Abstract
Land-cover information is significant for land-use planning, urban management, and environment monitoring. This paper presented a novel extended topology-preserving segmentation (ETPS)-based multi-scale and multi-feature method using the convolutional neural network (EMMCNN) for high spatial resolution (HSR) image land-cover classification. The EMMCNN first segmented the images into superpixels using the ETPS algorithm with false-color composition and enhancement and built parallel convolutional neural networks (CNNs) with dense connections for superpixel multi-scale deep feature learning. Then, the multi-resolution segmentation (MRS) object hand-delineated features were extracted and mapped to superpixels for complementary multi-segmentation and multi-type representation. Finally, a hybrid network was designed to consist of 1-dimension CNN and multi-layer perception (MLP) with channel-wise stacking and attention-based weighting for adaptive feature fusion and comprehensive classification. Experimental results on four real HSR GaoFen-2 datasets demonstrated the superiority of the proposed EMMCNN over several well-known classification methods in terms of accuracy and consistency, with overall accuracy averagely improved by 1.74% to 19.35% for testing images and 1.06% to 8.78% for validating images. It was found that the solution combining an appropriate number of larger scales and multi-type features is recommended for better performance. Efficient superpixel segmentation, networks with strong learning ability, optimized multi-scale and multi-feature solution, and adaptive attention-based feature fusion were key points for improving HSR image land-cover classification in this study.
Highlights
Land-cover information reflects the distribution of various natural and man-made ground objects, which is essential for land-use planning, urban management, and environment monitoring
Overall accuracy (OA) is the percentage of rightly predicted pixels in all pixels, and user’s accuracy (UA) and producer’s accuracy (PA) are the correct percentages for each class related to the classification and reference maps, respectively
high spatial resolution (HSR) images were first segmented into superpixels using the extended topology-preserving segmentation (ETPS) algorithm with false-color composition and image enhancement to improve the boundary adherence to confusing ground objects, and parallel dense convolutional neural networks (CNNs) were built for superpixel multi-scale deep and effective feature learning
Summary
Land-cover information reflects the distribution of various natural and man-made ground objects, which is essential for land-use planning, urban management, and environment monitoring. The clear visibility of objects’ composition and surrounding peripherals can cause high intra-class variability, and the similarity of construction materials and spectral properties among man-made objects can lead to low inter-class disparity, making land-cover classification of HSR images a challenging task [5,6]. Object-based methods require great domain knowledge for object segmentation and feature selection [1,9,10,11], and it is difficult to represent multi-scale ground objects using a single segmentation parameter. Many superpixel segmentation algorithms are developed from computer vision and designed for natural images, which are not directly applicable to multi-spectral remote sensing images. We adopted superpixels as processing units for HSR image land-cover classification and made efforts to adapt to multi-spectral images and join with deep feature extraction
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