Abstract
Convolutional neural networks (CNNs) have been widely used in hyperspectral image classification in recent years. The training of CNNs relies on a large amount of labeled sample data. However, the number of labeled samples of hyperspectral data is relatively small. Moreover, for hyperspectral images, fully extracting spectral and spatial feature information is the key to achieve high classification performance. To solve the above issues, a deep spectral spatial inverted residuals network (DSSIRNet) is proposed. In this network, a data block random erasing strategy is introduced to alleviate the problem of limited labeled samples by data augmentation of small spatial blocks. In addition, a deep inverted residuals (DIR) module for spectral spatial feature extraction is proposed, which locks the effective features of each layer while avoiding network degradation. Furthermore, a global 3D attention module is proposed, which can realize the fine extraction of spectral and spatial global context information under the condition of the same number of input and output feature maps. Experiments are carried out on four commonly used hyperspectral datasets. A large number of experimental results show that compared with some state-of-the-art classification methods, the proposed method can provide higher classification accuracy for hyperspectral images.
Highlights
With the rapid development of remote sensing imaging technology, hyperspectral image (HSI) has drawn more attention in recent years
In order to verify the performance of DSSIRNet, four classical datasets are used in the experiment
After excluding 20 bands of 104–108, 150–163, and 200 that cannot be reflected by water, the remaining 200 effective bands are taken as the research object
Summary
With the rapid development of remote sensing imaging technology, hyperspectral image (HSI) has drawn more attention in recent years. Each sample of HSI contains reflection information of hundreds of different spectral bands, which makes this kind of image suitable for many practical applications, such as precision agriculture [1], food analysis [2], anomaly detection [3], geological exploration [4,5], etc. Hyperspectral image processing technology has become increasingly popular due to the development of machine learning. (1) the training of deep learning model depends on a great quantity of labeled sample data, while the number of labeled samples in hyperspectral data is insufficient; (2) because HSI contains rich spectral spatial information, the problem that the spectral spatial features of HSI are not effectively extracted still exists [6]. The phenomenon of different spectral curves of the same substance and different substances of the same spectral curves often occur
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