Abstract
Due to the spectral complexity and high dimensionality of hyperspectral images (HSIs), the processing of HSIs is susceptible to the curse of dimensionality. In addition, the classification results of ground truth are not ideal. To overcome the problem of the curse of dimensionality and improve classification accuracy, an improved spatial–spectral weight manifold embedding (ISS-WME) algorithm, which is based on hyperspectral data with their own manifold structure and local neighbors, is proposed in this study. The manifold structure was constructed using the structural weight matrix and the distance weight matrix. The structural weight matrix was composed of within-class and between-class coefficient representation matrices. These matrices were obtained by using the collaborative representation method. Furthermore, the distance weight matrix integrated the spatial and spectral information of HSIs. The ISS-WME algorithm describes the whole structure of the data by the weight matrix constructed by combining the within-class and between-class matrices and the spatial–spectral information of HSIs, and the nearest neighbor samples of the data are retained without changing when embedding to the low-dimensional space. To verify the classification effect of the ISS-WME algorithm, three classical data sets, namely Indian Pines, Pavia University, and Salinas scene, were subjected to experiments for this paper. Six methods of dimensionality reduction (DR) were used for comparison experiments using different classifiers such as k-nearest neighbor (KNN) and support vector machine (SVM). The experimental results show that the ISS-WME algorithm can represent the HSI structure better than other methods, and effectively improves the classification accuracy of HSIs.
Highlights
With the development of science and technology, hyperspectral images (HSIs) have become the main research direction in the field of modern remote sensing technology
Given the HSI data set X = [x f, xp, where xf is the spectral reflectance of a pixel and xp is the spatial coordinates of a pixel, to construct Dij, we find each pair of samples i p p xi = [x fi, xi and xj = xfj, xj, where i, j = 1, · · ·, N
The results include the overall accuracy and kappa coefficients of each method, and each result is an average of the results of 10 runs with the associated coefficients each each result is an average of the(OA
Summary
With the development of science and technology, hyperspectral images (HSIs) have become the main research direction in the field of modern remote sensing technology. HSIs have a large number of spectral bands, which provide detailed spectral information about objects [1,2]. Due to the strong correlation between adjacent spectra, there is much redundant information in HSIs, which take up a large storage space and require much computation time. When classifying HSIs, classification accuracy is subject to the curse of dimensionality [3]. In order to improve classification accuracy, a dimensionality reduction (DR) method is a necessary and feasible preprocessing measure for HSI [4,5].
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