Abstract
Convolutional neural networks (CNNs) have been widely applied in hyperspectral imagery (HSI) classification. However, their classification performance might be limited by the scarcity of labeled data to be used for training and validation. In this paper, we propose a novel lightweight shuffled group convolutional neural network (abbreviated as SG-CNN) to achieve efficient training with a limited training dataset in HSI classification. SG-CNN consists of SG conv units that employ conventional and atrous convolution in different groups, followed by channel shuffle operation and shortcut connection. In this way, SG-CNNs have less trainable parameters, whilst they can still be accurately and efficiently trained with fewer labeled samples. Transfer learning between different HSI datasets is also applied on the SG-CNN to further improve the classification accuracy. To evaluate the effectiveness of SG-CNNs for HSI classification, experiments have been conducted on three public HSI datasets pretrained on HSIs from different sensors. SG-CNNs with different levels of complexity were tested, and their classification results were compared with fine-tuned ShuffleNet2, ResNeXt, and their original counterparts. The experimental results demonstrate that SG-CNNs can achieve competitive classification performance when the amount of labeled data for training is poor, as well as efficiently providing satisfying classification results.
Highlights
Hyperspectral sensors are able to grasp detailed information of objects and phenomena on Earth’s surface by severing their spectral characteristics in a large number of channels over a wide portion of the electromagnetic spectrum
We used conventional convolution, but we introduced atrous convolution into the group convolution, which was followed by a channel shuffle operation; this is a major difference with respect to the ResNeXt structure
Only limited labeled samples are available for hyperspectral imagery (HSI) classification
Summary
Hyperspectral sensors are able to grasp detailed information of objects and phenomena on Earth’s surface by severing their spectral characteristics in a large number of channels (bands) over a wide portion of the electromagnetic spectrum Such rich spectral information allows hyperspectral imagery (HSI) to be used for interpretation and analysis of surface materials in a more thorough way. Existing DL methods include fully connected feedforward neural networks [18,19,20], convolutional neural networks (CNNs) [21,22,23], recurrent neural networks (RNNs) [24,25], and so on Among these networks, CNN has become the major deep learning framework applied for hyperspectral image classification, as it can maintain the local invariance of the image and has a relatively small number of coefficients to be tuned [26]
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