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Type: Journal Article
Author(s): William J. Massman; Jason M. Forthofer; Mark A. Finney
Publication Date: 2017

The ability to rapidly estimate wind speed beneath a forest canopy or near the ground surface in any vegetation is critical to practical wildland fire behavior models. The common metric of this wind speed is the “mid-flame” wind speed, UMF. However, the existing approach for estimating UMF has some significant shortcomings. These include the assumptions that both the within-canopy wind speed and the canopy structure are uniform with depth (z) throughout the canopy and that the canopy roughness length (z0) and displacement height (d) are the same regardless of canopy structure and foliage density. The purpose of this study is to develop and assess a model of canopy wind and Reynolds stress that eliminates these shortcomings and thereby provide a more physically realistic method for calculating UMF. The present model can be used for canopies of arbitrary plant surface distribution and leaf area, and the single function that describes the within-canopy wind speed is shown to reproduce observed canopy wind speed profiles across a wide variety of canopies. An equally simple analytical expression for the within-canopy Reynolds stress, u^2(z), also provides a reasonable description of the observed vertical profiles of Reynolds stress. In turn, u^2(z) is used to calculate z0 and d. Tests of operational performance are also discussed.

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Citation: Massman, William J.; Forthofer, Jason M.; Finney, Mark A. 2017. An improved canopy wind model for predicting wind adjustment factors and wildland fire behavior. Canadian Journal of Forest Research 47(5):594-603.

Cataloging Information

Alaska    California    Eastern    Great Basin    Hawaii    Northern Rockies    Northwest    Rocky Mountain    Southern    Southwest    National
  • canopy foliage distribution
  • fire spread modeling
  • forest canopy
  • Rothermel model
  • wind speed
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Record Maintained By: FRAMES Staff (
FRAMES Record Number: 23762