基于Quick Shift算法的高光谱影像分类

论述了面向对象分类方法处理高光谱高空间分辨率影像的优势与流程;分析了快速漂移(Quick Shift)算法的原理,该算法在进行模式搜索时具有可控制模态选择和平衡"过分割"与"欠分割"的特点.将该算法应用于高光谱影像分割,可得到面向对象分类所需的较理想的"同质"影像对象.为提高影像分割的效率,提出了一种基于灰度共生矩阵的...     

面向对象影像多尺度分割最大异质性参数估计

多尺度分割是遥感影像分析的关键步骤,影像分割过程中的尺度参数选择直接关系到面向对象影像分析的质量和精度。首先,总结了面向对象影像分析中尺度概念的内涵,分析遥感影像空间和属性两大基本特征,依据空间统计和光谱统计获得理论上最优的空间尺度分割参数、属性尺度分割参数。其次,运用了基于谱空间统计的高分辨率影像分割尺度估计方法,分析了分形网络演化多尺度分割与影像谱空间统计特征的关系,进而将基于谱空间统计的面向对象影像分析尺度参数应用于分形网络演化多尺度分割算法中,最后,对其参数的合理性进行验证。研究采用高空间分辨率IKONOS和SPOT 5影像数据,选择建筑实验区和农田实验区进行空间和光谱特征统计,以进一步估计分割中的最佳尺度参数。使用分形网络演化方法对图像进行分割,利用监督分类对本文提出的尺度估计方法进行验证,验证结果表明尺度估计方法可以一定程度上保证后续的面向对象影像分类的精度。不同于以往分割后评价的尺度选择方法会需要大量的运算量,本文方法不需要先验知识的参与,且在分割前就可以自适应地估计出相对较为合适的尺度参数,提高了面向对象信息提取的自动化程度。     

基于多层次分割分类模型及其特征空间优化的建筑物提取方法

针对高空间分辨率遥感影像城市地物信息提取中的尺度效应、光谱多样性及分类特征优化等问题,基于面向对象影像分析方法,结合数据挖掘与机器学习技术,提出了一种多层次分割分类模型及其特征空间优化的建筑物提取方法。首先,根据遥感信息多尺度特性,针对地物特征差异设立层级关系,再结合光谱多样性特征定义地物包含的子类型,建立基于不透水面分割分类提取建筑物的层次化结构;然后,利用提出的Relief F-PSO组合特征选择方法,优化构建相应层次的影像特征空间;最后,在多尺度分割和特征优化的基础上,基于随机森林模型获取不透水面分布,进而采用J48决策树算法分类提取建筑物。实验结果表明,该方法能够利用较少数量的影像特征,获得高精度的建筑物提取成果。     

面向对象的多尺度加权联合稀疏表示的高空间分辨率遥感影像分类

针对高空间分辨率遥感影像中的地物具有多尺度特性,以及各个尺度的对象特征对地物分类精度的影响具有较强的尺度效性,并结合面向对象影像分析方法和多尺度联合稀疏表示方法在高空间分辨率遥感影像分类中的各自优点,提出了一种面向对象的多尺度加权稀疏表示的高空间分辨率遥感影像分类算法。首先,采用多尺度分割算法获得多尺度分割结果并提取对象的多尺度特征;然后,根据影像对象的多尺度分割质量测度计算各尺度的对象权重,构建面向对象的多尺度加权联合稀疏表示模型;最后,采用2个国产GF-2高空间分辨率遥感数据集和1个高光谱-高空间分辨率航空遥感数据集（WashingtonD.C.数据）验证该算法的有效性。试验结果表明,与SVM、像素级稀疏表示、单尺度和多尺度对象级稀疏表示和深度学习等算法相比较,本文算法获得了较高的OA和Kappa分类精度,提高了各个尺度地物的分类精度,有效抑止了地物分类结果中的椒盐噪声现象,同时保持大尺度地物的区域性和小尺度地物的细节信息。     

一种面向对象的高分辨率遥感影像信息提取方法

针对传统面向对象分类方法的不足,根据研究对象特征构建了一种改进的面向对象的高分辨率遥感影像信息提取分类方法.首先利用SLIC超像素算法对影像进行分割,并提取分割后影像的纹理、光谱和形状特征;再利用SVM分类器提取影像信息,区分相似性较高的耕地和道路;然后利用随机森林算法提取水体和人工表面;最后对不同地物信息的提取结果进行拼接,实现土地利用分类.结果表明,与传统的面向对象分类方法相比,该方法的分类精度更高.     

