Abstract
Convolutional neural networks have been highly successful in hyperspectral image classification owing to their unique feature expression ability. However, the traditional data partitioning strategy in tandem with patch-wise classification may lead to information leakage and result in overoptimistic experimental insights. In this paper, we propose a novel data partitioning scheme and a triple-attention parallel network (TAP-Net) to enhance the performance of HSI classification without information leakage. The dataset partitioning strategy is simple yet effective to avoid overfitting, and allows fair comparison of various algorithms, particularly in the case of limited annotated data. In contrast to classical encoder–decoder models, the proposed TAP-Net utilizes parallel subnetworks with the same spatial resolution and repeatedly reuses high-level feature maps of preceding subnetworks to refine the segmentation map. In addition, a channel–spectral–spatial-attention module is proposed to optimize the information transmission between different subnetworks. Experiments were conducted on three benchmark hyperspectral datasets, and the results demonstrate that the proposed method outperforms state-of-the-art methods with the overall accuracy of 90.31%, 91.64%, and 81.35% and the average accuracy of 93.18%, 87.45%, and 78.85% over Salinas Valley, Pavia University and Indian Pines dataset, respectively. It illustrates that the proposed TAP-Net is able to effectively exploit the spatial–spectral information to ensure high performance.
Highlights
With the rapid development of hyperspectral imaging technologies, it is feasible to collect hundreds of contiguous narrow spectral bands for each pixel in a scene [1,2]
Even though it has attracted considerable attention, it remains a challenging problem because of the limited number of training samples and the spatial variability of spectral signatures [6]. Both spectral and spatial information should be considered in hyperspectral image (HSI) classification, whereas early HSI classification methods primarily focused on the study of a continuous spectrum in an effort to classify pixels using distinguishable spectral features [7,8]
We introduce a novel routine for data partitioning and a triple-attention parallel network for HSI classification
Summary
With the rapid development of hyperspectral imaging technologies, it is feasible to collect hundreds of contiguous narrow spectral bands for each pixel in a scene [1,2]. This abundant spectral and spatial information in hyperspectral remote sensing data has been widely used in a broad range of applications with unprecedented accuracy [3] Among these applications, hyperspectral image (HSI) classification (or semantic segmentation), which aims at assigning a unique label to each pixel of HSI, is a critical enabling step for land-cover monitoring, ecological science, environmental science, and precision agriculture [4,5]. Hyperspectral image (HSI) classification (or semantic segmentation), which aims at assigning a unique label to each pixel of HSI, is a critical enabling step for land-cover monitoring, ecological science, environmental science, and precision agriculture [4,5] Even though it has attracted considerable attention, it remains a challenging problem because of the limited number of training samples and the spatial variability of spectral signatures [6].
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