Abstract
With the rapid development of point cloud processing technologies and the availability of a wide range of 3D capturing devices, a geometric object from the real world can be directly represented digitally as a dense and fine point cloud. Decomposing a 3D shape represented in point cloud into meaningful parts has very important practical implications in the fields of computer graphics, virtual reality and mixed reality. In this paper, a semantic-driven automated hybrid segmentation method is proposed for 3D point cloud shapes. Our method consists of three stages: semantic clustering, variational merging, and region remerging. In the first stage, a new feature of point cloud, called Local Concave-Convex Histogram, is introduced to first extract saddle regions complying with the semantic boundary feature. All other types of regions are then aggregated according to this extracted feature. This stage often leads to multiple over-segmentation convex regions, which are then remerged by a variational method established based on the narrow-band theory. Finally, in order to recombine the regions with the approximate shapes, order relation is introduced to improve the weighting forms in calculating the conventional Shape Diameter Function. We have conducted extensive experiments with the Princeton Dataset. The results show that the proposed algorithm outperforms the state-of-the-art algorithms in this area. We have also applied the proposed algorithm to process the point cloud data acquired directly from the real 3D objects. It achieves excellent results too. These results demonstrate that the method proposed in this paper is effective and universal.
Highlights
3D shape segmentation is a fundamental task in geometric information processing, geometric object recognition and reconstruction, and computer graphics
An efficient semantic-driven 3D point cloud hybrid segmentation algorithm is proposed in this paper
Based on the Local Concave-Convex Histogram (LCCH), the boundary regions which meet the semantic-driven requirements are obtained. This is accompanied with several other type-specific region clustering operations to achieve the semantic clustering of the 3D point cloud
Summary
Depending on the way in which a 3D shape is represented, its segmentation can be represented as a set of the topological adjacent points, edges or faces. By 3D shape segmentation, texture mapping for a complex geometry, which is a very difficult task, can be reduced to a set of simpler tasks of mapping. With the ever increasing development of the devices for 3D data acquisition and other related technologies, it becomes increasingly easy to capture the 3D points. Thanks to these developments, the 3D point cloud is able to contain rich information nowadays. There are a wide range of the applications which make use of 3D point cloud data [2], [3]
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