Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
International Journal of Wildland Fire International Journal of Wildland Fire Society
Journal of the International Association of Wildland Fire
RESEARCH ARTICLE (Open Access)

Improving silvicultural practices for Mediterranean forests through fire behaviour modelling using LiDAR-derived canopy fuel characteristics

Brigite Botequim A D * , Paulo M. Fernandes B , José G. Borges A , Eduardo González-Ferreiro C and Juan Guerra-Hernández A D *
+ Author Affiliations
- Author Affiliations

A Forest Research Centre, School of Agriculture, University of Lisbon, Instituto Superior de Agronomía (ISA), Tapada da Ajuda, P-1349-017, Lisbon, Portugal.

B Centre for the Research and Technology of Agro-Environmental and Biological Sciences (CITAB), University of Trás-os-Montes e Alto Douro, Quinta de Prados, 5001-801 Vila Real, Portugal.

C Departamento de Tecnología Minera, Topografía y de Infraestructuras, Grupo de Investigación en Geomática e Ingeniería Cartográfica, GI-202-GEOINCA, Escuela Superior y Técnica de Ingenieros de Minas, Universidad de León, Avenida de Astorga s/n, Campus de Ponferrada, 24401 Ponferrada, Spain.

D Corresponding authors. Emails: juanguerra@isa.ulisboa.pt; bbotequim@isa.ulisboa.pt

International Journal of Wildland Fire 28(11) 823-839 https://doi.org/10.1071/WF19001
Submitted: 8 January 2019  Accepted: 2 August 2019   Published: 15 October 2019

Journal Compilation © IAWF 2019 Open Access CC BY-NC-ND

Abstract

Wildfires cause substantial environmental and socioeconomic impacts and threaten many Spanish forested landscapes. We describe how LiDAR-derived canopy fuel characteristics and spatial fire simulation can be integrated with stand metrics to derive models describing fire behaviour. We assessed the potential use of very-low-density airborne LiDAR (light detection and ranging) data to estimate canopy fuel characteristics in south-western Spain Mediterranean forests. Forest type-specific equations were used to estimate canopy fuel attributes, namely stand height, canopy base height, fuel load, bulk density and cover. Regressions explained 61–85, 70–85, 38–96 and 75–95% of the variability in field estimated stand height, canopy fuel load, crown bulk density and canopy base height, respectively. The weakest relationships were found for mixed forests, where fuel loading variability was highest. Potential fire behaviour for typical wildfire conditions was predicted with FlamMap using LiDAR-derived canopy fuel characteristics and custom fuel models. Classification tree analysis was used to identify stand structures in relation to crown fire likelihood and fire suppression difficulty levels. The results of the research are useful for integrating multi-objective fire management decisions and effective fire prevention strategies within forest ecosystem management planning.

Additional keywords: airborne laser scanning (ALS), fire management, remote sensing, Spanish PNOA project (Plan Nacional de Ortofotografía Aérea de España).


References

Agee JK (1996) The influence of forest structure on fire behavior. In ‘Proceedings of the Seventeenth Annual Forest Vegetation Management Conference’, 16–18 January 1996, Redding, CA, USA. pp. 52–68.

Agee JK, Skinner CN (2005) Basic principles of forest fuel reduction treatments. Forest Ecology and Management 211, 83–96.
Basic principles of forest fuel reduction treatments.Crossref | GoogleScholarGoogle Scholar |

Ager AA, Vaillant NM, Finney MA (2010) A comparison of landscape fuel treatment strategies to mitigate wildland fire risk in the urban interface and preserve old forest structure. Forest Ecology and Management 259, 1556–1570.
A comparison of landscape fuel treatment strategies to mitigate wildland fire risk in the urban interface and preserve old forest structure.Crossref | GoogleScholarGoogle Scholar |

Ager AA, Vaillant NM, Finney MA, Preisler HK (2012) Analyzing wildfire exposure and source–sink relationships on a fire-prone forest landscape. Forest Ecology and Management 267, 271–283.
Analyzing wildfire exposure and source–sink relationships on a fire-prone forest landscape.Crossref | GoogleScholarGoogle Scholar |

Alcasena FJ, Salis M, Vega-García C (2016) A fire modeling approach to assess wildfire exposure of valued resources in central Navarra, Spain. European Journal of Forest Research 135, 87–107.
A fire modeling approach to assess wildfire exposure of valued resources in central Navarra, Spain.Crossref | GoogleScholarGoogle Scholar |

