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)

Risk assessment for wildland fire aerial detection patrol route planning in Ontario, Canada

Colin B. McFayden A G , Douglas G. Woolford B , Aaron Stacey C , Den Boychuk D , Joshua M. Johnston E , Melanie J. Wheatley A and David L. Martell F
+ Author Affiliations
- Author Affiliations

A Ontario Ministry of Natural Resources and Forestry, Aviation, Forest Fire and Emergency Services, Dryden Fire Management Centre, 95 Ghost Lake Road, PO Box 850, Dryden, ON P2N 2Z5, Canada.

B Department of Statistical and Actuarial Sciences, University of Western Ontario, 1151 Richmond Street, London, ON N6A 5B7, Canada.

C Ontario Ministry of Natural Resources and Forestry, Aviation, Forest Fire and Emergency Services, 300 Water Street, South Tower, Peterborough, ON K9J 3C7, Canada.

D Ontario Ministry of Natural Resources and Forestry, Aviation, Forest Fire and Emergency Services, 400–70 Foster Drive, Sault Ste Marie, ON P6A 6V5, Canada.

E Canadian Forest Service, Great Lakes Forestry Centre, 1219 Queen Street E, Sault Ste Marie, ON P6A 2E5, Canada.

F Faculty of Forestry, University of Toronto, 33 Willcocks Street, Toronto, ON M5S 3B3, Canada.

G Corresponding author: Email: colin.mcfayden@ontario.ca

International Journal of Wildland Fire 29(1) 28-41 https://doi.org/10.1071/WF19084
Submitted: 9 June 2019  Accepted: 23 October 2019   Published: 5 December 2019

Journal Compilation © IAWF 2020 Open Access CC BY-NC-ND

Abstract

This study presents a model developed using a risk-based framework that is calibrated by experts, and provides a spatially explicit measure of need for aerial detection daily in Ontario, Canada. This framework accounts for potential fire occurrence, behaviour and impact as well as the likelihood of detection by the public. A three-step assessment process of risk, opportunity and tolerance is employed, and the results represent the risk of not searching a specified area for the detection of wildland fires. Subjective assessment of the relative importance of these factors was elicited from Ontario Ministry of Natural Resources and Forestry experts to develop an index that captures their behaviour when they plan aerial detection patrol routes. The model is implemented to automatically produce a province-wide, fine-scale risk index map each day. A retrospective analysis found a statistically significant association between points that aerial detection patrols passed over and their aerial detection demand index values: detection patrols were more likely to pass over areas where the index was higher.

Additional keywords: decision-making, decision support systems, forest fire detection, uncertainty, wildfire detection.


References

Ager AA, Buonopane M, Reger A, Finney MA (2013) Wildfire exposure analysis on the national forests in the Pacific Northwest, USA. Risk Analysis 33, 1000–1020.
Wildfire exposure analysis on the national forests in the Pacific Northwest, USA.Crossref | GoogleScholarGoogle Scholar | 23078351PubMed |

Alexander ME (1982) Calculating and interpreting forest fire intensities. Canadian Journal of Botany 60, 349–357.
Calculating and interpreting forest fire intensities.Crossref | GoogleScholarGoogle Scholar |

Alexander ME, Cole FV (1995) Predicting and interpreting fire intensities in Alaskan black spruce forests using the Canadian system of fire danger rating. (Natural Resources Canada: Ottawa, ON, Canada) Available at http://cfs.nrcan.gc.ca/pubwarehouse/pdfs/24358.pdf [Verified 6 August 2019]

Alkhatib AA (2014) A review on forest fire detection techniques. International Journal of Distributed Sensor Networks 10, 597368
A review on forest fire detection techniques.Crossref | GoogleScholarGoogle Scholar |

Allison RS, Johnston JM, Craig G, Jennings S (2016) Airborne optical and thermal remote sensing for wildfire detection and monitoring. Sensors 16, 1310
Airborne optical and thermal remote sensing for wildfire detection and monitoring.Crossref | GoogleScholarGoogle Scholar |

Arienti MC, Cumming SG, Boutin S (2006) Empirical models of forest fire initial attack success probabilities: the effects of fuels, anthropogenic linear features, fire weather, and management. Canadian Journal of Forest Research 36, 3155–3166.
Empirical models of forest fire initial attack success probabilities: the effects of fuels, anthropogenic linear features, fire weather, and management.Crossref | GoogleScholarGoogle Scholar |

