Abstract
Hyperspectral remote sensing obtains abundant spectral and spatial information of the observed object simultaneously. It is an opportunity to classify hyperspectral imagery (HSI) with a fine-grained manner. In this study, the fine-grained classification of HSI, which contains a large number of classes, is investigated. On one hand, traditional classification methods cannot handle fine-grained classification of HSI well; on the other hand, deep learning methods have shown their powerfulness in fine-grained classification. So, in this paper, deep learning is explored for HSI supervised and semi-supervised fine-grained classification. For supervised HSI fine-grained classification, densely connected convolutional neural network (DenseNet) is explored for accurate classification. Moreover, DenseNet is combined with pre-processing technique (i.e., principal component analysis or auto-encoder) or post-processing technique (i.e., conditional random field) to further improve classification performance. For semi-supervised HSI fine-grained classification, a generative adversarial network (GAN), which includes a discriminative CNN and a generative CNN, is carefully designed. The GAN fully uses the labeled and unlabeled samples to improve classification accuracy. The proposed methods were tested on the Indian Pines data set, which contains 33,3951 samples with 52 classes. The experimental results show that the deep learning-based methods provide great improvements compared with other traditional methods, which demonstrate that deep models have huge potential for HSI fine-grained classification.
Highlights
Hyperspectral imaging obtains data of the observing target with spectral and spatial information simultaneously and has become a useful tool for a wide branch of users
The extended morphological profiles with RF (EMP-RF) method had the lowest precise in the dataset (see Figure 8(b)), and compared with the traditional methods, the deep learning methods achieved a superior performance in classification, we can see that our proposed Semi-generative adversarial network (GAN) gave a more detailed supervised methods
The deep models reduced the total consuming time drastically and improved the classification performance at the same time when compared with support vector machines (SVMs) model
Summary
Hyperspectral imaging obtains data of the observing target with spectral and spatial information simultaneously and has become a useful tool for a wide branch of users. Among the hyperspectral imagery (HSI) processing methods, classification is one of the core techniques, which tries to allocate a specific class to each pixel in the scene. In the context of hyperspectral remote sensing, varieties of instruments will be available for Earth observation. Those advanced technologies have increased different types of satellites images which have different resolutions in spectral and spatial dimensions. It leads to difficulties and opportunities for data processing techniques [2]
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