Alexander ME, Lanoville RA (1989) Predicting fire behavior in the black spruce–lichen woodland fuel type of western and northern Canada. Canadian Northern Forestry Centre, Edmonton, Alberta, and Government of Northwest Territories, Department of Renewable Resources, Territorial Forest Fire Centre, Fort Smith, Northwest Territories. (Edmonton, AB, Canada)

Alvarez A, Gracia M, Vayreda J, Retana J (2012) Patterns of fuel types and crown fire potential in Pinus halepensis forests in the western Mediterranean Basin. Forest Ecology and Management 270, 282–290.
Patterns of fuel types and crown fire potential in Pinus halepensis forests in the western Mediterranean Basin.Crossref | GoogleScholarGoogle Scholar |

Andersen H-E, McGaughey RJ, Reutebuch SE (2005) Estimating forest canopy fuel parameters using LiDAR data. Remote Sensing of Environment 94, 441–449.
Estimating forest canopy fuel parameters using LiDAR data.Crossref | GoogleScholarGoogle Scholar |

Arroyo LA, Pascual C, Manzanera JA (2008) Fire models and methods to map fuel types: the role of remote sensing. Forest Ecology and Management 256, 1239–1252.
Fire models and methods to map fuel types: the role of remote sensing.Crossref | GoogleScholarGoogle Scholar |

Belsley DA, Kuh E, Welsch RE (2005) ‘Regression diagnostics: identifying influential data and sources of collinearity.’ (John Wiley & Sons, Inc: New York, NY, USA)

Botequim B, Fernandes PM, Garcia-Gonzalo J, Silva A, Borges JG (2017) Coupling fire behaviour modelling and stand characteristics to assess and mitigate fire hazard in a maritime pine landscape in Portugal. European Journal of Forest Research 136, 527–542.
Coupling fire behaviour modelling and stand characteristics to assess and mitigate fire hazard in a maritime pine landscape in Portugal.Crossref | GoogleScholarGoogle Scholar |

Cao L, Coops NC, Hermosilla T, Innes J, Dai J, She G (2014) Using small-footprint discrete and full-waveform airborne LiDAR metrics to estimate total biomass and biomass components in subtropical forests. Remote Sensing 6, 7110–7135.
Using small-footprint discrete and full-waveform airborne LiDAR metrics to estimate total biomass and biomass components in subtropical forests.Crossref | GoogleScholarGoogle Scholar |

Castro FX, Tudela A, Sebastià MT (2003) Modeling moisture content in shrubs to predict fire risk in Catalonia (Spain). Agricultural and Forest Meteorology 116, 49–59.
Modeling moisture content in shrubs to predict fire risk in Catalonia (Spain).Crossref | GoogleScholarGoogle Scholar |

Crespo-Peremarch P, Ruiz LA, Balaguer-Beser A (2016) A comparative study of regression methods to predict forest structure and canopy fuel variables from LiDAR full-waveform data. Revista de Teledetección 27–40.
A comparative study of regression methods to predict forest structure and canopy fuel variables from LiDAR full-waveform data.Crossref | GoogleScholarGoogle Scholar |

Crespo-Peremarch P, Ruiz LÁ, Balaguer-Beser Á, Estornell J (2018) Analyzing the role of pulse density and voxelization parameters on full-waveform LiDAR-derived metrics. ISPRS Journal of Photogrammetry and Remote Sensing 146, 453–464.
Analyzing the role of pulse density and voxelization parameters on full-waveform LiDAR-derived metrics.Crossref | GoogleScholarGoogle Scholar |

Cruz MG, Alexander ME (2010) Assessing crown fire potential in coniferous forests of western North America: a critique of current approaches and recent simulation studies. International Journal of Wildland Fire 19, 377–398.
Assessing crown fire potential in coniferous forests of western North America: a critique of current approaches and recent simulation studies.Crossref | GoogleScholarGoogle Scholar |

Cruz MG, Alexander ME (2013) Uncertainty associated with model predictions of surface and crown fire rates of spread. Environmental Modelling & Software 47, 16–28.
Uncertainty associated with model predictions of surface and crown fire rates of spread.Crossref | GoogleScholarGoogle Scholar |

Cruz MG, Alexander ME, Wakimoto RH (2003) Assessing canopy fuel stratum characteristics in crown fire-prone fuel types of western North America. International Journal of Wildland Fire 12, 39–50.
Assessing canopy fuel stratum characteristics in crown fire-prone fuel types of western North America.Crossref | GoogleScholarGoogle Scholar |

