Abstract
Due to the limited varieties and sizes of existing public hyperspectral image (HSI) datasets, the classification accuracies are higher than 99% with convolutional neural networks (CNNs). In this paper, we presented a new HSI dataset named Shandong Feicheng, whose size and pixel quantity are much larger. It also has a larger intra-class variance and a smaller inter-class variance. State-of-the-art methods were compared on it to verify its diversity. Otherwise, to reduce overfitting caused by the imbalance between high dimension and small quantity of labeled HSI data, existing CNNs for HSI classification are relatively shallow and suffer from low capacity of feature learning. To solve this problem, we proposed an HSI classification framework named deep residual spectral spatial setwork (DRSSN). By using shortcut connection structure, which is an asymmetry structure, DRSSN can be deeper to extract features with better discrimination. In addition, to alleviate insufficient training caused by unbalanced sample sizes between easily and hard classified samples, we proposed a novel training loss function named sample balanced loss, which allocated weights to the losses of samples according to their prediction confidence. Experimental results on two popular datasets and our proposed dataset showed that our proposed network could provide competitive results compared with state-of-the-art methods.
Highlights
Hyperspectral image (HSI) consists of hundreds of narrow contiguous wavelength bands carrying a wealth of spectral information
The difficulty in hyperspectral image (HSI) classification lies in the inherent data characteristics of HSI data: First, the high-dimensions of hyperspectral pixels and information redundancy between adjacent bands lead to high calculation cost
The proposed DRSSN was compared with state-of-the-art HSI classification methods proposed in [21] and [22] on several datasets
Summary
Hyperspectral image (HSI) consists of hundreds of narrow contiguous wavelength bands carrying a wealth of spectral information. Taking advantage of the rich spectral information, classification using hyperspectral data has been developed for a variety of applications, such as image segmentation, object recognition, land cover mapping and anomaly detection [1,2,3,4]. The difficulty in HSI classification lies in the inherent data characteristics of HSI data: First, the high-dimensions of hyperspectral pixels and information redundancy between adjacent bands lead to high calculation cost. Factors such as different shooting time, different shooting environment or physical limitations of acquisition technology may cause the problem of large intra-class variance and small inter-class variance.
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