The effect of model resolution in predicting meteorological parameters used in fire danger rating
Document Type: Journal Article
Author(s): Jeanne L. Hoadley; Kenneth Westrick; Sue A. Ferguson; Scott L. Goodrick; Larry S. Bradshaw; Paul A. Werth
Publication Year: 2004

Cataloging Information

  • fire danger prediction
  • fire danger rating
  • fire management
  • fire weather
  • MM5 mesoscale model
Record Maintained By:
Record Last Modified: December 13, 2016
FRAMES Record Number: 4307


Previous studies of model performance at varying resolutions have focused on winter storms or isolated convective events. Little attention has been given to the static high pressure situations that may lead to severe wildfire outbreaks. This study focuses on such an event so as to evaluate the value of increased model resolution for prediction of fire danger. The results are intended to lay the groundwork for using the fifth-generation Pennsylvania State University-National Center for Atmospheric Research Mesoscale Model (MM5) as input to the National Fire Danger Rating System to provide gridded predictions of fire danger indices. Predicted weather parameters were derived from MM5 and evaluated at three different resolutions (36, 12, and 4 km). Model output was compared with observations during the 2000 fire season in western Montana and northern Idaho to help to determine the model's skill in predicting fire danger. For application in fire danger rating, little significant improvement was found in skill with increased model resolution using standard forecast verification techniques. Diurnal bias of modeled temperature and relative humidity resulted in errors larger than the differences between resolutions. Significant timing and magnitude errors at all resolutions could jeopardize accurate prediction of fire danger.

Online Link(s):
Hoadley, Jeanne L.; Westrick, Kenneth; Ferguson, Sue A.; Goodrick, Scott L.; Bradshaw, Larry S.; Werth, Paul. 2004. The effect of model resolution in predicting meteorological parameters used in fire danger rating. Journal of Applied Meteorology 43(10): 1333-1347.