Abstract
We describe an effective and efficient method for point-wise semantic classification of 3D point clouds. The method can handle unstructured and inhomogeneous point clouds such as those derived from static terrestrial LiDAR or photogammetric reconstruction; and it is computationally efficient, making it possible to process point clouds with many millions of points in a matter of minutes. The key issue, both to cope with strong variations in point density and to bring down computation time, turns out to be careful handling of neighborhood relations. By choosing appropriate definitions of a point’s (multi-scale) neighborhood, we obtain a feature set that is both expressive and fast to compute. We evaluate our classification method both on benchmark data from a mobile mapping platform and on a variety of large, terrestrial laser scans with greatly varying point density. The proposed feature set outperforms the state of the art with respect to per-point classification accuracy, while at the same time being much faster to compute.
Highlights
Dense 3D acquisition technologies like laser scanning and automated photogrammetric reconstruction have reached a high level of maturity, and routinely deliver point clouds with many millions of points
We describe an effective and efficient method for point-wise semantic classification of 3D point clouds
We learn the classifier from 8 scans and test on the other 10 scans. On these more challenging examples we evaluate the influence of the additional A-Signature of Histogram of Orientations (SHOT) and A-Shape Context 3D (SC3D) descriptors
Summary
Dense 3D acquisition technologies like laser scanning and automated photogrammetric reconstruction have reached a high level of maturity, and routinely deliver point clouds with many millions of points. The two main tasks are on the one hand to derive semantic information about the scanned objects, and on the other hand to convert point clouds into higher-level, CAD-like geometric representations. Both tasks have turned out to be surprisingly difficult to automate. Semantic labels (respectively, soft class probabilities) allow one to utilize class-specific a-priori models for subsequent tasks such as surface fitting, object extraction, etc
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