Abstract
This study proposes a deep quadruplet network (DQN) for hyperspectral image classification given the limitation of having a small number of samples. A quadruplet network is designed, which makes use of a new quadruplet loss function in order to learn a feature space where the distances between samples from the same class are shortened, while those from a different class are enlarged. A deep 3-D convolutional neural network (CNN) with characteristics of both dense convolution and dilated convolution is then employed and embedded in the quadruplet network to extract spatial-spectral features. Finally, the nearest neighbor (NN) classifier is used to accomplish the classification in the learned feature space. The results show that the proposed network can learn a feature space and is able to undertake hyperspectral image classification using only a limited number of samples. The main highlights of the study include: (1) The proposed approach was found to have high overall accuracy and can be classified as state-of-the-art; (2) Results of the ablation study suggest that all the modules of the proposed approach are effective in improving accuracy and that the proposed quadruplet loss contributes the most; (3) Time-analysis shows the proposed methodology has a similar level of time consumption as compared with existing methods.
Highlights
A hyperspectral image covers hundreds of bands with high spectral resolution and provides a detailed spectral curve for each pixel [1,2]
Many methods have been proposed for the hyperspectral image classification, such as spectral angle mapper (SAM), mixture tuned matched filtering (MTMF), spectral feature fitting (SFF) [3,4], neural network (NN) [5], support vector machine (SVM) [6,7], and random forest (RF) [8,9]
SAM, MTMF, and SFF are heavily influenced by anthropogenic decision-making, while NN, SVM, and RF are gradually becoming more dependent on new machine learning methods
Summary
A hyperspectral image covers hundreds of bands with high spectral resolution and provides a detailed spectral curve for each pixel [1,2]. Both the spatial and the spectral information are gathered in a hyperspectral image. Many methods have been proposed for the hyperspectral image classification, such as spectral angle mapper (SAM), mixture tuned matched filtering (MTMF), spectral feature fitting (SFF) [3,4], neural network (NN) [5], support vector machine (SVM) [6,7], and random forest (RF) [8,9]. Some deep-learning methods have been proposed by combining spectral and spatial features to improve classification accuracy [15,16,17,18,19,20,21]
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