基于ETM~+和ASTER近红外波段的水体信息提取对比

利用Landsat ETM+和ASTER近红外波段数据进行了水体信息提取,然后利用知识规则对2种提取结果进行进一步分类,并分析了波谱分辨率的差异对水体信息提取结果的影响。实验表明,基于Landsat ETM+数据的水体提取总体精度为82.4%,基于ASTER数据的水体信息提取结果总体精度为92.4%;在空间分辨率相同情况下,波谱分辨率的提高可以有效地提高水体信息提取的精度。     

基于归一化指数分析的居民地遥感信息提取

以无锡市作为研究区域,采用2000年Landsat ETM+影像数据,通过对居民地的遥感机理分析,利用植被指数、水体指数、城镇指数相结合的方法提取居民地信息。分析遥感影像的谱间结构特征,通过试验,建立二值逻辑运算式,得到居民地遥感信息提取结果。并用该方法在不同时相不同地区的Landsat TM/ETM+影像上进行了进一步的验证。研究结果表明:该方法可以将居民地信息提取出来,并且效果较好。     

塔里木盆地周边地区浅地表土壤含水信息提取方法研究

利用Landsat-7的ETM和Radarsat1号卫星SAR图像,通过主成分分析、ETM与SAR图像的融合处理和混合波段比值等多种方法,在塔里木盆地周边地区提取浅地表土壤中的含水信息,图像上高、中、低含水率区和第四系风积层覆盖下的含水地段分别显示出不同的色调特征。经实地验证,圈定了新的含水地段,取得了明显的信息提取效果。     

基于小波纹理信息的星载SAR图像与TM图像的数据融合

遥感图像的数据融合是当前遥感界研究的热点问题之一。论述利用小波变换提取合成孔径雷达（SAR）图像的多尺度纹理信息，基于小波纹理信息将SAR图像与TM图像进行融合。选取徐州市南郊风景区的Radarsat卫星SAR图像和TM图像进行试验研究，并与颜色变换法融合图像进行对比分析，结果表明，无论是目视解译还是定量分析，该融合方法与颜色变换法相比，将获得更理想的高空间分辨率多光谱的融合图像。     

基于Asar与TM图像的洪水淹没范围提取

在洪水灾害监测、灾情评估中,洪水淹没范围是最重要的信息之一。洪水灾害中获取的雷达图像能够提取水体的范围,但很难区分出原有水体和洪灾中淹没区范围。基于这个问题,本文提出利用目前功能最为强大的星载雷达系统Asar在灾中得到雷达图像和灾前或者灾后的TM图像复合,得到灾中与非洪灾时期水体的变化范围,即获得洪水淹没范围的方法。试验结果表明,利用这种方法可以快速、准确地提取洪水淹没范围。     

矿区水体变化遥感监测方法研究

采用遥感技术对矿区生态环境进行动态监测,对于人类健康和资源合理开发利用具有重要意义。本文以临沂苍峄矿区为研究区,采用多时相Landsat TM/ETM+/OLI遥感影像,运用单波段法、谱间关系法、水体指数法等多种方法提取水体信息。在此基础上提出一种新的水体变化信息提取流程,即运用RGB彩色合成法对不同时相影像进行合成,根据不同色调反映像元的不同变化趋势,发现并提取变化信息,实现了矿区水体信息的变化监测。     

基于阈值分割与决策树的SAR影像水体信息提取

目前我国的GF-3 SAR数据可实现全天时全天候的对地观测,已服务于海洋、减灾、水利、气象等多个领域。改进了基于阈值分割法与决策树的GF-3 SAR影像水体信息提取方法,首先对GF-3 SAR影像进行基本处理;再采用KI二值化阈值分割法进行图像分割;然后通过构建知识决策树模型来提取水体信息,为了提高精度,采用GDEM数据进行地表建模,提取山体阴影;最后利用空间分析功能将地形建模阴影图与提取的水体范围进行匹配,去除山体阴影,进而获得水体信息的精确范围。通过混淆矩阵计算得到水体信息提取的总体精度为89.22%,Kappa系数为0.71,精度优于基于光学GF-2号影像的水体指数法提取结果。整个流程人工干预少,具有自动化更强、效率更高的优势。     

多时相阴影轮廓差分辅助下的城市水体提取

如何避免水体提取中阴影信息与水体信息的混淆，是利用遥感数据提取城市水体信息需要解决的一个问题。本文以高分一号WFV图像及Landsat8 OLI图像为数据源，利用阴影轮廓的位置与形状在不同太阳高度角及太阳方位角下的差异性，提出一种基于多时相阴影轮廓差分的城市水体提取方法（WMSD）。以广州市天河区为试验区进行水体信息提取，同时运用NDWI、MNDWI及SWI指数法分别提取水体信息，进行精度对比分析。结果显示，本文所提出的WMSD方法分类精度超过88%，较NDWI法、SWI法及MNDWI法的水体提取精度分别提高了8.50%、9.50%及4.67%。说明基于阴影轮廓位置与形状的差异提取水体信息的方法能够较好地解决阴影与水体提取信息混淆的问题，为利用遥感数据提取城市地区水体提供了一个可行的处理方法。     

