Abstract
Airborne light detection and ranging (lidar) has become a powerful support for acquiring geospatial data in numerous geospatial applications and analyses. However, the process of extracting ground points accurately and effectively from raw point clouds remains a big challenge. This study presents an improved top-hat filter with a sloped brim to enhance the robustness of ground point extraction for complex objects and terrains. The top-hat transformation is executed and the elevation change intensity of the transitions between the obtained top-hats and outer brims is inspected to suppress the omission error caused by protruding terrain features. Finally, the nonground objects of complex structures, such as multilayer buildings, are identified by the brim filter that is extended outward. The performance of the proposed filter in various environments is evaluated using diverse datasets with difficult cases. The comparison of the proposed filter with the commercial software Terrasolid TerraScan and other popular filtering algorithms demonstrates the applicability and effectiveness of this filter. Experimental results show that the proposed filter has great promise in terms of its application in various types of landscapes. Abrupt terrain features with dramatic elevation changes are well preserved, and diverse objects with complicated shapes are effectively removed. This filter has minimal omission and commission error oscillation for different test areas and thus demonstrates a stable and reliable performance in diverse landscapes. In addition, the proposed algorithm has high computational efficiency because of its simple and efficient data structure and implementation.
Highlights
Airborne light detection and ranging, called airborne laser scanning, has become a powerful support for spatial data acquisition over the past decades
The present study proposes an improved top-hat filter with a sloped brim for obtaining ground points from raw lidar point clouds
The benchmark data released by the International Society for Photogrammetry and Remote Sensing (ISPRS) Commission III/WG3 were used in a comprehensive test to evaluate the proposed filter
Summary
Airborne light detection and ranging (lidar), called airborne laser scanning, has become a powerful support for spatial data acquisition over the past decades. Lidar is capable of rapidly gathering geospatial data of the ground surface by emitting and receiving laser pulses, and its measurements are not influenced by illumination conditions. The use of the lidar system is becoming increasingly popular, the effective processing of raw data remains a big challenge [7,8]. Raw lidar data mainly consist of huge point clouds without classification information. These point clouds may contain diverse objects, such as vegetation, buildings, vehicles, and electrical wires. The crucial step in DTM generation is to eliminate nonground points from the obtained point cloud; this process is referred to as filtering [9,10]
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