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RESEARCH ARTICLE
Contents Vol 18(8)

An approach to operational forest fire growth predictions for Canada

K. R. Anderson A C , P. Englefield A , J. M. Little A and Gerhard Reuter B
+ Author Affiliations
- Author Affiliations

A Natural Resources Canada, Canadian Forest Service, 5320-122 Street, Edmonton, AB, T6H 3S5, Canada.

B University of Alberta, Department of Earth and Atmospheric Sciences, 1-26 Earth Sciences Building, University of Alberta, Edmonton, AB, T6G 2E3, Canada.

C Corresponding author. Email: kanderso@nrcan.gc.ca.

International Journal of Wildland Fire 18(8) 893-905 https://doi.org/10.1071/WF08046
Submitted: 1 April 2008  Accepted: 21 April 2009   Published: 9 December 2009

Abstract

This paper presents an operational approach to predicting fire growth for wildland fires in Canada. The approach addresses data assimilation to provide predictions in a timely and efficient manner. Fuels and elevation grids, forecast weather, and active fire locations are entered into a fire-growth model; then predicted fire perimeters are mapped and presented on the web. The Moderate Resolution Imaging Spectroradiometer (MODIS) and the National Oceanic and Atmospheric Administration Advanced Very High Resolution Radiometer (NOAA/AVHRR) satellite-based detection systems are used to detect current wildland fires (referred to as hotspots). For selected regions, fire-growth simulation environments are assembled. Fuel type data from several fire management agencies are available in grid format at a resolution of 100 m or less; in areas where such data are not available, a national fuels map based on Satellite Pour l’Observation de la Terre Vegetation sensor (SPOT VGT) land cover and forest inventory is used. Similarly, terrain data are available from a variety of sources. Current hotspots are used as ignition points while past hotspots are used to delineate area burned. Surface wind, temperature, and dew-point values (forecast by Environment Canada) are used to determine the fire weather conditions at the fire location. A case study of two large fires in Canada consisting of 54 fire simulation days is used to test these hypotheses.

Additional keywords: fire detection, fire-growth modelling, Wood Buffalo National Park.


Acknowledgements

We thank Parks Canada staff for their support and assistance in providing the necessary fuels and topographic information (including Tanya Letcher for her description of the cause and behavior of the Boyer Rapids fires and Dan Perrakis for his description of fire prediction efforts used on these fires); the Canadian Meteorological Centre for providing the forecast weather information; and the University of Maryland Department of Geography and the NOAA National Environmental Satellite, Data and Information Service for providing the hotspot data. We also thank Mike Flannigan (Canadian Forest Service) and Paul Myers (University of Alberta) for their helpful comments.


References


Anderson K, Reuter G , Flannigan M (2007) Fire-growth modelling using meteorological data with random and systematic perturbations. International Journal of Wildland Fire  16(2), 174–182.
Crossref | GoogleScholarGoogle Scholar | Andrews PL (1986) BEHAVE: Fire behavior prediction and fuel modeling system – BURN subsystem, part 1. USDA Forest Service, Rocky Mountain Research Station, General Technical Report INT-194. (Ogden, UT)

Clark TL, Coen JL , Latham D (2004) Description of a coupled atmosphere–fire model. International Journal of Wildland Fire  13, 49–63.
Crossref | GoogleScholarGoogle Scholar | Englefield P, Lee BS, Fraser RH, Landry R, Hall RJ, Lynham TJ, Cihlar J, Li Z, Jin J, Ahern FJ (2004) Applying geographic information systems and remote sensing to forest fire monitoring, mapping and modelling in Canada. In ‘Proceedings of the 22nd Tall Timbers Fire Ecology Conference: Fire in Temperate, Boreal and Montane Ecosystems’, 15–18 October 2001, Kananaskis, AB. (Eds RT Engstrom, WJ de Groot) pp. 240–245. (Tall Timbers Research Station: Tallahassee, FL)

