Abstract
Natural vegetation provides various benefits to human society, but also acts as fuel for wildfires. Therefore, mapping fuel types is necessary to prevent wildfires, and hyperspectral imagery has applications in multiple fields, including the mapping of wildfire fuel types. This paper presents an automatic semisupervised machine learning approach for discriminating between wildfire fuel types and a procedure for fuel mapping using hyperspectral imagery (HSI) from PRISMA, a recently launched satellite of the Italian Space Agency. The approach includes sample generation and pseudolabelling using a single spectral signature as input data for each class, unmixing mixed pixels by a fully constrained linear mixing model, and differentiating sparse and mountainous vegetation from typical vegetation using biomass and DEM maps, respectively. Then the procedure of conversion from a classified map to a fuel map according to the JRC Anderson Codes is presented. PRISMA images of the southern part of Sardinia, an island off Italy, were considered to implement this procedure. As a result, the classified map obtained an overall accuracy of 87% upon validation. Furthermore, the stability of the proposed approach was tested by repeating the procedure on another HSI acquired for part of Bulgaria and we obtained an overall stability of around 84%. In terms of repeatability and reproducibility analysis, a degree of confidence greater than 95% was obtained. This study suggests that PRISMA imagery has good potential for wildfire fuel mapping, and the proposed semisupervised learning approach can generate samples for training the machine learning model when there is no single go-to dataset available, whereas this procedure can be implemented to develop a wildfire fuel map for any part of Europe using LUCAS land cover points as input.
Highlights
IntroductionFire is a significant ecological disturbance that threatens ecosystem sustainability worldwide, in Mediterranean regions
Introduction published maps and institutional affilFire is a significant ecological disturbance that threatens ecosystem sustainability worldwide, in Mediterranean regions
An automatic wildfire fuel mapping procedure using machine learning on hyperspectral imagery from the PRISMA satellite has been put forward
Summary
Fire is a significant ecological disturbance that threatens ecosystem sustainability worldwide, in Mediterranean regions. Over the last five decades, researchers have paid much attention to the ecological impacts of fire. Fire behaviour helps determine the impact of fire to a considerable extent. Fire behaviour has different ecological impacts, and helps us to determine the optimal suppression strategy for any given fire [2–5]. Fire intensity and rate of spread are two important aspects of fire behaviour that are affected, among other factors, by the load, type, and continuity of fuel [6]. Fuel types vary; for instance, Pinus halepensis is more flammable [3] due to the highly flammable resins and oils, producing high-intensity fires. Fuel continuity and fuel load relate to the percentage of the surface covered by vegetation—in other words, by potential fuels [6]. The accuracy and effectiveness of any tool for the simulation of fire behaviour or fire risk assessment iations
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