Cumming SG (2001) Forest type and wildfire in the Alberta boreal mixedwood: what do fires burn? Ecological Applications 11, 97–110.
Forest type and wildfire in the Alberta boreal mixedwood: what do fires burn?Crossref | GoogleScholarGoogle Scholar |

De’ath G, Fabricius KE (2000) Classification and regression trees: a powerful yet simple technique for ecological data analysis. Ecology 81, 3178–3192.
Classification and regression trees: a powerful yet simple technique for ecological data analysis.Crossref | GoogleScholarGoogle Scholar |

Erdody TL, Moskal LM (2010) Fusion of LiDAR and imagery for estimating forest canopy fuels. Remote Sensing of Environment 114, 725–737.
Fusion of LiDAR and imagery for estimating forest canopy fuels.Crossref | GoogleScholarGoogle Scholar |

Fernandes PM (2009) Combining forest structure data and fuel modelling to classify fire hazard in Portugal. Annals of Forest Science 66, 415
Combining forest structure data and fuel modelling to classify fire hazard in Portugal.Crossref | GoogleScholarGoogle Scholar |

Fernandes PM, Vega JA, Jimenez E, Rigolot E (2008) Fire resistance of European pines. Forest Ecology and Management 256, 246–255.
Fire resistance of European pines.Crossref | GoogleScholarGoogle Scholar |

Fernandes PM, Fernandes MM, Loureiro C (2015) Post-fire live residuals of maritime pine plantations in Portugal: structure, burn severity, and fire recurrence. Forest Ecology and Management 347, 170–179.
Post-fire live residuals of maritime pine plantations in Portugal: structure, burn severity, and fire recurrence.Crossref | GoogleScholarGoogle Scholar |

Fernández-Alonso JM, Alberdi I, Álvarez-González JG, Vega JA, Cañellas I, Ruiz-González AD (2013) Canopy fuel characteristics in relation to crown fire potential in pine stands: analysis, modelling and classification. European Journal of Forest Research 132, 363–377.
Canopy fuel characteristics in relation to crown fire potential in pine stands: analysis, modelling and classification.Crossref | GoogleScholarGoogle Scholar |

Ferreira L, Constantino MF, Borges JG, Garcia-Gonzalo J (2012) A stochastic dynamic programming approach to optimize short-rotation coppice systems management scheduling: an application to eucalypt plantations under wildfire risk in Portugal. Forest Science 58, 353–365.
A stochastic dynamic programming approach to optimize short-rotation coppice systems management scheduling: an application to eucalypt plantations under wildfire risk in Portugal.Crossref | GoogleScholarGoogle Scholar |

Ferreira L, Constantino M, Borges JG (2014) A stochastic approach to optimize maritime pine (Pinus pinaster Ait.) stand management scheduling under fire risk. An application in Portugal. Annals of Operations Research 219, 359–377.
A stochastic approach to optimize maritime pine (Pinus pinaster Ait.) stand management scheduling under fire risk. An application in Portugal.Crossref | GoogleScholarGoogle Scholar |

Finney MA (1998) FARSITE: Fire Area Simulator – model development and evaluation. USDA Forest Service, Rocky Mountain Research Station, Research Paper RMRS-RP-4, revised 2004. (Ogden, UT, USA)

Finney MA (2006) An overview of FlamMap fire modeling capabilities. In ‘Fuels Management – How to Measure Success: Conference Proceedings’, 28–30 March 2006, Portland, OR, USA. (Comps PL Andrews, BW Butler) USDA Forest Service, Rocky Mountain Research Station, Proceedings RMRS-P-41, pp. 213–220. (Fort Collins, CO, USA)

García M, Riaño D, Chuvieco E, Salas J, Danson FM (2011) Multispectral and LiDAR data fusion for fuel type mapping using Support Vector Machine and decision rules. Remote Sensing of Environment 115, 1369–1379.
Multispectral and LiDAR data fusion for fuel type mapping using Support Vector Machine and decision rules.Crossref | GoogleScholarGoogle Scholar |

Garcia-Gonzalo J, Pukkala T, Borges JG (2014) Integrating fire risk in stand management scheduling. An application to maritime pine stands in Portugal. Annals of Operations Research 219, 379–395.
Integrating fire risk in stand management scheduling. An application to maritime pine stands in Portugal.Crossref | GoogleScholarGoogle Scholar |