面向高光谱影像分类的显著性特征提取方法

针对高光谱影像分类问题,提出了一种显著性特征提取方法。首先,利用超像素分割算法将高光谱影像3个相邻波段分割为若干个小区域。然后,基于分割得到的小区域计算反映不同区域的显著性特征。最后,沿着光谱方向采用大小为3、步长为1的滑窗法获得所有波段的显著性特征。进一步将提取的显著性特征与光谱特征进行结合,并将结合后的特征输入到支持向量机中进行分类。利用Pavia大学、Indian Pines和Salinas 3组高光谱影像数据进行分类试验。试验结果表明,与传统的空间特征提取方法和基于卷积神经网络的高光谱影像分类方法相比,提取的显著性特征能够获得更高的高光谱影像分类精度,且结合光谱特征能够进一步提高分类精度。     

面向对象和规则的高分辨率影像分类研究

随着航天遥感技术的发展,遥感数据的空间分辨率、光谱分辨率和时间分辨率极大提高,高效解译并处理海量的、具有空间几何信息和纹理信息的地物高分辨率遥感影像数据已成为遥感领域研究的重点与难点。对此,本文提出一种面向对象和规则的遥感影像数据的分类提取方法,即通过发现和挖掘高分辨率影像丰富的光谱和空间特征知识,建立影像对象多层次网络分割分类结构,实现对遥感影像准确快速的地物分类和精度评价。以藏南地区WorldView-2影像数据为试验研究对象,采用面向对象和规则的影像分类方法进行验证试验,即综合采用均值方差法、最大面积法、精度比较法进行分析,选择3种最佳分割尺度建立多层次影像对象网络层次结构进行影像分类试验。结果表明,采用面向对象规则分类方法对高分辨率影像进行分类,能使高分辨率影像分类结果近似于目视判读的结果,分类精度更高。面向对象规则分类法的综合精度和Kappa系数分别为97.38%、0.967 3;与面向对象SVM法相比,分别高出6.23%、0.078;与面向对象KNN法相比,分别高出7.96%、0.099 6。建筑物的提取精度、用户精度分别比面向对象SVM法高出18.39%、3.98%,比面向对象KNN法高出21.27%、14.97%。     

结合光谱相似和相位一致的高分辨率影像分类

针对面向对象分类结果存在“平滑地物细节”的问题,该文提出顾及光谱相似性和相位一致的高分辨率影像分类方法。该方法首先采用顾及光谱相似性的相位一致的模型方法来获得边缘相应幅度,再采用自动标记分水岭算法对影像进行初分割;顾及相邻分割对象的空间位置、形状、面积等特征的多重约束,提出相邻分割对象合并代价函数模型,对分割结果进行优化,最后结合支持向量机(SVM)对分割对象进行分类。结果表明,本文方法在提高高分辨率影像分类精度的同时,还能保持地物细节。     

面向对象分类提取高分辨率多光谱影像建筑物

初步测试利用基于知识规则的面向对象分类方法从高分辨率Ikonos卫星影像上提取建筑物,包括:融合1 m全色和4 m多光谱波段影像,生成1 m分辨率的多光谱融合影像;分割融合影像;利用影像对象的光谱和空间特征执行基于对象的分类。面向对象分类提取结果与传统的基于像元最大似然分类结果进行对比,表明面向对象分类方法更适用于提取高分辨率遥感影像中的建筑物。     

融合光谱及形态学信息的对象级空间特征提取方法

针对传统的高分辨率遥感影像分割方法仅利用光谱特征或者形态学特征的弊端,提出了一种融合光谱信息和形态学信息的多尺度分割算法。该算法首先利用差分多尺度形态学序列特征与影像光谱特征构造光谱-形态学特征集,然后利用Hausdorff距离计算相邻像素的边权值并构造图模型,利用最小生成树Kruskal算法完成影像的初始分割,最后结合分形网络进化的区域异质性准则完成区域合并。在该分割结果的基础上,提出了面向对象的灰度共生矩阵特征和面向对象的像元形状指数特征。实验结果显示,所提出的分割方法在效果和效率上均优于eCognition 8.0和Meanshift算法,并且对象级灰度共生矩阵特征和对象级像元形状指数特征明显优于传统的像素级特征。     

