Abstract
Interpretation of 3-D scene through LiDAR point clouds has been a hot research topic for decades. To utilize measured points in the scene, assigning unique tags to the points of the scene with labels linking to individual objects plays a crucial role in the analysis process. In this article, we present a supervised classification approach for the semantic labeling of laser scanning points. A novel method for extracting geometric features is proposed, removing redundant and insignificant information in the local neighborhood of the supervoxels. The proposed feature extraction method uses the supervoxel-based local neighborhood instead of points as basic elements, encapsulating the geometric features of local points. Based on the initial classification results, the graph-based optimization is used to spatially smooth the labeling results, based on the graphical model using the perception weighted edges. Benefiting from the graph-based optimization process, our supervised classification method required only a few training datasets. Experiments were carried out by comparing the semantic labeling results with manually generated ground truth datasets. The performance of the proposed methods with different characteristics was analyzed. By using our testing datasets, we have achieved an overall accuracy of better than 0.8 for assigning the measured points to eight semantic classes.
Highlights
I N RECENT decades, automated interpretation of 3-D scenes with LiDAR has been a popular research topic in fields of photogrammetry [1], remote sensing [2], computer vision [3], architecture [4], civil engineering [5], cadastral investigation [6], and robotics [7]
3-D point clouds encode more precise topological and geometric information of the real 3-D scene than those of 2-D images, if we can provide additional constraints or assumptions based on these topological relations between structures and geometric characters of points, we could achieve a supervised classification without using a large percentage of the training dataset
We present a supervised semantic labeling method designed for classifying 3-D points, with supervoxel-based detrended features calculated in the local neighborhood and graphbased optimization
Summary
I N RECENT decades, automated interpretation of 3-D scenes with LiDAR has been a popular research topic in fields of photogrammetry [1], remote sensing [2], computer vision [3], architecture [4], civil engineering [5], cadastral investigation [6], and robotics [7]. ALS measures point clouds with a far observation distance and a relatively low density, which is usually used for mapping and monitoring a large area since the flying aerial platform can cover a large investigation area. For accurate analysis and interpretation of 3-D urban scenes, TLS and MLS, providing higher scanning density with close observation distance and more precise points with static carrier platform or stations, are more competent. 3-D point clouds encode more precise topological and geometric information of the real 3-D scene than those of 2-D images, if we can provide additional constraints or assumptions based on these topological relations between structures and geometric characters of points, we could achieve a supervised classification without using a large percentage of the training dataset.
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