Abstract
Deep learning (DL) has shown promising performances in various remote sensing applications as a powerful tool. To explore the great potential of DL in improving the accuracy of individual tree species (ITS) classification, four convolutional neural network models (ResNet-18, ResNet-34, ResNet-50, and DenseNet-40) were employed to classify four tree species using the combined high-resolution satellite imagery and airborne LiDAR data. A total of 1503 samples of four tree species, including maple, pine, locust, and spruce, were used in the experiments. When both WorldView-2 and airborne LiDAR data were used, the overall accuracies (OA) obtained by ResNet-18, ResNet-34, ResNet-50, and DenseNet-40 were 90.9%, 89.1%, 89.1%, and 86.9%, respectively. The OA of ResNet-18 was increased by 4.0% and 1.8% compared with random forest (86.7%) and support vector machine (89.1%), respectively. The experimental results demonstrated that the size of input images impacted on the classification accuracy of ResNet-18. It is suggested that the input size of ResNet models can be determined according to the maximum size of all tree crown sample images. The use of LiDAR intensity image was helpful in improving the accuracies of ITS classification and atmospheric correction is unnecessary when both pansharpened WorldView-2 images and airborne LiDAR data were used.
Highlights
Trees can reduce urban air pollution and noise, prevent soil erosion, and beautify the environment, which is important for ecosystems
This finding supports the importance of the normalized DSM (nDSM) and intensity image in improving the classification accuracy
It shows that support vector machine (SVM) achieved higher overall accuracies (OA) and kappa coefficients than random forest (RF) for each of the six feature combinations
Summary
Trees can reduce urban air pollution and noise, prevent soil erosion, and beautify the environment, which is important for ecosystems. The identification and mapping of the composition of tree species and the analysis of spatial distribution of tree species is crucial for forest conservation and urban planning and management. The remote sensing technology, which has the advantages of covering large areas and revisiting after several hours or days, has been employed in tree species identification for decades [1,2]. As early as the 1960s, aerial photographs were explored for the recognition of tree species [1]. In 1980, Walsh explored satellite data (such as Landsat) to identify and map 12 land-cover types, including seven coniferous forest types [2]. Studies on tree species classification were mainly conducted at the pixel level [3,4].
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