Boychuk D, McFayden C (2017) Appropriate response – Ontario’s strategic approach to wildland fire. Canadian Wildland Fire and Smoke Newsletter (Fall 2017). (Canada Wildfire: Edmonton, AB, Canada) Available at https://docs.wixstatic.com/ugd/90df79_bfcc500b532a4e38abaa78e1ecfdd26b.pdf [Verified 19 June 2019]

Brillinger DR, Preisler HK, Benoit JW (2003) Risk assessment: a forest fire example. In ‘Statistics and science: a festschrift for Terry Speed’. (Ed DR Goldstein) pp. 177–196. (Institute for Mathematical Statistics: Beachwood, OH, USA)

Byram GM (1959) Combustion of forest fuels. In ‘Forest fire: control and use’. (Ed KP Davis) pp. 61–89. (McGraw-Hill Book Company, Inc: New York, NY, USA)

Calkin DE, Thompson MP, Finney MA, Hyde KD (2011) A real-time risk assessment tool supporting wildland fire decision-making. Journal of Forestry 109, 274–280.

Clemen RT, Reilly T (2014) ‘Making hard decisions, 3rd edn.’ (South-Western, Cengage Learning: Mason, OH, USA)

Crichton D (1999) The risk triangle. In ‘Natural disaster management’. (Ed J Ingleton) pp. 102–103. (Tudor Rose: London, UK)

Cumming SG (2005) Effective fire suppression in boreal forests. Canadian Journal of Forest Research 35, 772–786.
Effective fire suppression in boreal forests.Crossref | GoogleScholarGoogle Scholar |

Dreyfus SE (2004) The five-stage model of adult skill acquisition. Bulletin of Science, Technology & Society 24, 177–181.
The five-stage model of adult skill acquisition.Crossref | GoogleScholarGoogle Scholar |

Duff TJ, Tolhurst KG (2015) Operational wildfire suppression modelling: a review evaluating development, state of the art and future directions. International Journal of Wildland Fire 24, 735–748.
Operational wildfire suppression modelling: a review evaluating development, state of the art and future directions.Crossref | GoogleScholarGoogle Scholar |

Elliott T (2005) Expert decision-making in naturalistic environments: a summary of research. (Defence Science and Technology Organisation Systems Sciences Laboratory: Edinburgh, SA, Australia) Available at https://apps.dtic.mil/dtic/tr/fulltext/u2/a434061.pdf [Verified 9 August 2019]

Eno R (n.d.) Exhibits: fire towers. Available at http://www.bushplane.com/exhibits/fire-towers/ [Verified 6 August 2019]

Finney MA (2005) The challenge of quantitative risk analysis for wildland fire. Forest Ecology and Management 211, 97–108.
The challenge of quantitative risk analysis for wildland fire.Crossref | GoogleScholarGoogle Scholar |

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, Canada)

Foster WT (1962) Aircraft in forest fire control in Ontario. Forestry Chronicle 38, 38–48.
Aircraft in forest fire control in Ontario.Crossref | GoogleScholarGoogle Scholar |

Halle W, Asam S, Borg E, Fischer C, Frauenberger O, Lorenz E, Richter R (2018) Firebird – small satellites for wildfire assessment. In ‘2018 IGARSS international geoscience and remote sensing symposium’ 22–27 July 2018, Valencia, Spain. (Ed J Moreno) pp. 8609–8612. (IEEE: New York, NY, USA) 10.1109/IGARSS.2018.8519246

Hand MS, Wibbenmeyer MJ, Calkin DE, Thompson MP (2015) Risk preferences, probability weighting, and strategy trade-offs in wildfire management. Risk Analysis 35, 1876–1891.
Risk preferences, probability weighting, and strategy trade-offs in wildfire management.Crossref | GoogleScholarGoogle Scholar | 26269258PubMed |

Hardy CC (2005) Wildland fire hazard and risk: problems, definitions, and context. Forest Ecology and Management 211, 73–82.
Wildland fire hazard and risk: problems, definitions, and context.Crossref | GoogleScholarGoogle Scholar |

Hasson F, Keeney S, McKenna H (2000) Research guidelines for the Delphi survey technique. Journal of Advanced Nursing 32, 1008–1015.

