Abstract
In various applications of airborne laser scanning (ALS), the classification of the point cloud is a basic and key step. It requires assigning category labels to each point, such as ground, building or vegetation. Convolutional neural networks have achieved great success in image classification and semantic segmentation, but they cannot be directly applied to point cloud classification because of the disordered and unstructured characteristics of point clouds. In this paper, we design a novel convolution operator to extract local features directly from unstructured points. Based on this convolution operator, we define the convolution layer, construct a convolution neural network to learn multi-level features from the point cloud, and obtain the category label of each point in an end-to-end manner. The proposed method is evaluated on two ALS datasets: the International Society for Photogrammetry and Remote Sensing (ISPRS) Vaihingen 3D Labeling benchmark and the 2019 IEEE Geoscience and Remote Sensing Society (GRSS) Data Fusion Contest (DFC) 3D dataset. The results show that our method achieves state-of-the-art performance for ALS point cloud classification, especially for the larger dataset DFC: we get an overall accuracy of 97.74% and a mean intersection over union (mIoU) of 0.9202, ranking in first place on the contest website.
Highlights
The three-dimensional (3D) point cloud has become an important data source for reconstructing and understanding the real world because of its abundant geometry, shape and scale information
We evaluated the proposed methods, using International Society for Photogrammetry and Remote Sensing (ISPRS) Vaihingen 3D data and 2019 IEEE Geoscience and Remote Sensing Society (GRSS) Data Fusion Contest (DFC) 3D data
The airborne light detection and ranging (LiDAR) point cloud data were captured by a Leica ALS50 with a mean flying height 500 m above Vaihingen, Germany
Summary
The three-dimensional (3D) point cloud has become an important data source for reconstructing and understanding the real world because of its abundant geometry, shape and scale information. Many applications of ALS point clouds have been explored, such as digital elevation model (DEM) generation [1,2], building reconstruction [3,4], road extraction [5,6], forest mapping [7,8], power line monitoring [9,10] and so on. For these applications, the basic and critical step is the classification of the 3D point cloud, which is called semantic segmentation of the point cloud in the field of computer vision. Due to the unstructured and disordered characteristics of point clouds, especially in urban scenes with different object types and variable point densities, the accurate and efficient classification of ALS point clouds is still a challenging task
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