Abstract
UAV laser scanning (ULS) has the potential to support forest operations since it provides high-density data with flexible operational conditions. This study examined the use of ULS systems to estimate several tree attributes from an uneven-aged northern hardwood stand. We investigated: (1) the transferability of raster-based and bottom-up point cloud-based individual tree detection (ITD) algorithms to ULS data; and (2) automated approaches to the retrieval of tree-level (i.e., height, crown diameter (CD), DBH) and stand-level (i.e., tree count, basal area (BA), DBH-distribution) forest inventory attributes. These objectives were studied under leaf-on and leaf-off canopy conditions. Results achieved from ULS data were cross-compared with ALS and TLS to better understand the potential and challenges faced by different laser scanning systems and methodological approaches in hardwood forest environments. The best results that characterized individual trees from ULS data were achieved under leaf-off conditions using a point cloud-based bottom-up ITD. The latter outperformed the raster-based ITD, improving the accuracy of tree detection (from 50% to 71%), crown delineation (from R2 = 0.29 to R2 = 0.61), and prediction of tree DBH (from R2 = 0.36 to R2 = 0.67), when compared with values that were estimated from reference TLS data. Major improvements were observed for the detection of trees in the lower canopy layer (from 9% with raster-based ITD to 51% with point cloud-based ITD) and in the intermediate canopy layer (from 24% with raster-based ITD to 59% with point cloud-based ITD). Under leaf-on conditions, LiDAR data from aerial systems include substantial signal occlusion incurred by the upper canopy. Under these conditions, the raster-based ITD was unable to detect low-level canopy trees (from 5% to 15% of trees detected from lower and intermediate canopy layers, respectively), resulting in a tree detection rate of about 40% for both ULS and ALS data. The cylinder-fitting method used to estimate tree DBH under leaf-off conditions did not meet inventory standards when compared to TLS DBH, resulting in RMSE = 7.4 cm, Bias = 3.1 cm, and R2 = 0.75. Yet, it yielded more accurate estimates of the BA (+3.5%) and DBH-distribution of the stand than did allometric models −12.9%), when compared with in situ field measurements. Results suggest that the use of bottom-up ITD on high-density ULS data from leaf-off hardwood forest leads to promising results when estimating trees and stand attributes, which opens up new possibilities for supporting forest inventories and operations.
Highlights
Achieving sustainability in timber supply requires forest managers to evaluate the short- and long-term ecological and economic consequences of their silvicultural treatments based on the actual and predicted forest conditions
The best individual tree detection and delineation (ITD) performance was obtained from the unmanned aerial vehicles (UAVs) laser scanning (ULS)-V-Pcloud dataset that was acquired in leaf-off conditions using the SimpleTree bottom-up ITD (Figure 11D), with a total of 71% Ntreesdet and 71% Ntreespaired (Table 4)
Under certain conditions, the transferability of ITD algorithms that were initially developed for airborne laser scanning (ALS) and terrestrial laser scanning (TLS) data to ULS data
Summary
Achieving sustainability in timber supply requires forest managers to evaluate the short- and long-term ecological and economic consequences of their silvicultural treatments based on the actual and predicted forest conditions. Forest planning processes over decades involve breaking down decision-making into three components: strategic (≈20 years), tactical (≈5 years), and operational (≈1 year) (see [1,2]). Accurate and up-to-date knowledge on the distribution of tree size, species, health, and growth of forest stands are essential for the planning and monitoring of forest operations. Tree-by-tree measurements are typically carried out in situ on forest sample plots and up-scaling approaches are used to assess forest resources over larger areas. The high labor and time costs of these conventional inventory techniques [3] currently lead to either the implementation being avoided all together or to sample size being reduced dramatically, limiting spatial and temporal resolution of field surveys and rendering them inadequate to provide high-resolution stand and tree characterization
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