High Resolution Weather Modeling for Improved Fire Management

Denver, Colorado November 10-November 16

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http://doi.ieeecomputersociety.org/10.1109/SC.2001.10043

ACM/IEEE SC 2001 Conference (SC 2001)

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	ASCII Text	x
	Kevin Roe, Duane Stevens, Carol McCord, "High Resolution Weather Modeling for Improved Fire Management," SC Conference, pp. 27, ACM/IEEE SC 2001 Conference (SC 2001), 2001.

	BibTex	x
	@article{ 10.1109/SC.2001.10043, author = {Kevin Roe and Duane Stevens and Carol McCord}, title = {High Resolution Weather Modeling for Improved Fire Management}, journal ={SC Conference}, volume = {0}, year = {2001}, isbn = {1-58113-293-X}, pages = {27}, doi = {http://doi.ieeecomputersociety.org/10.1109/SC.2001.10043}, publisher = {IEEE Computer Society}, address = {Los Alamitos, CA, USA}, }

	RefWorks Procite/RefMan/Endnote	x
	TY - CONF JO - SC Conference TI - High Resolution Weather Modeling for Improved Fire Management SN - 1-58113-293-X SP EP A1 - Kevin Roe, A1 - Duane Stevens, A1 - Carol McCord, PY - 2001 KW - Numerical Weather Prediction KW - Fire Behavior KW - Parallel Computing VL - 0 JA - SC Conference ER -

Kevin Roe, Maui High Performance Computing Center

Duane Stevens, University of Hawaii at Manoa

Carol McCord, Maui High Performance Computing Center

A critical element to the accurate prediction of fire/weather behaviour is the knowledge of near-surface weather. Weather variables, such as wind, temperature, humidity and precipitation, make direct impacts on the practice of managing prescribed burns and fighting wild fires. State-of-the-art Numerical Weather Prediction (NWP), coupled with the use of high performance computing, now enable significantly improved short-term forecasting of near-surface weather at a 1-3 km grid resolution.

This proof of concept project integrates two complementary model types to aid federal agencies in real-time management of fire. (1) A highly complex, full-physics mesoscale weather prediction model (MM5) which is applied in order to estimate the weather fields up to 72 hours in advance. (2) A diagnostic fire behavior model (FARSITE) takes the near-surface weather fields and computes the expected spread rate of a fire driven by wind, humidity, terrain, and fuels (i.e. vegetation).

Index Terms:

Numerical Weather Prediction, Fire Behavior, Parallel Computing

Citation:

Kevin Roe, Duane Stevens, Carol McCord, "High Resolution Weather Modeling for Improved Fire Management," sc, pp.27, ACM/IEEE SC 2001 Conference (SC 2001), 2001

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