Abstract
Fuel type is one of the key factors for analyzing the potential of fire ignition and propagation in agricultural and forest environments. The increase of three-dimensional datasets provided by active sensors, such as LiDAR (Light Detection and Ranging), has improved the classification of fuel types through empirical modelling. Empirical methods are site and sensor specific while Radiative Transfer Models (RTM) approaches provide broader universality. The aim of this work is to analyze the suitability of Discrete Anisotropic Radiative Transfer (DART) model to replicate low density small-footprint Airborne Laser Scanning (ALS) measurements and subsequent fuel type classification. Field data measured in 104 plots are used as ground truth to simulate LiDAR response based on the sensor and flight characteristics of low-density ALS data captured by the Spanish National Plan for Aerial Orthophotography (PNOA) in two different dates (2011 and 2016). The accuracy assessment of the DART simulations is performed using Spearman rank correlation coefficients between the simulated metrics and the ALS-PNOA ones. The results show that 32% of the computed metrics overpassed a correlation value of 0.80 between simulated and ALS-PNOA metrics in 2011 and 28% in 2016. The highest correlations were related to high height percentiles, canopy variability metrics as for example standard deviation and Rumple diversity index, reaching correlation values over 0.94. Two metric selection approaches and Support Vector Machine classification method with variants were compared to classify fuel types. The best-fitted classification model, trained with the DART simulated sample and validated with ALS-PNOA data, was obtained using Support Vector Machine method with radial kernel. The overall accuracy of the classification after validation was 88% and 91% for the 2011 and 2016 years, respectively. The use of DART demonstrates its value for simulating generalizable 3D data for fuel type classification providing relevant information for forest managers in fire prevention and extinction.
Highlights
IntroductionFuel type mapping is crucial for forest management and fire risk assessment as the spatial distribution of fuel affects wildfire ignition and propagation
Canopy height metrics (CHM) related with lower heights, as for example low percentiles or minimum height, present lower correlation than CHM high height metrics for both 2011 and 2016 Airborne Laser Scanning (ALS)-Plan for Aerial Orthophotography (PNOA) captures
Our objective was to analyze the accuracy of the Discrete Anisotropic Radiative Transfer (DART) model to replicate the low density small-footprint ALS data captured in the PNOA project and to assess the ability of simulations for model training to classify the fuel types of the study are, in absence of field data, the leaf area index (LAI) value to be assigned to the turbid medium was estimated applying the Biophysical Processor tool integrated in the SNAP software to two Sentinel
Summary
Fuel type mapping is crucial for forest management and fire risk assessment as the spatial distribution of fuel affects wildfire ignition and propagation. Forest fires have had a relevant impact in Mediterranean landscapes, in the last decades, the recurrence, magnitude and severity of wildfires have increased [2]. Fuel type mapping has been accomplished by several authors using remote sensed data [4,5], mostly based on multispectral mediumresolution sensors [5,6,7,8] and using hyperspectral images captured by sensors on board of aircrafts [9,10], airborne and satellite LiDAR (Light Detection and Ranging) data [11,12,13]
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