利用景观格局指数的空间分辨率对水域面积提取影响的分析

对8个不同地区对应的同一时间的ETM+数据和MODIS数据,利用谱间关系法得到30 m和250 m分辨率具有不同景观格局分布的水体专题图,研究分辨率对不同景观格局分布的水体提取的影响。通过比较发现,区域内水体边缘密度很小时,ETM+和MODIS提取结果的误差很小;当区域内水体边缘密度很大时,ETM+和MODIS提取结果的误差相应就变大。通过引入景观格局指数与两种分辨率的提取结果进行回归分析发现,对于不破碎区域的水体,MODIS和ETM+可以得到相近的精度;而对于中度破碎的水体,引入景观格局指数信息能显著地提高中度破碎水体的精度;但对于高度破碎的水体,通过引入景观格局指数信息的多元回归几乎不能提高精度。     

基于资源三号和ETM~+影像的断裂构造解译

以资源三号影像、ETM+影像为数据源,在分析断裂构造遥感影像特征基础上,研究断裂构造解译中的遥感图像处理方法,运用灰度拉伸、图像融合、定向滤波等方法进行增强处理,依据解译标志进行人机交互解译。对鄂尔多斯盆地的断裂构造进行了综合分析,证明高空间分辨率的资源三号影像与多光谱分辨率的ETM+影像相结合的遥感技术在断裂构造解译方面具有可行性。     

Cross-sensor calibration between Ikonos and Landsat ETM+ for spectral mixture analysis

Spectral mixture analysis is an algorithm that is developed to overcome the weakness in traditional land-use/land-cover (LULC) classification where each picture element (pixel) from remote sensing is assigned to one and only one LULC type. In reality, a remotely sensed signal from a pixel is often a spectral mixture from several LULC types. Spectral mixture analysis can derive subpixel proportions for the endmembers from remotely sensed data. However, one frequently faces the problem in determining the spectral signatures for the endmembers. This study provides a cross-sensor calibration algorithm that enables us to obtain the endmember signatures from an Ikonos multispectral image for spectral mixture analysis using Landsat ETM+ images. The calibration algorithm first converts the raw digital numbers from both sensors into at-satellite reflectance. Then, the Ikonos at-satellite reflectance image is degraded to match the spatial resolution of the Landsat ETM+ image. The histograms at the same spatial resolution from the two images are matched, and the signatures from the pure pixels in the Ikonos image are used as the endmember signatures. Validation of the spectral mixture analysis indicates that the simple algorithm works effectively. The algorithm is not limited to Ikonos and Landsat sensors. It is, in general, applicable to spectral mixture analysis where a high spatial resolution sensor and a low spatial resolution sensor with similar spectral resolutions are available as long as images collected by the two sensors are close in time over the same place.     

基于小波分解的星载SAR图像纹理信息提取

论述利用小波变换提取合成孔径雷达（SAR）图像的多尺度纹理信息，借助Daubechies3正交小波，对图像进行小波分解，将小波变换各个频带输出的l1范数作为纹理特征值。选取徐州市区局部的Radarsat卫星SAR图像，提取出纹理图像，实验证明，该纹理提取方法能有效地提取出面目标的纹理信息。     

小卫星遥感影像自动提取水体方法研究

基于小卫星影像的水体信息提取方法,即用波段运算得到特征波段(PRWI),经过决策树等辅助手段提取出水体信息。通过在山东省微山湖上级坝北湖选取水体所做的试验表明,该方法在平原地区的总体提取效果较好,经检验发现其误判的像元主要是位于水体和其他地物的交界处。在山区选取山东省东周水库做的试验表明,在山区用该方法提取的小卫星水体信息和Landsat卫星的TM/ETM影像差距不大。小卫星还可以很好地用于城市规划、生态环境、土地利用和环境灾害等动态监测。     

基于频域滤波的高分辨率遥感图像城市河道信息提取

提出一种基于频域滤波的城市河道信息提取方法。首先对高分辨率遥感图像进行傅里叶变换得到频谱图, 并利用径向和角向分布图分析城市河道的频谱特征。其次, 基于城市河道的双线型特点, 将其分为边缘特征和低频信息两个部分, 并根据周期性纹理的频谱模型和地物频谱能量分布规律确定两个部分的频域识别标志。然后设计相应的扇环形带通log Butterworth滤波器和低通Butterworth滤波器分别对城市河道的边缘特征和低频信息进行提取, 并根据该两部分信息实现城市河道信息提取。最后对城市河道信息提取结果进行定量评价, 结果表明, 本文方法可以有效地实现城市河道的信息提取。     

A spatial–temporal Hopfield neural network approach for super-resolution land cover mapping with multi-temporal different resolution remotely sensed images

