Abstract
High dimensional image classification is a fundamental technique for information retrieval from hyperspectral remote sensing data. However, data quality is readily affected by the atmosphere and noise in the imaging process, which makes it difficult to achieve good classification performance. In this paper, multiple kernel learning-based low rank representation at superpixel level (Sp_MKL_LRR) is proposed to improve the classification accuracy for hyperspectral images. Superpixels are generated first from the hyperspectral image to reduce noise effect and form homogeneous regions. An optimal superpixel kernel parameter is then selected by the kernel matrix using a multiple kernel learning framework. Finally, a kernel low rank representation is applied to classify the hyperspectral image. The proposed method offers two advantages. (1) The global correlation constraint is exploited by the low rank representation, while the local neighborhood information is extracted as the superpixel kernel adaptively learns the high-dimensional manifold features of the samples in each class; (2) It can meet the challenges of multiscale feature learning and adaptive parameter determination in the conventional kernel methods. Experimental results on several hyperspectral image datasets demonstrate that the proposed method outperforms several state-of-the-art classifiers tested in terms of overall accuracy, average accuracy, and kappa statistic.
Highlights
The hyperspectral image (HSI) reflects information on hundreds of adjacent narrow spectral bands collected by the airborne or space-borne hyperspectral imagers
Based on the rich spectral information of HSI, many pixel-by-pixel classification methods are used for hyperspectral image classification, such as multinomial logistic regression (MLR) [11], support vector machine (SVM) [12], artificial neural network (ANN) [13], and maximum likelihood method [14]
A hyperspectral classification method is proposed, which is designed on the basis of a superpixel kernel, multiple kernel learning, and low rank representation
Summary
The hyperspectral image (HSI) reflects information on hundreds of adjacent narrow spectral bands collected by the airborne or space-borne hyperspectral imagers. HSI classification is a hotspot in the field of remote sensing image processing [5,6,7,8,9,10]. Based on the rich spectral information of HSI, many pixel-by-pixel classification methods are used for hyperspectral image classification, such as multinomial logistic regression (MLR) [11], support vector machine (SVM) [12], artificial neural network (ANN) [13], and maximum likelihood method [14]. The sparse/low rank classifier [15,16,17] has been applied to conduct HSI classification. These types of methods use sparse or low rank properties to exploit the prior knowledge. Given a training sample set, any test sample can be represented by a small number of training samples as the representation coefficient is sparse or of low rank
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