多层级二值模式的高光谱影像空-谱分类

利用高光谱遥感影像的空间纹理特征,可以提高高光谱遥感影像的分类精度。提出了一种多层级二值模式的高光谱影像空-谱联合分类方法。该方法将高光谱影像转化为局部二值模式特征图像获取像元微观特征,基于特征图像生成多层级特征向量获取像元宏观特征。为验证该方法的有效性,选取PaviaU、Salinas和Chikusei高光谱影像数据,利用核极限学习机分类器,分别针对光谱、局部二值模式、多层级二值模式等特征开展实验。结果表明,多层级二值模式空-谱分类总体精度分别达到97.31%、98.96%和97.85%,明显优于传统光谱、3Gabor空-谱等分类方法。该方法可为高光谱影像分类提供更加有效的类别判定特征,有助于提高影像分类精度并获取更加平滑的分类结果图。     

Comparative study on projected clustering methods for hyperspectral imagery classification

In this study, projected clustering is introduced to hyperspectral imagery for unsupervised classification. The main advantage of projected clustering lies in its ability to simultaneously perform feature selection and clustering. This framework also allows selection of different sets of dimensions (features/bands) for different clusters. This framework provides an effective way to address the issues associated with the high dimensionality of the data. Experiments are conducted on both synthetic and real hyperspectral imagery. For this purpose, projected clustering algorithms are implemented and compared with k-means and k-means preceded by principal component analysis. Preliminary analyses of studied algorithms on synthetic hyperspectral imagery demonstrate good results. For real hyperspectral imagery, only ORCLUS is able to produce acceptable results as compared to other unsupervised methods. The main concern lies with identification of right parameter settings. More experiments are required in this direction.     

Band Selection and Dimension Estimation for Hyperspectral Imagery—a New Approach Based on Invasive Weed Optimization

Currently, hyperspectral images have potential applications in many scientific areas due to the high spectral resolution. Extracting suitable and adequate bands/features from high dimensional data is a crucial task to classify such data. To overcome this issue, dimension reduction techniques have direct effects to improve the efficiency of classifiers on hyperspectral images. One common approach for decreasing the dimensionality is the feature/band selection by considering the optimum dimensionality of the hyperspectral imagery. In this paper, a new method was proposed to select optimal band for classification application, based on a metaheuristic Invasive Weed Optimization (IWO) algorithm. In this regard, the K-nearest neighbour (K-NN) technique was used as the classifier. Moreover, as a by-product of our band selection method, a new method was proposed to estimate an optimum dimension of the reduced hyperspectral images for better classification. Experimental results over three real-world hyperspectral datasets clearly showed that the proposed IWO-based band selection algorithm of this study led to the significant progress in selecting suitable bands for classification applications and estimation of optimum dimensionality of these datasets. In this regard, the overall accuracy (OA) of classification of the proposed IWO-based band selection algorithm was 92.02, 93.57, and 89.72 % for each dataset, respectively. Moreover, results reveal the superiority of the proposed IWO-based band selection algorithm against the other algorithms including GA, SA, ACO, and PSO for band selection purpose.     

高光谱影像的DAE分类

针对高光谱影像非线性分类问题,根据高光谱影像光谱分辨率高且光谱具有非线性的特点,结合深度学习理论,提出了一种采用降噪自动编码器(DAE)的高光谱影像分类方法。该方法结合降噪自动编码器与SOFTMAX分类器,构造深层网络分类模型;然后,利用加噪后的光谱数据,采用Dropout方法对分类模型进行预训练和微调;最后,利用训练得到的网络模型学习高光谱影像光谱的隐含特征,实现高光谱影像的分类。采用该方法对AVIRIS和PHI的高光谱影像分别进行分类对比实验,结果表明该方法能有效提高高光谱影像分类精度。     

A fast clonal selection algorithm for feature selection in hyperspectral imagery

Clonal selection feature selection algorithm (CSFS) based on clonal selection algorithm (CSA), a new computational intelligence approach, has been proposed to perform the task of dimensionality reduction in high-dimensional images, and has better performance than traditional feature selection algorithms with more computational costs. In this paper, a fast clonal selection feature selection algorithm (FCSFS) for hyperspectral imagery is proposed to improve the convergence rate by using Cauchy mutation instead of non-uniform mutation as the primary immune operator. Two experiments are performed to evaluate the performance of the proposed algorithm in comparison with CSFS using hyperspectral remote sensing imagery acquired by the pushbroom hyperspectral imager (PHI) and the airborne visible/infrared imaging spectrometer (AVIRIS), respectively. Experimental results demonstrate that the FCSFS converges faster than CSFS, hence providing an effective new option for dimensionality reduction of hyperspectral remote sensing imagery.     

