Abstract
In forests with dense mixed canopies, laser scanning is often the only effective technique to acquire forest inventory attributes, rather than structure-from-motion optical methods. This study investigates the potential of laser scanner data collected with a low-cost unmanned aerial vehicle laser scanner (UAV-LS), for individual tree crown (ITC) delineation to derive forest biometric parameters, over two-layered dense mixed forest stands in central Italy. A raster-based local maxima region growing algorithm (itcLiDAR) and a point cloud-based algorithm (li2012) were applied to isolate individual tree crowns, compute height and crown area, estimate the diameter at breast height (DBH) and the above ground biomass (AGB) of individual trees. To maximize the level of detection rate, the ITC algorithm parameters were tuned varying 1350 setting combinations and matching the segmented trees with field measured trees. For each setting, the delineation accuracy was assessed by computing the detection rate, the omission and commission errors over three forest plots. Segmentation using itcLiDAR showed detection rates between 40% and 57%, while ITC delineation was successful at segmenting trees with DBH larger than 10 cm (detection rate ~78%), while failed to detect trees with smaller DBH (detection rate ~37%). The performance of li2012 was quite lower with the higher detection rate equal to 27%. Errors and goodness-of-fit between field-surveyed and flight-derived biometric parameters (AGB and tree height) were species-dependent, with higher error and lower r2 for shorter species that constitute the lowermost layer of the forest. Overall, while the application of UAV-LS to delineate tree crowns and estimate biometric parameters is satisfactory, its accuracy is affected by the presence of a multilayered and multispecies canopy that will require specific approaches and algorithms to better deal with the added complexity.
Highlights
Laser scanning is a well-established and consolidated technology used extensively for environmental monitoring and mapping
This study explored the application of two different algorithms, i.e., itcLiDAR() and li2012, for individual tree crown segmentation in a two-layered dense mixed forest
The raster-based local maxima region growing algorithm itcLiDAR() performed better than the point cloud-based li2012 and the performance of its estimates resulted comparable to those obtained in individual tree crown (ITC) segmentation based on airborne laser scanning (ALS) data
Summary
Laser scanning is a well-established and consolidated technology used extensively for environmental monitoring and mapping. In forest monitoring and inventories, airborne laser scanning (ALS) started to be used since 1990s [1] with focus on tree height measurements (e.g., [2]), individual tree identification (e.g., [3,4,5]), canopy structure assessment (e.g., [6]), forest volume estimation (e.g., [7,8,9]). It is known that digital aerial photography (DAP) major advantage is its scalability in enhanced forest inventories where manned aircrafts are required to cover extensive areas that are out-of-range of UAVs. Given that DAP does not rely on the reflection of laser pulses, survey flights can be higher and faster than ALS ones, covering larger areas and costing one-half to one-third less than ALS flights [21,22]. ALS segmentation tended to under-segment and under-detect trees, while
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