库、白洋淀5个不同浑浊程度的湖泊和水库开展了星地同步实验,获取了85个采样点的水面遥感反射率光谱和水质参数实测数据。发展了基于Sentinel-2 MSI影像均匀不变地物的HY-1C CZI影像相对大气校正算法和系统定标模型。HY-1C CZI的蓝、绿、红、近红外波段遥感反射率反演平均无偏相对误差(AURE)分别为14.7%、11.2%、28.9%、41.7%,蓝、绿、红波段的大气校正精度相对较高;此外,大气校正与实测光谱的相关系数r的平均值为0.978,光谱角度距离(SAD)的平均值为0.109,说明大气校正遥感反射率光谱形状与实测光谱一致性较高。基于实测数据构建了叶绿素a浓度和透明度反演模型,经独立数据验证,HY-1C CZI影像叶绿素a浓度反演的AURE为33.8%,均方根误差(RMSE)...     

高斯曲线优化能见度与气溶胶光学厚度转换模型

大气气溶胶是影响对地观测定量精度的最主要不确定性因素。随着定量遥感的发展,对气溶胶光学厚度数据的精度提出了更高要求。在广泛应用的基于辐射传输模型大气校正研究中,需要输入气溶胶光学厚度等关键参数,但与对地观测影像数据同时相的气溶胶光学厚度获取较难,而水平能见度作为表征气溶胶光学特性的间接参数可通过广泛分布的气象台站获得,可将能见度转换得到的气溶胶光学厚度数据作为同时相数据输入传输模型进行大气校正计算。本文以实测的能见度和气溶胶光学厚度数据为基础,通过拟合气溶胶标高其随时间的变化对Peterson模型进行了修正。对修正后的模型进行精度验证得到RMSE为0.254,结果表明优化的模型对精度有较大提升。     

地表反射率产品支持的GF-1 PMS气溶胶光学厚度反演及大气校正

GF-1卫星PMS(GF-1 PMS)数据具有高空间分辨率、短重访周期的特点,可以在地表类型识别、参数提取中发挥重要作用。但由于缺少2.1μm附近的短波红外波段,使得气溶胶反演时地表反射率的精确确定非常困难,从而导致其高精度大气校正难以开展,限制了该数据的应用。本文提出了一种地表反射率数据支持的气溶胶反演方法,用于GF-1PMS数据的大气校正。其基本思想是:使用现有的地表反射率数据集为GF-1PMS数据提供地表反射率,用于确定GF-1PMS图像中浓密植被像元(DDV)的分布,基于确定的浓密植被像元反演气溶胶光学厚度(AOD),并用于大气校正。这里使用的地表反射率数据集为合成的无云MODIS地表反射率产品,对GF-1PMS数据做了空间尺度的转换。为降低两类数据配准误差对地表反射率确定的影响,提出了使用区域NDVI分布百分比匹配的方法,回避了像元的直接匹配,为GF-1PMS数据提供DDV的空间分布。为验证该方法的有效性,利用北京、太湖两个AERONET站点观测的气溶胶光学厚度对气溶胶反演结果进行精度验证,结果表明,气溶胶反演算法精度较高,稳定性较强。AOD反演结果应用于北京和敦煌地区的GF-1PMS数据大气校正,获得的地表反射率与地面实测的地表反射率的误差低于0.015,且大气校正后影像对比度明显提高。     

A coupled atmospheric and topographic correction algorithm for remotely sensed satellite imagery over mountainous terrain

Radiometric correction is an important issue in the quantitative remote-sensing community. By integrating dark object subtraction (DOS)-based atmospheric correction with physics-based topographic correction, a coupled land surface reflectance retrieval algorithm (coupled atmospheric and topographic correction algorithm, named the CAT algorithm) for rugged mountainous regions is proposed. Terra MODIS-derived atmospheric characterization data (including aerosol optical depth, integrated precipitable water, surface pressure, and ozone concentration) are employed as inputs for the proposed algorithm. A physics-based path radiance estimation model is proposed and embedded in the CAT algorithm, and band-specific per-pixel path radiance values are calculated. After the CAT algorithm was performed, the correlation between reflectance and terrain was dramatically reduced, with correlation coefficients nearly equal zero, especially for the near infrared and short-wave infrared bands, meanwhile the image information content increased over 20%. To provide a comparison with previous studies, two commonly used methods in the literature (DOS + Cosine and DOS + C) were employed. The results of the comparison show that the proposed algorithm performed better in both atmospheric and topographic corrections without empirical regression.     

