Abstract
In hyperspectral image (HSI) classification, convolutional neural networks (CNN) have been attracting increasing attention because of their ability to represent spectral-spatial features. Nevertheless, the conventional CNN models perform convolution operation on regular-grid image regions with a fixed kernel size and as a result, they neglect the inherent relation between HSI data. In recent years, graph convolutional networks (GCN) used for data representation in a non-Euclidean space, have been successfully applied to HSI classification. However, conventional GCN methods suffer from a huge computational cost since they construct the adjacency matrix between all HSI pixels, and they ignore the local spatial context information of hyperspectral images. To alleviate these shortcomings, we propose a novel method termed spectral-spatial offset graph convolutional networks (SSOGCN). Different from the usually used GCN models that compute the adjacency matrix between all pixels, we construct an adjacency matrix only using pixels within a patch, which contains rich local spatial context information, while reducing the computation cost and memory consumption of the adjacency matrix. Moreover, to emphasize important local spatial information, an offset graph convolution module is proposed to extract more robust features and improve the classification performance. Comprehensive experiments are carried out on three representative benchmark data sets, and the experimental results effectively certify that the proposed SSOGCN method has more advantages than the recent state-of-the-art (SOTA) methods.
Highlights
In recent years, hyperspectral imaging technology has witnessed rapid and sustained development, and the corresponding spectral resolution and spatial resolution have been significantly improved, which is beneficial to the accurate classification and recognition of surface objects [1]
It can be seen that our methods are improved by 17.81%, 21.18% in overall accuracy (OA), respectively, compared with graph convolutional networks (GCN), minibatch graph convolutional network (miniGCN), which mainly model long-range spatial relationships and ignore local spatial information
It has a great improvement in OA compared with 2D-convolutional neural networks (CNN) which is restricted by the fixed convolution kernel
Summary
Hyperspectral imaging technology has witnessed rapid and sustained development, and the corresponding spectral resolution and spatial resolution have been significantly improved, which is beneficial to the accurate classification and recognition of surface objects [1]. Due to the large amounts of spectral bands, HSI classification tasks still suffer from many challenges. Feature extraction is one of the effective ways to solve these problems. Complications situations such as spectral variability [6] bring a great challenge to the feature extraction task. It was acquired by the Reflective Optics System Imaging Spectrometer (ROSIS) sensor in 2002. The data set includes nine land cover classes, and a total of 42,776 samples can be referred.
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