Abstract
Airborne Light Detection and Ranging (LiDAR) is a popular active remote sensing technology that has been developing very rapidly in recent years. To solve the problems of low filtering accuracy of airborne LiDAR point clouds in complex terrain environments and avoiding too much human intervention, this paper proposes a point cloud filtering method based on active learning. In the proposed method, the initial training samples are acquired and marked automatically by multi-scale morphological operations. In so doing, no training samples are selected and labeled manually, i.e., the training samples are added gradually according to the oracle used in active learning. In this paper, the oracle is set to a sigmoid function of residuals from the points to the fitted surface. Subsequently, the training model is revised progressively using the updated training samples. Finally, the classification results are further optimized by a slope-based method. Three datasets with different filtering challenges provided by the International Society for Photogrammetry and Remote Sensing (ISPRS) were used to test the proposed method. Comparing with the other ten famous filtering methods, the proposed method can achieve the smallest average total error (5.51%). Thus, it can be concluded that the proposed method performs very well toward different terrain environments.
Highlights
As an active remote sensing technology, airborne Light Detection and Ranging (LiDAR) has rapidly developed in recent years
Airborne LiDAR has been widely used for digital terrain model (DTM) generation [3], [4]
DTM generation is a crucial step in LiDAR point cloud data processing applications, such as road extraction [5], [6], The associate editor coordinating the review of this manuscript and approving it for publication was Wei Liu
Summary
As an active remote sensing technology, airborne LiDAR has rapidly developed in recent years. Compared with traditional passive remote sensing methods, such as photogrammetric mapping, airborne LiDAR can acquire accurate three-dimensional point clouds data directly to characterize the topographic profile of the earth surface [1]. Airborne LiDAR has been widely used for digital terrain model (DTM) generation [3], [4]. Lots of researchers have been involved in developing algorithms for DTM extraction from airborne LiDAR point clouds [3], [11], [12]. This process is commonly known as filtering. According to their filtering principles, these methods can be categorized into seven classes, namely slope-based, morphology-based, surface-based, triangularirregular-network-based (TIN), segmentation-based, statisticbased and energy-optimization-based
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