Articles citing this paper
cfArticle2ecfc1291681887$funcTITLE@473831c2
Miguel G. Cruz A C , Martin E. Alexander B and Andrew L. Sullivan A
+ Author Affiliations
- Author Affiliations
A CSIRO, GPO Box 1700, Canberra, ACT 2601, Australia.
B Wild Rose Fire Behaviour, 180-50434 Range Road 232, Leduc County, AB, T4X 1L0, Canada.
C Corresponding author. Email: miguel.cruz@csiro.au
International Journal of Wildland Fire 26(11) 973-981 https://doi.org/10.1071/WF17097
Submitted: 13 February 2017 Accepted: 14 August 2017 Published: 24 October 2017
25 articles found in Crossref database.
Pixel-level statistical analyses of prescribed fire spread
Currie M.,
Speer K.,
Hiers J.K.,
O’Brien J.J.,
Goodrick S., Quaife B.
Canadian Journal of Forest Research. 2019 49(1). p.18
Modeling thinning effects on fire behavior with STANDFIRE
Parsons Russell A.,
Pimont Francois,
Wells Lucas,
Cohn Greg,
Jolly W. Matt,
de Coligny Francois,
Rigolot Eric,
Dupuy Jean-Luc,
Mell William, Linn Rodman R.
Annals of Forest Science. 2018 75(1).
Effect of fuel spatial resolution on predictive wildfire models
Taneja Ritu,
Hilton James,
Wallace Luke,
Reinke Karin, Jones Simon
International Journal of Wildland Fire. 2021 30(10). p.776
Empirical Modeling of Fire Spread Rate in No-Wind and No-Slope Conditions
Rossa Carlos G, Fernandes Paulo M
Forest Science. 2018 64(4). p.358
Examining Landscape-Scale Fuel and Terrain Controls of Wildfire Spread Rates Using Repetitive Airborne Thermal Infrared (ATIR) Imagery
Schag Gavin M.,
Stow Douglas A.,
Riggan Philip J.,
Tissell Robert G., Coen Janice L.
Fire. 2021 4(1). p.6
The Impact of Fuel Treatments on Wildfire Behavior in North American Boreal Fuels: A Simulation Study Using FIRETEC
Marshall Ginny,
Thompson Dan,
Anderson Kerry,
Simpson Brian,
Linn Rodman, Schroeder Dave
Fire. 2020 3(2). p.18
A generic fuel moisture content attenuation factor for fire spread rate empirical models
Rossa Carlos G.
Forest Systems. 2018 27(2). p.e009
A response to ‘Clarifying the meaning of mantras in wildland fire behaviour modelling: reply to Cruz et al. (2017)'
Cruz Miguel G.,
Alexander Martin E., Sullivan Andrew L.
International Journal of Wildland Fire. 2018 27(11). p.776
Firefighter tenability and its influence on wildfire suppression
Penney G.,
Habibi D., Cattani M.
Fire Safety Journal. 2019 106 p.38
Review of wildfire modeling considering effects on land surfaces
Or Dani,
Furtak-Cole Eden,
Berli Markus,
Shillito Rose,
Ebrahimian Hamed,
Vahdat-Aboueshagh Hamid, McKenna Sean A.
Earth-Science Reviews. 2023 245 p.104569
An Empirical Model for the Effect of Wind on Fire Spread Rate
Rossa Carlos, Fernandes Paulo
Fire. 2018 1(2). p.31
Clarifying the meaning of mantras in wildland fire behaviour modelling: reply to Cruz et al. (2017)
Mell William,
Simeoni Albert,
Morvan Dominique,
Hiers J. Kevin,
Skowronski Nicholas, Hadden Rory M.
International Journal of Wildland Fire. 2018 27(11). p.770
Conditional Performance Evaluation: Using Wildfire Observations for Systematic Fire Simulator Development
Duff Thomas,
Cawson Jane,
Cirulis Brett,
Nyman Petter,
Sheridan Gary, Tolhurst Kevin
Forests. 2018 9(4). p.189
Evaluating the Performance of Fire Rate of Spread Models in Northern-European Calluna vulgaris Heathlands
Minsavage-Davis Charles D., Davies G. Matt
Fire. 2022 5(2). p.46
Physics-based simulations of grassfire propagation on sloped terrain at field scale: motivations, model reliability, rate of spread and fire intensity†
Innocent Jasmine,
Sutherland Duncan,
Khan Nazmul, Moinuddin Khalid
International Journal of Wildland Fire. 2023 32(4). p.496
Assessing improvements in models used to operationally predict wildland fire rate of spread
Cruz Miguel G.,
Alexander Martin E.,
Sullivan Andrew L.,
Gould James S., Kilinc Musa
Environmental Modelling & Software. 2018 105 p.54
The state of wildfire and bushfire science: Temporal trends, research divisions and knowledge gaps
Haghani Milad,
Kuligowski Erica,
Rajabifard Abbas, Kolden Crystal A.
Safety Science. 2022 153 p.105797
Embracing Complexity to Advance the Science of Wildland Fire Behavior
Yedinak Kara,
Strand Eva,
Hiers J., Varner J.
Fire. 2018 1(2). p.20
The Fire and Smoke Model Evaluation Experiment—A Plan for Integrated, Large Fire–Atmosphere Field Campaigns
Prichard Susan,
Larkin N.,
Ottmar Roger,
French Nancy,
Baker Kirk,
Brown Tim,
Clements Craig,
Dickinson Matt,
Hudak Andrew,
Kochanski Adam,
Linn Rod,
Liu Yongqiang,
Potter Brian,
Mell William,
Tanzer Danielle,
Urbanski Shawn, Watts Adam
Atmosphere. 2019 10(2). p.66
Modelling of the Radiant Heat Flux and Rate of Spread of Wildfire within the Urban Environment
Penney Greg, Richardson Steven
Fire. 2019 2(1). p.4
Differences in Canopy Cover Estimations from ALS Data and Their Effect on Fire Prediction
Taneja Ritu,
Wallace Luke,
Reinke Karin,
Hilton James, Jones Simon
Environmental Modeling & Assessment. 2023 28(4). p.565
Pyros: a raster–vector spatial simulation model for predicting wildland surface fire spread and growth
Voltolina Debora,
Cappellini Giacomo,
Apuani Tiziana, Sterlacchini Simone
International Journal of Wildland Fire. 2024 33(3).
Improving firefighter tenability during entrapment and burnover: An analysis of vehicle protection systems
Penney Greg,
Habibi Daryoush, Cattani Marcus
Fire Safety Journal. 2020 118 p.103209
Assessing uncertainty and demonstrating potential for estimating fire rate of spread at landscape scales based on time sequential airborne thermal infrared imaging
Stow Douglas,
Riggan Philip,
Schag Gavin,
Brewer William,
Tissell Robert,
Coen Janice, Storey Emanuel
International Journal of Remote Sensing. 2019 40(13). p.4876
Design and implementation of a portable, large-scale wind tunnel for wildfire research
Di Cristina Giovanni,
Gallagher Michael R.,
Skowronski Nicholas S.,
Simeoni Albert,
Rangwala Ali, Im Seong-kyun
Fire Safety Journal. 2022 131 p.103607
