Abstract
Urban object segmentation and classification tasks are critical data processing steps in scene understanding, intelligent vehicles and 3D high-precision maps. Semantic segmentation of 3D point clouds is the foundational step in object recognition. To identify the intersecting objects and improve the accuracy of classification, this paper proposes a segment-based classification method for 3D point clouds. This method firstly divides points into multi-scale supervoxels and groups them by proposed inverse node graph (IN-Graph) construction, which does not need to define prior information about the node, it divides supervoxels by judging the connection state of edges between them. This method reaches minimum global energy by graph cutting, obtains the structural segments as completely as possible, and retains boundaries at the same time. Then, the random forest classifier is utilized for supervised classification. To deal with the mislabeling of scattered fragments, higher-order CRF with small-label cluster optimization is proposed to refine the classification results. Experiments were carried out on mobile laser scan (MLS) point dataset and terrestrial laser scan (TLS) points dataset, and the results show that overall accuracies of 97.57% and 96.39% were obtained in the two datasets. The boundaries of objects were retained well, and the method achieved a good result in the classification of cars and motorcycles. More experimental analyses have verified the advantages of the proposed method and proved the practicability and versatility of the method.
Highlights
A segment-based semantic segmentation method of 3D point clouds is proposed to classify the objects in the urban scene
(2) In the label refinement step, it individually deals with the small-label cluster based on the higher-order conditional random field (CRF), which further optimizes the mislabeling of the fragments, and a simplified algorithm is carried out to speed up the efficiency of the optimization
Paris-rue-Cassette mobile laser scan (MLS) dataset and the Wuhan University terrestrial laser scan (TLS) dataset, in comparison with three other state-of-the-art methods: the method in this paper achieved a better overall accuracy and mean F1-score, 97.57% and 77.06% in the Paris-rue-Cassette dataset, respectively
Summary
With the development of sensing devices and urbanization, smart cities have become an important concept in urban understanding and management. Three-dimensional laser scanning is a fast and accurate technique to obtain high-precision 3D geographical distributions of urban scenes [1,2,3]. Three-dimensional point cloud data have become a very useful data source in perceiving urban elements. Parameterization of 3D point clouds is an important way to reconstruct urban scenes, which refers to the transformation of basic reconstruction of cities. The semantic segmentation of 3D point clouds is a fundamental
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