Calibration of FARSITE simulator in northern Iranian forests

Jahdi, Roghayeh; Salis, Michele; Darvishsefat, A A; Mostafavi, Mir Abolfazl; Alcasena, Fermín; Etemad, V; Lozano, Olga M.; Spano, Donatella

doi:10.5194/nhess-15-443-2015

Cited by 18 publications

(4 citation statements)

References 70 publications

(98 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Urban areas with very low fuel load (NB) 0.00 0.00 À1.00 20.6 0.0 0.0 0.0 0.0 0.0 J the number of fire events analysed in this study still does not fully represent the complexity of fire conditions and vegetation in the Mediterranean basin context, the broad gradient of the events considered highlights the potential for applying spatially explicit fire modelling in Mediterranean environments. Overall, modelling fire spread and behaviour is a complex task owing to a set of factors, including spatial and temporal heterogeneity in weather and fuels and fire suppression effects on fire propagation (Mutlu et al 2008;Alexander and Cruz 2013;Taylor et al 2013;Jahdi et al 2015). Several previous studies validated fire spread simulators by comparing simulated fire propagation against historical fire data (Perry 1998;Fujioka 2002;Arca et al 2007b;Filippi et al 2014;Milne et al 2014;Jahdi et al 2015).…”

Section: Discussionmentioning

confidence: 99%

“…In recent years, much effort has been dedicated to developing an alternative to standard fuel models (Deeming et al 1972;Anderson 1982;Scott and Burgan 2005). In fact, although FARSITE provides reliable results in fire behaviour modelling over landscapes containing fuel types consistent with the original standard fuel models of Anderson (1982) and Scott and Burgan (2005) designed for US fuel types, extrapolation to other ecosystems is not always an easy and reliable task and can result in biased outputs (Pastor et al 2003;Arca et al 2007b;Arroyo et al 2008;Jahdi et al 2015Jahdi et al , 2016. Several customised fuel models have been recently developed to better represent the fuel characteristics of the Mediterranean vegetation in Greece (Dimitrakopoulos 2002), the medium-height (maquis) and low and degraded shrublands (garrigue) communities in Italy (Arca et al 2007b(Arca et al , 2009, the shrub vegetation in Turkey (Bilgili and Saglam 2003;Saglam et al 2008), Pinus pinaster stands in Portugal (Fernandes 2001;Cruz and Fernandes 2008), and the grass, shrub and canopy fuel types in Spain (De Luis et al 2004;Rodríguez y Silva and Molina-Martínez 2012;Vega-Garcia et al 2014).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Predicting wildfire spread and behaviour in Mediterranean landscapes

Salis

Arca

Alcasena

et al. 2016

Int. J. Wildland Fire

View full text Add to dashboard Cite

The use of spatially explicit fire spread models to assess fire propagation and behaviour has several applications for fire management and research. We used the FARSITE simulator to predict the spread of a set of wildfires that occurred along an east–west gradient of the Euro-Mediterranean countries. The main purpose of this work was to evaluate the overall accuracy of the simulator and to quantify the effects of standard vs custom fuel models on fire simulation performance. We also analysed the effects of different fuel models and slope classes on the accuracy of FARSITE predictions. To run the simulations, several input layers describing each study area were acquired, and their effect on simulation outputs was analysed. Site-specific fuel models and canopy inputs were derived either from existing vegetation information and field sampling or through remote-sensing data. The custom fuel models produced an increase in simulation accuracy, and results were nearly unequivocal for all the case studies examined. We suggest that spatially explicit fire spread simulators and custom fuel models specifically developed for the heterogeneous landscapes of Mediterranean ecosystems can help improve fire hazard mapping and optimise fuel management practices across the Euro-Mediterranean region.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Predicting wildfire spread and behaviour in Mediterranean landscapes

Salis

Arca

Alcasena

et al. 2016

Int. J. Wildland Fire

View full text Add to dashboard Cite

show abstract

“…Generalized maps of fuel beds, such as from LAND-FIRE, may produce simulated fire-spread that differs considerably from observed patterns, as we demonstrated for the Soda Wildfire, and use of LANDFIRE FBFM maps is best preceded by assessment and/or validation prior to application. The model-accuracy assessment and alternative method for FBFM selection we describe are useful advances beyond the field-vegetation map-based accuracy assessments of MTT and FARSITE developed for other semiarid settings, e.g., shrublands of the Mediterranean or Iranian grasslands (Arca et al 2007;Jahdi et al 2015Jahdi et al , 2016Salis et al 2016Salis et al , 2021. The analysis conducted here may not be feasible for most site-specific applications.…”

Section: Discussionmentioning

confidence: 99%

Modeling of fire spread in sagebrush steppe using FARSITE: an approach to improving input data and simulation accuracy

