Abstract
Airborne Laser Scanning (ALS) and terrestrial photogrammetry are methods applicable for mapping forested environments. While ground-based techniques provide valuable information about the forest understory, the measured point clouds are normally expressed in a local coordinate system, whose transformation into a georeferenced system requires additional effort. In contrast, ALS point clouds are usually georeferenced, yet the point density near the ground may be poor under dense overstory conditions. In this work, we propose to combine the strengths of the two data sources by co-registering the respective point clouds, thus enriching the georeferenced ALS point cloud with detailed understory information in a fully automatic manner. Due to markedly different sensor characteristics, coregistration methods which expect a high geometric similarity between keypoints are not suitable in this setting. Instead, our method focuses on the object (tree stem) level. We first calculate approximate stem positions in the terrestrial and ALS point clouds and construct, for each stem, a descriptor which quantifies the 2D and vertical distances to other stem centers (at ground height). Then, the similarities between all descriptor pairs from the two point clouds are calculated, and standard graph maximum matching techniques are employed to compute corresponding stem pairs (tiepoints). Finally, the tiepoint subset yielding the optimal rigid transformation between the terrestrial and ALS coordinate systems is determined. We test our method on simulated tree positions and a plot situated in the northern interior of the Coast Range in western Oregon, USA, using ALS data (76 x 121 m<sup>2</sup>) and a photogrammetric point cloud (33 x 35 m<sup>2</sup>) derived from terrestrial photographs taken with a handheld camera. Results on both simulated and real data show that the proposed stem descriptors are discriminative enough to derive good correspondences. Specifically, for the real plot data, 24 corresponding stems were coregistered with an average 2D position deviation of 66 cm.
Highlights
During the last decade, the application of Airborne Laser Scanning (ALS) for mapping forested areas has become widespread (Hyyppaet al., 2012)
We presented a method for coregistering ALS and terrestrial photogrammetric point clouds in forested areas
We showed that incorporating DTM variability into the distance metric can yield improved discriminative capabilities compared to a purely planimetric variation, which leads to enhanced quality of the tree matching
Summary
The application of Airborne Laser Scanning (ALS) for mapping forested areas has become widespread (Hyyppaet al., 2012). An attractive property of ALS point clouds is that they are usually georeferenced due to the integration of a GNSS receiver and an IMU with the laser scanner This simplifies inference about specific geographic locations or target inventory sites. Combined with a cheap video camera-based measurement system, this would make it possible to augment an ALS point cloud with understory information using moderate effort, which boils down to taking terrestrial photographs of the target area. Such capabilities could significantly simplify forest inventory tasks concerning the understory layer
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