Abstract
Among traditional Light Detection And Ranging (LIDAR) data representations such as raster grid, triangulated irregular network, point clouds and octree, the explicit 3D nature of voxel-based representation makes it a promising alternative. Despite the benefit of voxel-based representation, voxel-based algorithms have rarely been used for building detection. In this paper, a voxel segmentation-based 3D building detection algorithm is developed for separating building and nonbuilding voxels. The proposed algorithm first voxelizes the LIDAR point cloud into a grayscale voxel structure in which the grayscale of the voxel corresponds to the quantized mean intensity of the LIDAR points within the voxel. The voxelized dataset is segmented into multiple 3D-connected regions depending on the connectivity and grayscale similarity among voxels. The 3D-connected regions corresponding to the building roof and facade are detected sequentially according to characteristics such as their area, density, elevation difference and location. The obtained results for the detected buildings are evaluated by the LIDAR data provided by working group III/4 of ISPRS, which demonstrate a high rate of success. Average completeness, correctness, quality, and kappa coefficient indexes values of 90.0%, 96.0%, 88.1% and 88.7%, respectively, are obtained for buildings.
Highlights
The obtained results for the detected buildings are evaluated by the Light Detection And Ranging (LIDAR) data provided by working group III/4 of ISPRS, which demonstrate a high rate of success
Data Availability Statement: Data are available from the Working Group (WG) III/4 of ISPRS from Vaihingen area of Germany, but the data need to be requested
The goal of this paper is to develop a novel voxel segmentation based algorithm to precisely detect buildings from the constructed Grayscale Voxel Structure (GVS) model
Summary
Data Availability Statement: Data are available from the Working Group (WG) III/4 of ISPRS from Vaihingen area of Germany, but the data need to be requested. Other conditions of data usage include that: 1) The data must not be used for other than research purposes. 2) The data must not be distributed to third parties. Any person interested in the data may obtain them via ISPRS WG III/4. 3) Any scientific papers whose results are based on the Vaihingen test data must cite [Cramer, 2010] and must contain the following. Airborne Light Detection And Ranging (LIDAR) data, which can provide dense, accurate, and georeferenced true 3D point clouds and the intensity of the returned signal, appear to be an ideal data source for detecting 3D buildings
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