Abstract
Filtering is one of the core post-processing steps for airborne LiDAR point cloud. In recent years, the morphology-based filtering algorithms have proven to be a powerful and efficient tool for filtering airborne LiDAR point cloud. However, most traditional morphology-based algorithms have difficulties in preserving abrupt terrain features, especially when using larger filtering windows. In order to suppress the omission error caused by protruding terrain features, this paper proposes an improved morphological algorithm based on multi-level kriging interpolation. This algorithm is essentially a combination of progressive morphological filtering algorithm and multi-level interpolation filtering algorithm. The morphological opening operation is performed with filtering window gradually downsizing, while kriging interpolation is conducted at different levels according to the different filtering windows. This process is iterative in a top to down fashion until the filtering window is no longer greater than the preset minimum filtering window. Fifteen samples provided by the ISPRS commission were chosen to test the performance of the proposed algorithm. Experimental results show that the proposed method can achieve promising results not only in flat urban areas but also in rural areas. Comparing with other eight classical filtering methods, the proposed method obtained the lowest omission error, and preserved protruding terrain features better.
Highlights
Airborne light detection and ranging (LiDAR) technology has been developing very rapidly in recent years
To enhance the applicability of morphology-based filtering algorithm in complicated terrain environments and suppress the omission error caused by protruding ground features, this paper proposes an improved morphological algorithm based on multi-level kriging interpolation
This can be explained by the nature of the morphological filtering
Summary
Airborne light detection and ranging (LiDAR) technology has been developing very rapidly in recent years Since it can obtain a high density point cloud of three-dimensional (3D) information, and does not suffer the effect of outside light conditions, this technology has been widely used in various fields, such as digital terrain model (DTM) generation [1,2,3], 3D city model construction [4,5], road extraction [6,7] and many others. Several filtering algorithms have been proposed and applied successfully to airborne LiDAR point cloud.
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