Abstract
In hyperspectral remote sensing, the clustering technique is an important issue of concern. Affinity propagation is a widely used clustering algorithm. However, the complex structure of the hyperspectral image (HSI) dataset presents challenge for the application of affinity propagation. In this paper, an improved version of affinity propagation based on complex wavelet structural similarity index and local outlier factor is proposed specifically for the HSI dataset. In the proposed algorithm, the complex wavelet structural similarity index is used to calculate the spatial similarity of HSI pixels. Meanwhile, the calculation strategy of the spatial similarity is simplified to reduce the computational complexity. The spatial similarity and the traditional spectral similarity of the HSI pixels jointly constitute the similarity matrix of affinity propagation. Furthermore, the local outlier factors are applied as weights to revise the original exemplar preferences of the affinity propagation. Finally, the modified similarity matrix and exemplar preferences are applied, and the clustering index is obtained by the traditional affinity propagation. Extensive experiments were conducted on three HSI datasets, and the results demonstrate that the proposed method can improve the performance of the traditional affinity propagation and provide competitive clustering results among the competitors.
Highlights
Hyperspectral image (HSI) has gradually become a powerful tool with its rich spectral and spatial information, which is widely used in environmental monitoring, fine agriculture, mineral exploration, military targets, and many other fields [1–3]
A modified Affinity propagation (AP) based on CW-structural similarity (SSIM) and local outlier factor (LOF) was proposed
The CWSSIM was used to extract the structure-based spatial similarity of the HSI dataset, which was combined with the pixel-based spectral similarity to generate the final similarity matrix of AP
Summary
Hyperspectral image (HSI) has gradually become a powerful tool with its rich spectral and spatial information, which is widely used in environmental monitoring, fine agriculture, mineral exploration, military targets, and many other fields [1–3]. Though the potentialities of hyperspectral technology appear to be relatively wide, the analysis and treatment of these data remain insufficient [4]. Classification is an important manner in which to exploit. HSI, which can be divided into supervised classification and unsupervised classification. Compared with the supervised classification, the unsupervised classification, known as clustering, can automatically detect the distinct classes in an objective way without training samples. Training samples are very difficult to access for some applications. It is meaningful to study the clustering technology
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