Gómez-Vázquez I, Crecente-Campo F, Diéguez-Aranda U, Castedo-Dorado F (2013) Modelling canopy fuel variables in Pinus pinaster Ait. and Pinus radiata D. Don stands in north-western Spain. Annals of Forest Science 70, 161–172.
Modelling canopy fuel variables in Pinus pinaster Ait. and Pinus radiata D. Don stands in north-western Spain.Crossref | GoogleScholarGoogle Scholar |

Gómez-Vázquez I, Fernandes PM, Arias-Rodil M, Barrio-Anta M, Castedo-Dorado F (2014) Using density management diagrams to assess crown fire potential in Pinus pinaster Ait. stands. Annals of Forest Science 71, 473–484.
Using density management diagrams to assess crown fire potential in Pinus pinaster Ait. stands.Crossref | GoogleScholarGoogle Scholar |

González-Ferreiro E, Diéguez-Aranda U, Crecente-Campo F, Barreiro-Fernández L, Miranda D, Castedo-Dorado F (2014) Modelling canopy fuel variables for Pinus radiata D. Don in NW Spain with low-density LiDAR data. International Journal of Wildland Fire 23, 350–362.
Modelling canopy fuel variables for Pinus radiata D. Don in NW Spain with low-density LiDAR data.Crossref | GoogleScholarGoogle Scholar |

González-Ferreiro E, Arellano-Pérez S, Castedo-Dorado F, Hevia A, Vega JA, Vega-Nieva D, Álvarez-González JG, Ruiz-González AD (2017) Modelling the vertical distribution of canopy fuel load using national forest inventory and low-density airbone laser scanning data. PLoS One 12, e0176114
Modelling the vertical distribution of canopy fuel load using national forest inventory and low-density airbone laser scanning data.Crossref | GoogleScholarGoogle Scholar | 28448524PubMed |

González-Olabarria J-R, Rodríguez F, Fernández-Landa A, Mola-Yudego B (2012) Mapping fire risk in the model forest of Urbión (Spain) based on airborne LiDAR measurements. Forest Ecology and Management 282, 149–156.
Mapping fire risk in the model forest of Urbión (Spain) based on airborne LiDAR measurements.Crossref | GoogleScholarGoogle Scholar |

Guerra-Hernández J, Görgens EB, García-Gutiérrez J, Rodriguez LCE, Tomé M, González-Ferreiro E (2016a) Comparison of ALS based models for estimating aboveground biomass in three types of Mediterranean forest. European Journal of Remote Sensing 49, 185–204.
Comparison of ALS based models for estimating aboveground biomass in three types of Mediterranean forest.Crossref | GoogleScholarGoogle Scholar |

Guerra-Hernández J, Tomé M, González-Ferreiro E (2016b) Using low-density LiDAR data to map Mediterranean forest characteristics by means of an area-based approach and height threshold analysis. Revista de Teledetección 103–117.
Using low-density LiDAR data to map Mediterranean forest characteristics by means of an area-based approach and height threshold analysis.Crossref | GoogleScholarGoogle Scholar |

Hall SA, Burke IC, Box DO, Kaufmann MR, Stoker JM (2005) Estimating stand structure using discrete-return lidar: an example from low-density, fire-prone ponderosa pine forests. Forest Ecology and Management 208, 189–209.
Estimating stand structure using discrete-return lidar: an example from low-density, fire-prone ponderosa pine forests.Crossref | GoogleScholarGoogle Scholar |

Hermosilla T, Ruiz LA, Kazakova AN, Coops NC, Moskal LM (2014) Estimation of forest structure and canopy fuel parameters from small-footprint full-waveform LiDAR data. International Journal of Wildland Fire 23, 224–233.
Estimation of forest structure and canopy fuel parameters from small-footprint full-waveform LiDAR data.Crossref | GoogleScholarGoogle Scholar |

Hevia A, Álvarez-González JG, Ruiz-Fernández E, Prendes C, Ruiz-González AD, Majada J, González-Ferreiro E (2016) Modelling canopy fuel and forest stand variables and characterizing the influence of thinning in the stand structure using airborne LiDAR. Revista de Teledetección 41–55.
Modelling canopy fuel and forest stand variables and characterizing the influence of thinning in the stand structure using airborne LiDAR.Crossref | GoogleScholarGoogle Scholar |

Jakubowksi MK, Guo Q, Collins B, Stephens S, Kelly M (2013) Predicting surface fuel models and fuel metrics using lidar and CIR imagery in a dense mixed-conifer forest. Photogrammetric Engineering and Remote Sensing 79, 37–49.