Hickey AM, Davis AM (2003) Elicitation technique selection: how do experts do it? In ‘Proceedings 11th IEEE international requirements engineering conference’, 8–12 September 2003, Monterey, CA, USA. pp. 169–178. (IEEE: New York, NY, USA) 10.1109/ICRE.2003.1232748

Hirsch KG, Martell DL (1996) A review of initial attack fire crew productivity and effectiveness. International Journal of Wildland Fire 6, 199–215.
A review of initial attack fire crew productivity and effectiveness.Crossref | GoogleScholarGoogle Scholar |

Hirsch KG, Corey PN, Martell DL (1998) Using expert judgment to model initial attack fire crew effectiveness. Forest Science 44, 539–549.

Hirsch KG, Podur JJ, Janser RF, McAlpine RS, Martell DL (2004) Productivity of Ontario initial-attack fire crews: results of an expert-judgement elicitation study. Canadian Journal of Forest Research 34, 705–715.
Productivity of Ontario initial-attack fire crews: results of an expert-judgement elicitation study.Crossref | GoogleScholarGoogle Scholar |

Hoffman RR, Lintern G (2006) Eliciting and representing the knowledge of experts. In ‘Cambridge handbook of expertise and expert performance’. (Eds KA Ericsson, N Charness, P Feltovich, R Hoffman) pp. 203–222. (Cambridge University Press: New York, NY, USA)

Hoffman RR, Shadbolt NR, Burton AM, Klein G (1995) Eliciting knowledge from experts: a methodological analysis. Organizational Behavior and Human Decision Processes 62, 129–158.
Eliciting knowledge from experts: a methodological analysis.Crossref | GoogleScholarGoogle Scholar |

Hutton RJ, Klein G (1999) Expert decision-making. Systems Engineering 2, 32–45.
Expert decision-making.Crossref | GoogleScholarGoogle Scholar |

Johnston J, Johnston L, Wooster M, Brookes A, McFayden C, Cantin A (2018) Satellite detection limitations of sub-canopy smouldering wildfires in the North American Boreal Forest. Fire 1, 28
Satellite detection limitations of sub-canopy smouldering wildfires in the North American Boreal Forest.Crossref | GoogleScholarGoogle Scholar |

Johnston LM, Flannigan MD (2018) Mapping Canadian wildland fire interface areas. International Journal of Wildland Fire 27, 1–14.
Mapping Canadian wildland fire interface areas.Crossref | GoogleScholarGoogle Scholar |

Kahneman D, Klein G (2009) Conditions for intuitive expertise: a failure to disagree. The American Psychologist 64, 515–526.
Conditions for intuitive expertise: a failure to disagree.Crossref | GoogleScholarGoogle Scholar | 19739881PubMed |

Kaplan S, Garrick BJ (1981) On the quantitative definition of risk. Risk Analysis 1, 11–27.
On the quantitative definition of risk.Crossref | GoogleScholarGoogle Scholar |

Kourtz PH (1973) A forest fire detection demand model-for scheduling and routing of airborne detection patrols. Departmental Publication no. 1322. (Environment Canada, Canadian Forestry Service Headquarters: Ottawa, ON, Canada) Available at https://cfs.nrcan.gc.ca/publications?id=24860 [Verified 8 August 2019]

Kourtz PH (1987) The need for improved forest fire detection. Forestry Chronicle 63, 272–277.
The need for improved forest fire detection.Crossref | GoogleScholarGoogle Scholar |

Kourtz PH (1994) Advanced information systems in Canadian forest fire control. In ‘Proceedings of the AFAC conference’, 4 November 1994, Perth, WA, Australia. (Natural Resources Canada: Ottawa, ON, Canada) Available at http://cfs.nrcan.gc.ca/pubwarehouse/pdfs/33796.pdf [Verified 8 August 2019]

Maguire LA, Albright EA (2005) Can behavioral decision theory explain risk-averse fire management decisions? Forest Ecology and Management 211, 47–58.
Can behavioral decision theory explain risk-averse fire management decisions?Crossref | GoogleScholarGoogle Scholar |

Martell DL (1982) A review of operational research studies in forest fire management. Canadian Journal of Forest Research 12, 119–140.
A review of operational research studies in forest fire management.Crossref | GoogleScholarGoogle Scholar |

Martell DL (2011) The development and implementation of forest and wildland fire management decision support systems: reflections on past practices and emerging needs and challenges. Mathematical and Computational Forestry & Natural-Resource Sciences 3, 18–26.

