Abstract
3D semantic labeling is a fundamental task in airborne laser scanning (ALS) point clouds processing. The complexity of observed scenes and the irregularity of point distributions make this task quite challenging. Existing methods rely on a large number of features for the LiDAR points and the interaction of neighboring points, but cannot exploit the potential of them. In this paper, a convolutional neural network (CNN) based method that extracts the high-level representation of features is used. A point-based feature image-generation method is proposed that transforms the 3D neighborhood features of a point into a 2D image. First, for each point in the ALS data, the local geometric features, global geometric features and full-waveform features of its neighboring points within a window are extracted and transformed into an image. Then, the feature images are treated as the input of a CNN model for a 3D semantic labeling task. Finally, to allow performance comparisons with existing approaches, we evaluate our framework on the publicly available datasets provided by the International Society for Photogrammetry and Remote Sensing Working Groups II/4 (ISPRS WG II/4) benchmark tests on 3D labeling. The experiment results achieve 82.3% overall accuracy, which is the best among all considered methods.
Highlights
The classification of 3D point clouds has generated great attention in the fields of computer vision, remote sensing, and photogrammetry
We find the proper values of the three parameters, showing that the end results of our method CNN_DEIV perform well on overall accuracy (82.3%) and average F1 (61.6%)
We propose a point-based feature image-generation method used by a convolutional neural network (CNN)
Summary
The classification of 3D point clouds has generated great attention in the fields of computer vision, remote sensing, and photogrammetry. The ALS point clouds allow an automated analysis of large areas in terms of assigning a (semantic) class label to each point of the considered 3D point cloud. In addition to generative classifiers to model the joint distribution of the data and labels [1], modern discriminative methods such as Adaboost [2], Support Vector. Chehata [6] applied the RF to classify full-waveform LiDAR data. Various multi-echo and full-waveform LiDAR features can be processed and Random Forests are used since they provide an accurate classification and run efficiently on large datasets. Mallet [7] used a point-based multi-class SVM for urban area
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