基于神经网络的二类水体大气修正

大气修正是海洋水色遥感中的关键技术之一。近海二类水体大气修正面临两个挑战：浑浊水体造成NIR大气修正波段的离水辐射明显大于零;近海上空存在较强吸收性的气溶胶。本文针对HY-1A CZI,在辐射传输模拟的基础上建立了基于神经网络技术的二类水体大气修正算法,可以由波段1-4的TOA反射率和三个角度反演得到离水反射率、气溶胶光学厚度等参数。利用模拟数据进行了算法的性能评估,并开展了卫星数据处理试验。结果表明,除了在非常浑浊的水体,反演结果基本合理。     

Atmospheric Correction Over Coastal Turbid Waters of Bay of Bengal Using OCEANSAT-I Ocean Colour Monitor (OCM) Data

Space-borne ocean-colour remote sensor-detected radiance is heavily contaminated by solar radiation backscattered by the atmospheric air molecules and aerosols. Hence, the first step in ocean-colour data processing is the removal of this atmospheric contribution from the sensor-detected radiance to enable detection of optically active oceanic constituents e.g. chlorophyll-a, suspended sediment etc. In standard atmospheric correction procedure for OCEANSAT-1 Ocean Colour Monitor (OCM) data, NIR bands centered at 765 and 865 nm wavelengths were used for aerosol characterization. Due to high absorption by water molecules, ocean surface in these two wavelengths acts as dark background, therefore, sensor detected radiance can be assumed to have major contribution from atmospheric scattering. For coastal turbid waters this assumption of dark surface fails due to the presence of highly scattering sediments which causes sufficient water-leaving radiance in NIR bands and lead to over-estimation of aerosol radiance resulting in negative water leaving radiance for λ < 700 nm. In the present study, for the turbid coastal waters in the northern Bay of Bengal, the concept of spatial homogeneity of aerosol and water leaving reflectance has been applied to perform atmospheric correction of OCAEANSAT-1 OCM data. The results of the turbid water atmospheric correction have also been validated using in-situ measured water-leaving radiance. Comparison of satellite derived water-leaving radiance for five coastal stations with in-situ measured radiance spectra, indicates an improvement over the standard atmospheric correction algorithm giving physically realistic and positive values. Root Mean Square Error (RMSE) between the in-situ measured and satellite derived water leaving radiance for wavelengths 412 nm, 443 nm, 490 nm, 512 nm and 555 nm was found to be 1.11, 0.718, 0.575, 0.611 and 0.651%, respectively, using standard atmospheric correction procedure. By the use of spatial homogeneity concept, this error was reduced to 0.125, 0.173, 0.176, 0.225, and 0.290 and the correlation coefficient arrived at 0.945, which is an improvement over the standard atmospheric correction procedure.     

AMTIS大气订正算法——基于MODTRAN4．1与BRDF大气订正环

基于BRDF大气订正环的途径和核驱动模型 ,用MODTRAN创建大气参数查找表 (LookUpTable LUT) ,加入地表先验知识 ,对AMTIS(AirborneMulti angleTIR/NIRImagingSystem AMTIS)的可见光、近红外波段数据进行了大气订正 ,并根据地面数据进行了验证。结果表明 ,采用本文算法比基于地表朗伯假定的大气订正能更有效地去除大气影响     

联合云量自动评估和加权支持向量机的Landsat图像云检测

针对ACCA（云量自动评估）算法难以检测Landsat图像中的半透明云问题,提出了一种ACCA和WSVM（加权支持向量机）相结合的云检测算法．首先根据云在不同波段中的大气辐射特点,结合Landsat ETM+图像数据的光谱特性,利用ACCA算法将图像像元初步分成云像元、非云像元和待定像元,再以云的光谱特性构造特征向量,利用WSVM算法进行待定像元的云层检测,最终获得全部图像的云检测结果．仿真实验结果表明,该方法既具有ACCA算法的云检测优势,还对ACCA算法难以识别的半透明云有很好的检测效果．     