The mixed pixel problem affects the extraction of land cover information from remotely sensed images. Super-resolution mapping (SRM) can produce land cover maps with a finer spatial resolution than the remotely sensed images, and reduce the mixed pixel problem to some extent. Traditional SRMs solely adopt a single coarse-resolution image as input. Uncertainty always exists in resultant fine-resolution land cover maps, due to the lack of information about detailed land cover spatial patterns. The development of remote sensing technology has enabled the storage of a great amount of fine spatial resolution remotely sensed images. These data can provide fine-resolution land cover spatial information and are promising in reducing the SRM uncertainty. This paper presents a spatial–temporal Hopfield neural network (STHNN) based SRM, by employing both a current coarse-resolution image and a previous fine-resolution land cover map as input. STHNN considers the spatial information, as well as the temporal information of sub-pixel pairs by distinguishing the unchanged, decreased and increased land cover fractions in each coarse-resolution pixel, and uses different rules in labeling these sub-pixels. The proposed STHNN method was tested using synthetic images with different class fraction errors and real Landsat images, by comparing with pixel-based classification method and several popular SRM methods including pixel-swapping algorithm, Hopfield neural network based method and sub-pixel land cover change mapping method. Results show that STHNN outperforms pixel-based classification method, pixel-swapping algorithm and Hopfield neural network based model in most cases. The weight parameters of different STHNN spatial constraints, temporal constraints and fraction constraint have important functions in the STHNN performance. The heterogeneity degree of the previous map and the fraction images errors affect the STHNN accuracy, and can be served as guidances of selecting the optimal STHNN weight parameters.     

Synoptic Monitoring of Gross Primary Productivity of Maize Using Landsat Data

There is a growing interest in monitoring the gross primary productivity (GPP) of crops due mostly to their carbon sequestration potential. Both within- and between-field variability are important components of crop GPP monitoring, particularly for the estimation of carbon budgets. In this letter, we present a new technique for daytime GPP estimation in maize based on the close and consistent relationship between GPP and crop chlorophyll content, and entirely on remotely sensed data. A recently proposed chlorophyll index (CI), which involves green and near-infrared spectral bands, was used to retrieve daytime GPP from Landsat Enhanced Thematic Mapper Plus (ETM+) data. Because of its high spatial resolution (i.e., 30 30 m/pixel), this satellite system is particularly appropriate for detecting not only between- but also within-field GPP variability during the growing season. The CI obtained using atmospherically corrected Landsat ETM+ data was found to be linearly related with daytime maize GPP: root mean squared error of less than 1.58 in a GPP range of 1.88 to 23.1 ; therefore, it constitutes an accurate surrogate measure for GPP estimation. For comparison purposes, other vegetation indices were also tested. These results open new possibilities for analyzing the spatiotemporal variation of the GPP of crops using the extensive archive of Landsat imagery acquired since the early 1980s.     

Fusion of TerraSAR-x and Landsat ETM+ data for protected area mapping in Uganda

TerraSAR-X satellite acquires very high spatial resolution data with potential for detailed land cover mapping. A known problem with synthetic aperture radar (SAR) data is the lack of spectral information. Fusion of SAR and multispectral data provides opportunities for better image interpretation and information extraction. The aim of this study was to investigate the fusion between TerraSAR-X and Landsat ETM+ for protected area mapping using high pass filtering (HPF), principal component analysis with band substitution (PCA) and principal component with wavelet transform (WPCA). A total of thirteen land cover classes were identified for classification using a non-parametric C 4.5 decision tree classifier. Overall classification accuracies of 74.99%, 83.12% and 85.38% and kappa indices of 0.7220, 0.8100 and 0.8369 were obtained for HPF, PCA and WPCA fusion approaches respectively. These results indicate a high potential for a combined use of TerraSAR-X and Landsat ETM+ data for protected area mapping in Uganda.     

Ann Based Robust LULC Classification Technique Using Spectral, Texture and Elevation Data

Albeit the advent of fast computing facilities, digital image classification of remotely sensed data is still remain the topic of research. This might be due to the reason that the ancillary information such as texture and topography is absent in image classification. Since two decades, texture is widely applied in image classification but there is no explicit icon in most popularly used remote sensing software. Hence the aim of this study is to classify the Landsat ETM+ captured in 2000 using spectral information, topographic information and texture information. This study helps to throw light into statistical texture analysis i.e., the effect window size i.e., 3?×?3 to 9?×?9, on image classification. The ability of Grey Run Length Matrix (GRLM), which is computationally complex compared to industrially well-known Grey Level Co-occurrence Matrix (GLCM) but encompasses greater potential to discriminate between two classes, is explored. Eight spectral bands, 11 texture parameters extracted from Landsat ETM+ data and elevation, slope, aspect extracted from DEM data are classified individually using Artificial Neural Network (ANN) and the individually classified information is integrated using endorsement theory. Validations of classified results are performed using Google Maps and Landmap services updated in 2009. The results are compared with Maximum Likelihood classification (MLC) and hence all the evidence (spectral, texture and topography) with 5?×?5 texture window provided maximum classification accuracy of 70.44 %.