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Wildland fire risk maps using S<sup>2</sup>F<sup>2</sup>M<sup>*</sup>
Keywords:
Wildland fire, Propagation danger, Risk Maps, High-performance computingAbstract
Wildland fires are a critical natural hazard in many regions of the World. Every year, millions of hectares are burned in Tropical, Boreal and Mediterranean forest, which causes a wide variety of effects, from atmospheric emissions, to soil erosion, biodiversity loss and drainage alterations. Reduction of those negative effects of fire requires to improve current fire risk assessment methods. Wildland firerisk assessment is a very significant issue. This risk assessment is usually based on ignition probability due to meteorological or human factors, but it does not usually consider propagation danger when a wildland fire has started. To evaluate propagation danger, it is necessary to apply some propagation model and simulate the behaviour of the fireline. However, this propagation danger must be evaluated considering many different possible scenarios. Therefore, the amount of simulations that must be carried out is enormous and it is necessary to apply high-performance computing techniques to make the methodology feasible. In this paper, a method for creating propagation danger maps based on factorial experimentation is described. The methodology was applied at a southern Europe scale during the 2004 summer season.
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References
[1] Andrews P. L. “BEHAVE: Fire Behavior prediction and modeling systems - Burn subsystem, part 1”. General Technical Report INT-194. Odgen, UT, US Department of Agriculture, Forest Service, Intermountain Research Station; 1986.
[2] Andrews, Patricia L.; Bevins, Collin D.; Seli, Robert C. “BehavePlus fire modeling system, version 2.0: User's Guide”. Gen. Tech. Rep. RMRSGTR-106WWW. Ogden, UT: Department of Agriculture, Forest Service, Rocky Mountain Research Station. 2003.
[3] G. Bianchini, A. Cortés, T. Margalef and E. Luque. “S2 F2 M - Statistical System for Forest Fire Management”. LNCS 3514, pp. 427-434. 2005.
[4] Collins D. Bevins, “FireLib User Manual & Technical Reference”, 1996. http://www.fire.org.
[5] Finney, Mark A.. “FARSITE: Fire Area Simulator-model development and evaluation”. Res. Pap. RMRS-RP-4, Ogden, UT: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station. 47 p. 1998.
[6] ADAI Products: FIRESTATION http://www.adai.pt/products/firestation/
[7] ADAI - CEIF (Center of Forest Fire Studies) http://www.adai.pt/ceif/Gestosa/
[8] Douglas C. Montgomery, George C. Runger, “Applied statistics and probability for engineer”, John Wiley & Sons, New York. D.L. 1994 ISBN 0471010219
[9] MPI: The Message Passing Interface Standard http://www-unix.mcs.anl.gov/mpi/
[10] Rothermel, R. C., “A mathematical model for predicting fire spread in wildland fuels”, USDA FS, Ogden TU, Res. Pap. INT-115, 1972.
[11] Project Spread, Forest Fire Spread Prevention and Mitigation http://www.adai.pt/spread/
[2] Andrews, Patricia L.; Bevins, Collin D.; Seli, Robert C. “BehavePlus fire modeling system, version 2.0: User's Guide”. Gen. Tech. Rep. RMRSGTR-106WWW. Ogden, UT: Department of Agriculture, Forest Service, Rocky Mountain Research Station. 2003.
[3] G. Bianchini, A. Cortés, T. Margalef and E. Luque. “S2 F2 M - Statistical System for Forest Fire Management”. LNCS 3514, pp. 427-434. 2005.
[4] Collins D. Bevins, “FireLib User Manual & Technical Reference”, 1996. http://www.fire.org.
[5] Finney, Mark A.. “FARSITE: Fire Area Simulator-model development and evaluation”. Res. Pap. RMRS-RP-4, Ogden, UT: U.S. Department of Agriculture, Forest Service, Rocky Mountain Research Station. 47 p. 1998.
[6] ADAI Products: FIRESTATION http://www.adai.pt/products/firestation/
[7] ADAI - CEIF (Center of Forest Fire Studies) http://www.adai.pt/ceif/Gestosa/
[8] Douglas C. Montgomery, George C. Runger, “Applied statistics and probability for engineer”, John Wiley & Sons, New York. D.L. 1994 ISBN 0471010219
[9] MPI: The Message Passing Interface Standard http://www-unix.mcs.anl.gov/mpi/
[10] Rothermel, R. C., “A mathematical model for predicting fire spread in wildland fuels”, USDA FS, Ogden TU, Res. Pap. INT-115, 1972.
[11] Project Spread, Forest Fire Spread Prevention and Mitigation http://www.adai.pt/spread/
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Published
2005-12-01
How to Cite
BIanchini, G., Cortés, A., Margalef, T., Luque Fadón, E., Chuvieco, E., & Camia, A. (2005). Wildland fire risk maps using S<sup>2</sup>F<sup>2</sup>M<sup>*</sup>. Journal of Computer Science and Technology, 5(04), p. 244–249. Retrieved from https://journal.info.unlp.edu.ar/JCST/article/view/843
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