从ASTER和Landsat／TM卫星数据反演日本千叶地区地表反射率和气溶胶光学厚度分布

在卫星遥感大气研究中，已有的精确反演海洋表面反射率和其上空气溶胶光学厚度分布的算法，由于陆地地表像元反射率的不均一性，使得这些方法在应用于陆地表面反射率的反演中具有一定的局限性。而利用三步校正法可以去除地表邻近像元的影响，从而消除这种局限性。文中介绍了三步校正的算法，并对日本千叶地区ASTER卫星数据进行了大气和地表邻近像元的影响校正，精确地反演了该地区的地表反射率，通过地表反射率和气溶胶光学厚度之间的关系计算得到了气溶胶光学厚度的分布。同时证明了在洁净天反演的地表反射率可以应用于反演同一季节中非洁净天的气溶胶光学厚度分布，这样不但减小了气溶胶模式选择的影响，而且实现了在缺少太阳辐射计数据情况下获得气溶胶光学厚度分布的目的。     

Developing a semi-analytical algorithm to estimate particulate organic carbon (POC) levels in inland eutrophic turbid water based on MERIS images: A case study of Lake Taihu

Particulate organic carbon (POC) plays an important role in the carbon cycle in water due to its biological pump process. In the open ocean, algorithms can accurately estimate the surface POC concentration. However, no suitable POC-estimation algorithm based on MERIS bands is available for inland turbid eutrophic water. A total of 228 field samples were collected from Lake Taihu in different seasons between 2013 and 2015. At each site, the optical parameters and water quality were analyzed. Using in situ data, it was found that POC-estimation algorithms developed for the open ocean and coastal waters using remote sensing reflectance were not suitable for inland turbid eutrophic water. The organic suspended matter (OSM) concentration was found to be the best indicator of the POC concentration, and POC has an exponential relationship with the OSM concentration. Through an analysis of the POC concentration and optical parameters, it was found that the absorption peak of total suspended matter (TSM) at 665 nm was the optimum parameter to estimate POC. As a result, MERIS band 7, MERIS band 10 and MERIS band 12 were used to derive the absorption coefficient of TSM at 665 nm, and then, a semi-analytical algorithm was used to estimate the POC concentration for inland turbid eutrophic water. An accuracy assessment showed that the developed semi-analytical algorithm could be successfully applied with a MAPE of 31.82% and RMSE of 2.68 mg/L. The developed algorithm was successfully applied to a MERIS image, and two full-resolution MERIS images, acquired on August 13, 2010, and December 7, 2010, were used to map the POC spatial distribution in Lake Taihu in summer and winter.     

Urban aerosol mapping over Athens using the differential textural analysis (DTA) algorithm on MERIS-ENVISAT data

Low and moderate spatial resolution satellite sensors (such as TOMS, AVHRR, SeaWiFS) have already shown their capability in tracking aerosols at a global scale. Sensors with moderate to high spatial resolution (such as MODIS and MERIS) seem also to be appropriate for aerosol retrieval at a regional scale. We investigated in this study the potential of MERIS-ENVISAT data to resolve the horizontal spatial distribution of aerosols over urban areas, such as the Athens metropolitan area, by using the differential textural analysis (DTA) code. The code was applied to a set of geo-corrected images to retrieve and map aerosol optical thickness (AOT) values relative to a reference image assumed to be clean of pollution with a homogeneous atmosphere. The comparison of satellite retrieved AOT against PM₁₀ data measured at ground level showed a high positive correlation particularly for the AOT values calculated using the 5th MERIS’ spectral band (R²=0.83). These first results suggest that the application of the DTA code on cloud free areas of MERIS images can be used to provide AOT related to air quality in this urban region. The accuracy of retrieved AOT mainly depends on the overall quality, the pollution cleanness and the atmospheric homogeneity of the reference image.