Abstract
Abstract. Over the past years, the algorithms for dense image matching (DIM) to obtain point clouds from aerial images improved significantly. Consequently, DIM point clouds are now a good alternative to the established Airborne Laser Scanning (ALS) point clouds for remote sensing applications. In order to derive high-level applications such as digital terrain models or city models, each point within a point cloud must be assigned a class label. Usually, ALS and DIM are labelled with different classifiers due to their varying characteristics. In this work, we explore both point cloud types in a fully convolutional encoder-decoder network, which learns to classify ALS as well as DIM point clouds. As input, we project the point clouds onto a 2D image raster plane and calculate the minimal, average and maximal height values for each raster cell. The network then differentiates between the classes ground, non-ground, building and no data. We test our network in six training setups using only one point cloud type, both point clouds as well as several transfer-learning approaches. We quantitatively and qualitatively compare all results and discuss the advantages and disadvantages of all setups. The best network achieves an overall accuracy of 96 % in an ALS and 83 % in a DIM test set.
Highlights
Semantic classification is an essential step in processing point cloud data
In contrast to small indoor scenes or point clouds measured by a terrestrial laser scanner, the point clouds used for remote sensing applications have a much larger extent of several kilometres compared to dozens of meters
Rather than searching for the most optimized solution, we focus on comparing these different setups on an Airborne Laser Scanning (ALS) and Dense Image Matching (DIM) test set
Summary
A classified point cloud is the starting point for many high-level remote sensing products such as digital terrain models (DTMs) or city models. In contrast to small indoor scenes or point clouds measured by a terrestrial laser scanner, the point clouds used for remote sensing applications have a much larger extent of several kilometres compared to dozens of meters. There are two different types of point cloud data available. ALS point clouds have a quite sparse overall point density of only several points/m2. Dense Image Matching (DIM) point clouds are the second point cloud type. A semi-global matching algorithm matches aerial image pixels to create DIM point clouds. Every pixel in those aerial images creates a point in the point cloud resulting in a high point density
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