Abstract
Fire regimes are strongly related to weather conditions that directly and indirectly influence fire ignition and propagation. Identifying the most important meteorological fire drivers is thus fundamental for daily fire risk forecasting. In this context, several fire weather indices have been developed focussing mainly on fire-related local weather conditions and fuel characteristics. The specificity of the conditions for which fire danger indices are developed makes its direct transfer and applicability problematic in different areas or with other fuel types. In this paper we used the low-to-intermediate fire-prone region of Canton Ticino as a case study to develop a new daily fire danger index by implementing a niche modelling approach (Maxent). In order to identify the most suitable weather conditions for fires, different combinations of input variables were tested (meteorological variables, existing fire danger indices or a combination of both). Our findings demonstrate that such combinations of input variables increase the predictive power of the resulting index and surprisingly even using meteorological variables only allows similar or better performances than using the complex Canadian Fire Weather Index (FWI). Furthermore, the niche modelling approach based on Maxent resulted in slightly improved model performance and in a reduced number of selected variables with respect to the classical logistic approach. Factors influencing final model robustness were the number of fire events considered and the specificity of the meteorological conditions leading to fire ignition.
Highlights
A fire regime is the result of complex interactions between weather conditions, fuel, topography and ignition sources [1], [2], [3]
When relating the results to the theoretical Maximum Area Under the Curve (AUC).bg for each fire regime, the sa displays the lowest scores for every group of explanatory variables considered
The modelling approach based on Maxent resulted in slightly improved model performance and a reduction in the number of variables selected in the best models with respect to the classical logistic approach
Summary
A fire regime is the result of complex interactions between weather conditions, fuel, topography and ignition sources [1], [2], [3]. As term of reference we used the logistic model It is a particular case of the generalized linear model (GLM—[41]), widely used in species distribution modelling because of its strong statistical foundation and ability to realistically describe ecological relationships [42], [30]. The link function is the “logit” function of the binary response data, and the appropriate GLM is a logistic model. Each day of the study period and of the corresponding fire regime represents a binary response variable for which we considered the days with at least one fire ignition (fire days) as presence and the days without fire ignitions as absence
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