Abstract
The automating classification of point clouds capturing urban scenes is critical for supporting applications that demand three-dimensional (3D) models. Achieving this goal, however, is met with challenges because of the varying densities of the point clouds and the complexity of the 3D data. In order to increase the level of automation in the point cloud classification, this study proposes a segment-based parameter learning method that incorporates a two-dimensional (2D) land cover map, in which a strategy of fusing the 2D land cover map and the 3D points is first adopted to create labelled samples, and a formalized procedure is then implemented to automatically learn the following parameters of point cloud classification: the optimal scale of the neighborhood for segmentation, optimal feature set, and the training classifier. It comprises four main steps, namely: (1) point cloud segmentation; (2) sample selection; (3) optimal feature set selection; and (4) point cloud classification. Three datasets containing the point cloud data were used in this study to validate the efficiency of the proposed method. The first two datasets cover two areas of the National University of Singapore (NUS) campus while the third dataset is a widely used benchmark point cloud dataset of Oakland, Pennsylvania. The classification parameters were learned from the first dataset consisting of a terrestrial laser-scanning data and a 2D land cover map, and were subsequently used to classify both of the NUS datasets. The evaluation of the classification results showed overall accuracies of 94.07% and 91.13%, respectively, indicating that the transition of the knowledge learned from one dataset to another was satisfactory. The classification of the Oakland dataset achieved an overall accuracy of 97.08%, which further verified the transferability of the proposed approach. An experiment of the point-based classification was also conducted on the first dataset and the result was compared to that of the segment-based classification. The evaluation revealed that the overall accuracy of the segment-based classification is indeed higher than that of the point-based classification, demonstrating the advantage of the segment-based approaches.
Highlights
Constructing semantic three-dimensional (3D) models of the urban environment is an important enabler for knowledge sharing, decision-making, and complex problem solving with applications in virtual tourism, navigation, and urban planning
The Correlation-based Feature Selection (CFS) method and best-first search (BFS) strategy were combined to select the optimal feature set, which considered the relevance between the features
The results suggested that (1) the normal vector plays an important role in point classification, especially its value at z direction; (2) despite the fact that some of the spectral features (F16, F18, and F19) have a high contribution, because of the correlation with other spectral features, they should be avoided; (3) the geometrical features do not have very high gain ratio scores, they are still selected into the optimal feature set because of the low correlations with other two types of features
Summary
Constructing semantic three-dimensional (3D) models of the urban environment is an important enabler for knowledge sharing, decision-making, and complex problem solving with applications in virtual tourism, navigation, and urban planning. Recent works in this direction have increasingly adopted Light Detection and Ranging (LiDAR) generated point clouds as the source data. Existing research into classifying point clouds has produced rich literature the approaches to handling airborne laser-scanning (ALS) data [1,2,3] Adopting these approaches to mobile laser-scanning (MLS) or terrestrial laser-scanning (TLS) data is, not ideal. Coupled with a high level of heterogeneity and the complexity of urban environments, classifying the MLS or TLS data efficiently and accurately remains challenging
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