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RESEARCH ARTICLE
Contents Vol 16(5)

Evaluation of FARSITE simulator in Mediterranean maquis

Bachisio Arca A C D , P. Duce A , M. Laconi B , G. Pellizzaro A , M. Salis B and D. Spano B
+ Author Affiliations
- Author Affiliations

A CNR-IBIMET, Institute of Biometeorology, Sassari, Italy.

B DESA, Department of Economics and Woody Plant Ecosystems, University of Sassari, Italy.

C Present address: CNR-IBIMET, via Funtana di lu Colbu 4/a, I-07100 Sassari, Italy.

D Corresponding author. Email: b.arca@ibimet.cnr.it

International Journal of Wildland Fire 16(5) 563-572 https://doi.org/10.1071/WF06070
Submitted: 16 May 2006  Accepted: 17 February 2007   Published: 26 October 2007

Abstract

In the last two decades, several models were developed to provide temporal and spatial variations of fire spread and behaviour. The most common models (i.e. BEHAVE and FARSITE) are based on Rothermel's original fire spread equation and describe fire spread and behaviour taking into account the influences of fuels, terrain and weather conditions. The use of FARSITE on areas different from those where the simulator was originally developed requires a local calibration to produce reliable results. This is particularly true for Mediterranean ecosystems, where plant communities are characterised by high specific and structural heterogeneity and complexity. To perform FARSITE calibration, an appropriate fuel model or the development of a specific custom fuel model is needed. In this study, FARSITE was employed to simulate three fire events in Mediterranean areas using different fuel models and meteorological input data, and the accuracy of results was analysed. A custom fuel model designed and developed for shrubland vegetation (maquis) provided realistic values of rate of spread, when compared with estimated values obtained using standard fuel models. Our results confirm that the use of both wind field data and appropriate custom fuel models are crucial to obtain reasonable simulations of wildfire events occurring on Mediterranean vegetation during the drought season.

Additional keywords: behaviour, fire modelling, fuel models, Mediterranean forest areas, shrubland vegetation.


Acknowledgements

The authors would like to thank the personnel of the Sardinian Agrometeorological Service for providing weather data, and the Sardinian Forestry Corps (Cooperative agreement 27.12.2005) for providing GIS data and most of the information about the fire events. This work was partially funded by the Italian Ministry of Education, University and Scientific Research (MIUR), Grant N. 165-DM 1105/2002.


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