Abstract
3D spatial information from unmanned aerial vehicles (UAV) images is usually provided in the form of 3D point clouds. For various UAV applications, it is important to generate dense 3D point clouds automatically from over the entire extent of UAV images. In this paper, we aim to apply image matching for generation of local point clouds over a pair or group of images and global optimization to combine local point clouds over the whole region of interest. We tried to apply two types of image matching, an object space-based matching technique and an image space-based matching technique, and to compare the performance of the two techniques. The object space-based matching used here sets a list of candidate height values for a fixed horizontal position in the object space. For each height, its corresponding image point is calculated and similarity is measured by grey-level correlation. The image space-based matching used here is a modified relaxation matching. We devised a global optimization scheme for finding optimal pairs (or groups) to apply image matching, defining local match region in image- or object- space, and merging local point clouds into a global one. For optimal pair selection, tiepoints among images were extracted and stereo coverage network was defined by forming a maximum spanning tree using the tiepoints. From experiments, we confirmed that through image matching and global optimization, 3D point clouds were generated successfully. However, results also revealed some limitations. In case of image-based matching results, we observed some blanks in 3D point clouds. In case of object space-based matching results, we observed more blunders than image-based matching ones and noisy local height variations. We suspect these might be due to inaccurate orientation parameters. The work in this paper is still ongoing. We will further test our approach with more precise orientation parameters.
Highlights
Operational objective of Unmanned Aerial Vehicles (UAVs) was image accusation, such as monitoring
The platform and sensor performance has been improved and the objective includes the extraction of additional information from UAV image
There were many point cloud extraction techniques using satellite and aerial images. Most of these showed high performance for calculating 3D geospatial information based on geometric information with accurate sensor model. (Haala and Rothermel 2012; Jeong and Kim, 2014 )
Summary
Operational objective of Unmanned Aerial Vehicles (UAVs) was image accusation, such as monitoring. The platform and sensor performance has been improved and the objective includes the extraction of additional information from UAV image. There were many point cloud extraction techniques using satellite and aerial images. Most of these showed high performance for calculating 3D geospatial information based on geometric information with accurate sensor model. UAV images do not have good quality as compared to aerial images. In an export to overcome this problem, feature point base matching technique has been used for UAV image. This matching technique does not consider the geometric information calculated from exterior orientation. Feature point based matching is processed only using characteristics of image, such as pixel position and brightness
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