Jiménez E, Vega-Nieva D, Rey E, Fernández C, Vega JA (2016) Midterm fuel structure recovery and potential fire behaviour in a Pinus pinaster Ait. forest in northern central Spain after thinning and mastication. European Journal of Forest Research 135, 675–686.
Midterm fuel structure recovery and potential fire behaviour in a Pinus pinaster Ait. forest in northern central Spain after thinning and mastication.Crossref | GoogleScholarGoogle Scholar |

Kelly M, Su Y, Di Tommaso S, Fry DL, Collins BM, Stephens SL, Guo Q (2017) Impact of error in LiDAR-derived canopy height and canopy base height on modeled wildfire behavior in the Sierra Nevada, California, USA. Remote Sensing 10, 10
Impact of error in LiDAR-derived canopy height and canopy base height on modeled wildfire behavior in the Sierra Nevada, California, USA.Crossref | GoogleScholarGoogle Scholar |

Keyes CR, O’Hara KL (2002) Quantifying stand targets for silvicultural prevention of crown fires. Western Journal of Applied Forestry 17, 101–109.

Kraus K, Pfeifer N (2001) Advanced DTM generation from LIDAR data. The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences 34, 23–30.

Latifi H, Fassnacht FE, Hartig F, Berger C, Hernández J, Corvalán P, Koch B (2015) Stratified aboveground forest biomass estimation by remote sensing data. International Journal of Applied Earth Observation and Geoinformation 38, 229–241.
Stratified aboveground forest biomass estimation by remote sensing data.Crossref | GoogleScholarGoogle Scholar |

Lumley T, Miller A (2009) Leaps: regression subset selection. R package version 2.9. Available at http://CRAN R-project org/package=leaps [Verified 12 June 2018]

Maltamo M, Næsset E, Vauhkonen J (2014) ‘Forestry applications of airborne laser scanning.’ (Springer: Dordrecht)

Martin A, Botequim B, Oliveira TM, Ager A, Pirotti F (2016) Resource Communication. Temporal optimization of fuel treatment design in blue gum (Eucalyptus globulus) plantations. Forest Systems 25, eRC09
Resource Communication. Temporal optimization of fuel treatment design in blue gum (Eucalyptus globulus) plantations.Crossref | GoogleScholarGoogle Scholar |

McGaughey R (2016) FUSION/LDV: software for LiDAR data analysis and visualization. Version 3.41. USDA Forest Service, Pacific Northwest Research Station. (Seattle, WA, USA)

Ministerio de Fomento (Ed) (2010) Plan Nacional de Ortofotografía aérea. Especificaciones Técnicas para vuelo fotogramétrico digital con vuelo LiDAR. (Ministerio de Fomento: Madrid, Spain) Available at https://pnoa.ign.es/especificaciones-tecnicas [Verified 1 October 2019] [in Spanish]

Molina JR, Silva FR, Herrera MA (2011) Potential crown fire behavior in Pinus pinea stands following different fuel treatments. Forest Systems 20, 266–267.
Potential crown fire behavior in Pinus pinea stands following different fuel treatments.Crossref | GoogleScholarGoogle Scholar |

Morsdorf F, Mårell A, Koetz B, Cassagne N, Pimont F, Rigolot E, Allgöwer B (2010) Discrimination of vegetation strata in a multilayered Mediterranean forest ecosystem using height and intensity information derived from airborne laser scanning. Remote Sensing of Environment 114, 1403–1415.
Discrimination of vegetation strata in a multilayered Mediterranean forest ecosystem using height and intensity information derived from airborne laser scanning.Crossref | GoogleScholarGoogle Scholar |

Mutlu M, Popescu SC, Stripling C, Spencer T (2008) Mapping surface fuel models using LiDAR and multispectral data fusion for fire behavior. Remote Sensing of Environment 112, 274–285.
Mapping surface fuel models using LiDAR and multispectral data fusion for fire behavior.Crossref | GoogleScholarGoogle Scholar |

Nakai T, Sumida A, Kodama Y, Hara T, Ohta T (2010) A comparison between various definitions of forest stand height and aerodynamic canopy height. Agricultural and Forest Meteorology 150, 1225–1233.
A comparison between various definitions of forest stand height and aerodynamic canopy height.Crossref | GoogleScholarGoogle Scholar |

R Core Team (2017) ‘R: a language and environment for statistical computing.’ (R Foundation for Statisitcal Computing: Vienna, Austria)

