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Estimating Stand and Fire-Related Surface and Canopy Fuel Variables in Pine Stands Using Low-Density Airborne and Single-Scan Terrestrial Laser Scanning Data
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Orientador(es)
Resumo(s)
In this study, we used data from a thinning trial conducted on 34 different sites and
102 sample plots established in pure and even-aged Pinus radiata and Pinus pinaster stands, to test the
potential use of low-density airborne laser scanning (ALS) metrics and terrestrial laser scanning (TLS)
metrics to provide accurate estimates of variables related to surface and canopy fires. An exhaustive
field inventory was carried out in each plot to estimate the main stand variables and the main
variables related to fire hazard: surface fuel loads by layers, fuel strata gap, surface fuel height, stand
mean height, canopy base height, canopy fuel load and canopy bulk density. In addition, the point
clouds from low-density ALS and single-scan TLS of each sample plot were used to calculate metrics
related to the vertical and horizontal distribution of forest fuels. The comparative performance of the
following three non-parametric machine learning techniques used to estimate the main stand- and
fire-related variables from those metrics was evaluated: (i) multivariate adaptive regression splines
(MARS), (ii) support vector machine (SVM), and (iii) random forest (RF). The selection of the best
modeling approach was based on a comparison of the root mean square error (RMSE), obtained
by optimizing the parameters of each technique and performing cross-validation. Overall, the best
results were obtained with the MARS techniques for data from both sensors. The TLS data provided
the best results for variables associated with the internal characteristics of canopy structure and
understory fuel but were less reliable for estimating variables associated with the upper canopy,
due to occlusion by mid-canopy foliage. The combination of ALS and TLS metrics improved the
accuracy of estimates for all variables analyzed, except the height and the biomass of the understory
shrubs. The variability demonstrated by the combined use of both types of metrics ranged from
43.11% for the biomass of duff litter layers to 94.25% for dominant height. The results suggest that the
combination of machine learning techniques and metrics derived from low-density ALS data, drawn
from a single-scan TLS or a combination of both metrics, may represent a promising alternative
to traditional field inventories for obtaining valuable information about surface and canopy fuel
variables at large scales
Descrição
Palavras-chave
forest fuel modeling ALS/TLS canopy fuel characterization understory fuel characterization
Contexto Educativo
Citação
Alonso-Rego, C.; Arellano-Pérez, S.; Guerra-Hernández, J.; Molina-Valero, J.A.; Martínez-Calvo, A.; Pérez-Cruzado, C.; Castedo-Dorado, F.; González-Ferreiro, E.; Álvarez-González, J.G.; Ruiz-González, A.D. Estimating Stand and Fire-Related Surface and Canopy Fuel Variables in Pine Stands Using Low-Density Airborne and Single-Scan Terrestrial Laser Scanning Data. Remote Sens. 2021, 13, 5170
Editora
MDPI