Price

Germino

2022

fire ecol

View full text Add to dashboard Cite

Background Model simulations of wildfire spread and assessments of their accuracy are needed for understanding and managing altered fire regimes in semiarid regions. The accuracy of wildfire spread simulations can be evaluated from post hoc comparisons of simulated and actual wildfire perimeters, but this requires information on pre-fire vegetation fuels that is typically not available. We assessed the accuracy of the Fire-Area Simulator (FARSITE) model parameterized with maps of fire behavior fuel models (FBFMs) obtained from the widely used LANDFIRE, as well as alternative means which utilized the classification of Rangeland Analysis Platform (RAP) satellite-derived vegetation cover maps to create FBFM maps. We focused on the 2015 Soda wildfire, which burned 113,000 ha of sagebrush steppe in the western USA, and then assessed the transferability of our RAP-to-FBFM selection process, which produced the most accurate reconstruction of the Soda wildfire, on the nearby 2016 Cherry Road wildfire. Results Parameterizing FARSITE with maps of FBFMs from LANDFIRE resulted in low levels of agreement between simulated and observed area burned, with maximum Sorensen’s coefficient (SC) and Cohen’s kappa (K) values of 0.38 and 0.36, respectively. In contrast, maps of FBFMs derived from unsupervised classification of RAP vegetation cover maps led to much greater simulated-to-observed burned area agreement (SC = 0.70, K = 0.68). The FBFM map that generated the greatest simulated-to-observed burned area agreement for the Soda wildfire was then used to crosswalk FBFMs to another nearby wildfire (2016 Cherry Road), and this FBFM selection led to high FARSITE simulated-to-observed burned area agreement (SC = 0.80, K = 0.79). Conclusions Using RAP to inform pre-fire FBFM selection increased the accuracy of FARSITE simulations compared to parameterization with the standard LANDFIRE FBFM maps, in sagebrush steppe. Additionally, the crosswalk method appeared to have regional generalizability. Flanking and backfires were the primary source of disagreements between simulated and observed fire spread in FARSITE, which are sources of error that may require modeling of lateral heterogeneity in fuels and fire processes at finer scales than used here.

show abstract

“…Although the fire regime consisted of the summer, fall, and a mixture of the two in the study area, wildfires in recent years have burned well outside of the typical fire season. According to Jahdi [60] et al the three-month wildfire season in northern Iran has become longer and now lasts six months. Other factors contributing to longer wildfire seasons include extended drought, dieback of Persian oak trees (Quercus castaneifolia C. A.…”

Section: Wildfire Regimementioning

confidence: 99%

Surface Wildfire Regime and Simulation-Based Wildfire Exposure in the Golestan National Park, NE Iran

Jahdi

Bacciu

Salis

et al. 2023

Fire

Self Cite

View full text Add to dashboard Cite

This research analyzes the spatiotemporal patterns of wildfire regime attributes (e.g., seasonality, size, frequency, and burn rate) across the Golestan National Park (GNP), northeast Iran over the last two decades. We used a variety of data, including existing vegetation data, current vegetation survey, and historical wildfire data, and then data were processed through ArcMap. We also predicted fire exposure profiles (burn probability (BP), conditional flame length (CFL (m)), and fire size (FS (ha)) by the application of the minimum travel time (MTT) fire spread algorithm. The kernel density estimation (KDE) method was used to estimate wildfire likelihood, based on recent wildfires (2000–2020) that occurred in the GNP. Finally, we developed a logistic regression model to investigate how independent variables such as weather, fuel, and topographic data influence wildfires in the park. Wildfires in the landscape have not been constant in either space or time. Their extent, seasonality, frequency, and other wildfire regime characters varied considerably across the landscape. Our results highlighted that shrublands in the southern part of the park showed, in general, the highest values in terms of the wildfire regime attributes. Large fires (10–100 ha, 51%) and very large fires (>100 ha, 24%), fire intervals greater than 10 years (90%), and high burn rates (>1% y−1, 35%) are all characteristics that contribute to high wildfire activity in shrublands. Similarly, areas predicted to have high wildfire exposure levels (average BP = 0.004; average CFL = 1.60 m; average FS = 840 ha) are found in the fuel models of high-load grass and medium-load shrub. Finally, the regression model results revealed that weather and fuel were the most influential parameters (R2 ≥ 0.2), while topography had comparatively less influence in the study area. In light of these results, we suggest proactively incorporating this information into fire and fuel management which can help develop a fire prevention plan, predict fire ignition probability and frequency, and finally address altered fire regimes threatening the park.

show abstract

Calibration of FARSITE simulator in northern Iranian forests

Cited by 18 publications

References 70 publications

Predicting wildfire spread and behaviour in Mediterranean landscapes

Predicting wildfire spread and behaviour in Mediterranean landscapes

Modeling of fire spread in sagebrush steppe using FARSITE: an approach to improving input data and simulation accuracy

Surface Wildfire Regime and Simulation-Based Wildfire Exposure in the Golestan National Park, NE Iran

Contact Info

Product

Resources

About