Reinhardt ED, Crookston NL (Tech Eds) (2003) The Fire and Fuels Extension to the Forest Vegetation Simulator. USDA Forest Service, Rocky Mountain Research Station, General Technical Report RMRS-GTR-116. (Ogden, UT, USA)

Riaño D, Meier E, Allgöwer B, Chuvieco E, Ustin SL (2003) Modeling airborne laser scanning data for the spatial generation of critical forest parameters in fire behavior modeling. Remote Sensing of Environment 86, 177–186.
Modeling airborne laser scanning data for the spatial generation of critical forest parameters in fire behavior modeling.Crossref | GoogleScholarGoogle Scholar |

Riaño D, Chuvieco E, Condés S, González-Matesanz J, Ustin SL (2004) Generation of cruz for Pinus sylvestris L. from lidar. Remote Sensing of Environment 92, 345–352.
Generation of cruz for Pinus sylvestris L. from lidar.Crossref | GoogleScholarGoogle Scholar |

Rodríguez y Silva F, Molina-Martínez JR (2012) Modeling Mediterranean forest fuels by integrating field data and mapping tools. European Journal of Forest Research 131, 571–582.
Modeling Mediterranean forest fuels by integrating field data and mapping tools.Crossref | GoogleScholarGoogle Scholar |

Rodríguez y Silva F, Guijarro M, Madrigal J, Jiménez E, Molina JR, Hernando C, Vélez R, Vega JA (2017) Assessment of crown fire initiation and spread models in Mediterranean conifer forests by using data from field and laboratory experiments. Forest Systems 26, e02S
Assessment of crown fire initiation and spread models in Mediterranean conifer forests by using data from field and laboratory experiments.Crossref | GoogleScholarGoogle Scholar |

Salazar Iglesias S, Sanchez LE, Galindo P, Santa Regina I (2010) Above-ground tree biomass equations and nutrient pools for a paraclimax chestnut stand and for a climax oak stand in the Sierra de Francia Mountains, Salamanca, Spain. Scientific Research and Essays 5, 1294–1301.

Salis M, Ager AA, Arca B, Finney MA, Bacciu V, Duce P, Spano D (2013) Assessing exposure of human and ecological values to wildfire in Sardinia, Italy. International Journal of Wildland Fire 22, 549–565.
Assessing exposure of human and ecological values to wildfire in Sardinia, Italy.Crossref | GoogleScholarGoogle Scholar |

Salis M, Laconi M, Ager AA, Alcasena FJ, Arca B, Lozano O, de Oliveira AF, Spano D (2016) Evaluating alternative fuel treatment strategies to reduce wildfire losses in a Mediterranean area. Forest Ecology and Management 368, 207–221.
Evaluating alternative fuel treatment strategies to reduce wildfire losses in a Mediterranean area.Crossref | GoogleScholarGoogle Scholar |

SAS Institute (2012) ‘JMP 10 Modeling and Multivariate Methods.’ (SAS Institute: Cary, NC, USA)

Shapiro SS, Wilk MB, Chen HJ (1968) A comparative study of various tests for normality. Journal of the American Statistical Association 63, 1343–1372.
A comparative study of various tests for normality.Crossref | GoogleScholarGoogle Scholar |

Skowronski NS, Clark KL, Duveneck M, Hom J (2011) Three-dimensional canopy fuel loading predicted using upward- and downward-sensing LiDAR systems. Remote Sensing of Environment 115, 703–714.
Three-dimensional canopy fuel loading predicted using upward- and downward-sensing LiDAR systems.Crossref | GoogleScholarGoogle Scholar |

Smith AM, Falkowski MJ, Hudak AT, Evans JS, Robinson AP, Steele CM (2009) A cross-comparison of field, spectral, and lidar estimates of forest canopy cover. Canadian Journal of Remote Sensing 35, 447–459.
A cross-comparison of field, spectral, and lidar estimates of forest canopy cover.Crossref | GoogleScholarGoogle Scholar |

Van Wagner CE (1977) Conditions for the start and spread of crown fire. Canadian Journal of Forest Research 7, 23–34.

Zhao K, Popescu S, Meng X, Pang Y, Agca M (2011) Characterizing forest canopy structure with LiDAR composite metrics and machine learning. Remote Sensing of Environment 115, 1978–1996.
Characterizing forest canopy structure with LiDAR composite metrics and machine learning.Crossref | GoogleScholarGoogle Scholar |