Finney MA (1998) FARSITE: Fire area simulator – model development and evaluation. USDA Forest Service, Rocky Mountain Research Station, Research Paper RMRS-RP-4. (Ogden, UT)

Forestry Canada Fire Danger Group (1992) Development and structure of the Canadian Forest Fire Behavior Prediction System. Forestry Canada, Science and Sustainable Development Directorate, Information Report ST-X-3. (Ottawa, ON)

Landry C, Parent R, Deschênes J-F, Giguère A, Hardy G, Verret R (2005) Operational Scribe nowcasting subsystem: objective verification results. In ‘21st International Conference on Interactive Information Processing Systems (IIPS) for Meteorology, Oceanography, and Hydrology’, 10–13 January 2005, San Diego, CA. (American Meteorological Society: Boston, MA)

Latifovic R, Zhi-Liang Z, Cihlar J, Giri C , Olthof I (2004) Land cover mapping North and Central America: global land cover 2000. Remote Sensing of Environment  89, 116–127.
Crossref | GoogleScholarGoogle Scholar | Lawson BL, Armitage OB, Hoskins WD (1996) Diurnal variations in the Fine Fuel Moisture Code: tables and computer source code. Canadian Forest Service, Forest Resource Development Agreement Report 245. (Victoria, BC)

Linn R, Reisner J, Colman J , Winterkamp J (2002) Studying wildfire behavior using FIRETEC. International Journal of Wildland Fire  11, 233–246.
Crossref | GoogleScholarGoogle Scholar | Nadeau LB, McRae DJ, Jin J-Z (2005) Development of a national fuel-type map for Canada using fuzzy logic. Canadian Forestry Service, Information Report NOR-X-406. (Edmonton, AB)

Quayle B, Lannom K, Finco M, Norton J, Warnick R (2003) Monitoring wildland fire activity on a national-scale with MODIS imagery. In ‘2nd International Wildland Fire Ecology and Fire Management Congress and 5th Symposium on Fire and Forest Meteorology’, 16–20 November 2003, Orlando, FL. (American Meteorological Service: Boston, MA)

Richards GD (1994) The properties of elliptical wildfire growth for time-dependent fuel and meteorological conditions. Combustion Science Technology  95, 357–383.
Crossref | GoogleScholarGoogle Scholar | Stanski HR, Wilson LJ, Burrows WR (1989) ‘Survey of Common Verification Methods in Meteorology, 2nd edn.’ Report Number (MSRB) 89–5. (Atmospheric Environment Service: Downsview, ON)

Stocks BJ, Lawson BD, Alexander ME, Van Wagner CE, McAlpine RS, Lynham TJ , Dubé DE (1989) The Canadian Forest Fire Danger Rating System: an overview. Forestry Chronicle  65, 450–457.
Van Wagner CE (1977) A method of computing fine fuel moisture content throughout the diurnal cycle. Canadian Forestry Service, Ontario Information Report PS-X-69. (Chalk River, ON)

Van Wagner CE (1987) Development and structure of the Canadian Forest Fire Weather Index System. Canadian Forestry Service, Forest Technology Report 35. (Ottawa, ON)

Verret R, Vigneux D, Marcoux J, Petrucci F, Landry C, Pelletier L, Hardy G (1997) SCRIBE 3.0 A Product Generator. In ‘13th International Conference on Interactive Information and Processing Systems for Meteorology, Oceanography and Hydrology’, 2–7 February 1997, Long Beach, CA. pp. 392–395. (American Meteorological Society: Boston, MA)

Wilson LJ , Vallée M (2002) The Canadian Updateable Model Output Statistics (UMOS) system: design and development tests. Weather and Forecasting  17, 206–222.
Crossref | GoogleScholarGoogle Scholar |

Wilson LJ , Vallée M (2003) The Canadian Updateable Model Output Statistics (UMOS) system: validation against Perfect Prog. Weather and Forecasting  18, 288–302.
Crossref | GoogleScholarGoogle Scholar |