Abstract
Wildland fires are one of the factors causing the deepest disturbances on the natural environment and severely threatening many ecosystems, as well as economic welfare and public health. Having accurate and up-to-date fuel type maps is essential to properly manage wildland fire risk areas. This research aims to assess the viability of combining Geographic Object-Based Image Analysis (GEOBIA) and the fusion of a WorldView-2 (WV2) image and low density Light Detection and Ranging (LiDAR) data in order to produce fuel type maps within an area of complex orography and vegetation distribution located in the island of Tenerife (Spain). Independent GEOBIAs were applied to four datasets to create four fuel type maps according to the Prometheus classification. The following fusion methods were compared: Image Stack (IS), Principal Component Analysis (PCA) and Minimum Noise Fraction (MNF), as well as the WV2 image alone. Accuracy assessment of the maps was conducted by comparison against the fuel types assessed in the field. Besides global agreement, disagreement measures due to allocation and quantity were estimated, both globally and by fuel type. This made it possible to better understand the nature of disagreements linked to each map. The global agreement of the obtained maps varied from 76.23% to 85.43%. Maps obtained through data fusion reached a significantly higher global agreement than the map derived from the WV2 image alone. By integrating LiDAR information with the GEOBIAs, global agreement improvements by over 10% were attained in all cases. No significant differences in global agreement were found among the three classifications performed on WV2 and LiDAR fusion data (IS, PCA, MNF). These study’s findings show the validity of the combined use of GEOBIA, high-spatial resolution multispectral data and low density LiDAR data in order to generate fuel type maps in the Canary Islands.
Highlights
Wildland fires are one of the factors causing the deepest disturbances on the natural environment and severely threatening many ecosystems, as well as economic welfare and public health [1,2,3,4].Having up-to-date and accurate fuel type maps is fundamental to properly manage wildland fire risk areas [5,6]
PFT7 is the fuel type covering a greater surface, taking up a relative surface of over 30% in all cases. This fuel type corresponds to the greenwood and Myrica-Erica evergreen forest bordering agricultural vegetation areas found in the northeastern segment of the study area and to canary pine forests in the central segment
Four independent Geographic Object-Based Image Analysis (GEOBIA) were produced by means of three fused images (IS, Principal Component Analysis (PCA) and Minimum Noise Fraction (MNF)) and one non-fused WV2 image
Summary
Wildland fires are one of the factors causing the deepest disturbances on the natural environment and severely threatening many ecosystems, as well as economic welfare and public health [1,2,3,4]. Having up-to-date and accurate fuel type maps is fundamental to properly manage wildland fire risk areas [5,6]. Fuel types can be any part of the vegetation vulnerable to catching fire in the event of a fire. In order to define such fuels, it is necessary to know the quantity and proportion of living and dead biomass, their distribution by size, branches, leaves, trunks, etc., and their horizontal and vertical spatial distribution [7,8]. The challenge of getting this information for the entirety of the forested area makes it necessary to simplify reality through the use of fuel type classifications.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