基于支持向量回归的高光谱影像目标探测

高光谱影像目标探测可视为一个分类问题,本文通过揭示支持向量回归(SVR)与支持向量分类(SVC)之间的关系,证明了SVR用于分类的可行性,并以此为根据提出了一种基于SVR的目标探测算法,该算法利用虚拟维数得到端元个数的估计,结合端元选择和线性混合模型生成训练样本替代从影像中选择的训练样本,因而减少了对影像先验知识的依赖。采用模拟数据和由AVIRIS获得的高光谱影像对本文算法进行了检验,结果令人满意。     

面向对象的高分辨率遥感影像地理要素提取

应用面向对象影像分类方法进行空间目标特征提取和分析,实现利用遥感影像建立与更新地理空间数据库,对于正在进行的数字城市建设和国情监测具有重要的意义和作用。本文阐述了高空间分辨率影像特征提取的关键技术,采用面向对象的特征提取技术和影像分类方法,开展了基于ADS40航空影像的地理要素提取实验,获得了比较满意的专题信息。     

利用可分离非负矩阵分解实现高光谱波段选择

高光谱影像波段众多且相关性强,导致分类存在信息冗余且计算量较大。提出了可分离非负矩阵分解方法来选取高光谱影像的代表性波段子集,在保证分类精度的同时降低计算量。该方法假设高光谱影像的波段集合具有可分离特性,改进传统非负矩阵分解模型,将波段选择转换为可分离非负矩阵分解问题,采用迭代投影方法来依次选取能够非负线性表达其他波段的代表性波段。在此基础上,利用两个公开高光谱数据集对比几种主流方法,采用定量评价和分类精度指标来综合评价所提的波段选择方法的效果。实验结果表明,可分离非负矩阵分解方法的分类精度高于其他几种方法,而且计算效率排名第2,能够选取合适的波段子集以满足高光谱遥感的应用需求。     

Object-based habitat mapping using very high spatial resolution multispectral and hyperspectral imagery with LiDAR data

This study investigated the combined use of multispectral/hyperspectral imagery and LiDAR data for habitat mapping across parts of south Cumbria, North West England. The methodology adopted in this study integrated spectral information contained in pansharp QuickBird multispectral/AISA Eagle hyperspectral imagery and LiDAR-derived measures with object-based machine learning classifiers and ensemble analysis techniques. Using the LiDAR point cloud data, elevation models (such as the Digital Surface Model and Digital Terrain Model raster) and intensity features were extracted directly. The LiDAR-derived measures exploited in this study included Canopy Height Model, intensity and topographic information (i.e. mean, maximum and standard deviation). These three LiDAR measures were combined with spectral information contained in the pansharp QuickBird and Eagle MNF transformed imagery for image classification experiments. A fusion of pansharp QuickBird multispectral and Eagle MNF hyperspectral imagery with all LiDAR-derived measures generated the best classification accuracies, 89.8 and 92.6% respectively. These results were generated with the Support Vector Machine and Random Forest machine learning algorithms respectively. The ensemble analysis of all three learning machine classifiers for the pansharp QuickBird and Eagle MNF fused data outputs did not significantly increase the overall classification accuracy. Results of the study demonstrate the potential of combining either very high spatial resolution multispectral or hyperspectral imagery with LiDAR data for habitat mapping.     

A Multiple SVM System for Classification of Hyperspectral Remote Sensing Data

With recent technological advances in remote sensing sensors and systems, very high-dimensional hyperspectral data are available for a better discrimination among different complex land-cover classes. However, the large number of spectral bands, but limited availability of training samples creates the problem of Hughes phenomenon or ‘curse of dimensionality’ in hyperspectral data sets. Moreover, these high numbers of bands are usually highly correlated. Because of these complexities of hyperspectral data, traditional classification strategies have often limited performance in classification of hyperspectral imagery. Referring to the limitation of single classifier in these situations, Multiple Classifier Systems (MCS) may have better performance than single classifier. This paper presents a new method for classification of hyperspectral data based on a band clustering strategy through a multiple Support Vector Machine system. The proposed method uses the band grouping process based on a modified mutual information strategy to split data into few band groups. After the band grouping step, the proposed algorithm aims at benefiting from the capabilities of SVM as classification method. So, the proposed approach applies SVM on each band group that is produced in a previous step. Finally, Naive Bayes (NB) as a classifier fusion method combines decisions of SVM classifiers. Experimental results on two common hyperspectral data sets show that the proposed method improves the classification accuracy in comparison with the standard SVM on entire bands of data and feature selection methods.