Martell DL, Sun H (2008) The impact of fire suppression, vegetation, and weather on the area burned by lightning-caused forest fires in Ontario. Canadian Journal of Forest Research 38, 1547–1563.
The impact of fire suppression, vegetation, and weather on the area burned by lightning-caused forest fires in Ontario.Crossref | GoogleScholarGoogle Scholar |

Martell DL, Kourtz PH, Tithecott A, Ward PC (1999) The development and implementation of forest fire management decision support systems in Ontario, Canada. In ‘Proceedings of the symposium on fire economics, planning and policy: bottom lines’, 5–9 April 1999, San Diego, CA, USA. USDA Forest Service, Pacific Southwest Research Station, General Technical Report PSWGTR-173. pp. 131–142. (Albany, CA, USA)

McFayden CB, Boychuk D, Woolford DG, Wheatley MJ, Johnston L (2019) Impacts of wildland fire effects on resources and assets through expert elicitation to support fire response decisions. International Journal of Wildland Fire
Impacts of wildland fire effects on resources and assets through expert elicitation to support fire response decisions.Crossref | GoogleScholarGoogle Scholar |

Minas JP, Hearne JW, Handmer J (2012) A review of operations research methods applicable to wildfire management. International Journal of Wildland Fire 21, 189–196.
A review of operations research methods applicable to wildfire management.Crossref | GoogleScholarGoogle Scholar |

National Defence, Fisheries and Oceans Canada (2014) Canadian aeronautical and maritime search and rescue manual. Combined Edn – Vols I, II and III. B-GA-209–001/FP-001 DFO 5449. (Sooke, BC, Canada) Available at https://ccga-pacific.org/training/manuals/CAMSAR-2014-english-signed.pdf [Verified 09 August 2019]

OMNRF (2014) ‘Wildland fire management strategy.’ (Queen’s Printer for Ontario: Toronto, ON, Canada)

OMNRF (2019) Land Information Ontario (LIO). Available at https://www.ontario.ca/page/land-information-ontario [Verified 19 June 2019]

Pacheco AP, Claro J, Fernandes PM, de Neufville R, Oliveira TM, Borges JG, Rodrigues JC (2015) Cohesive fire management within an uncertain environment: a review of risk handling and decision-support systems. Forest Ecology and Management 347, 1–17.
Cohesive fire management within an uncertain environment: a review of risk handling and decision-support systems.Crossref | GoogleScholarGoogle Scholar |

Parks GM (1964) Development and application of a model for suppression of forest fires. Management Science 10, 760–766.
Development and application of a model for suppression of forest fires.Crossref | GoogleScholarGoogle Scholar |

Paudel A, Martell DL, Woolford DG (2019) Factors that affect the timing of the dispatch of initial attack resources to forest fires in north-eastern Ontario, Canada. International Journal of Wildland Fire 28, 15–24.
Factors that affect the timing of the dispatch of initial attack resources to forest fires in north-eastern Ontario, Canada.Crossref | GoogleScholarGoogle Scholar |

Podur J, Wotton BM (2010) Will climate change overwhelm fire management capacity? Ecological Modelling 221, 1301–1309.
Will climate change overwhelm fire management capacity?Crossref | GoogleScholarGoogle Scholar |

Preisler HK, Brillinger DR, Burgan RE, Benoit J (2004) Probability-based models for estimation of wildfire risk. International Journal of Wildland Fire 13, 133–142.
Probability-based models for estimation of wildfire risk.Crossref | GoogleScholarGoogle Scholar |

Schroeder D (2004) Evaluation of three wildfire smoke detection systems. Advantage, 524, 8

Scott JH (2006) An analytical framework for quantifying wildland fire risk and fuel treatment benefit. In ‘Fuels management – How to measure success: conference proceedings’, 28–30 March 2006, Portland, OR, USA. (Eds PL Andrews, BW Butler) pp. 169–184. (USDA Forest Service: Washington, DC, USA). Available at https://www.fs.usda.gov/treesearch/pubs/25944 [Verified 17 July 2019]

Scott JH, Thompson MP, Calkin DE (2013) A wildland fire risk assessment framework for land and resource management. USDA Forest Service, Rocky Mountain Research Station, General Technical Report RMRS-GTR-315. (Ogden, UT, USA)

Simard AJ (1976) Wildland fire management the economics of policy alternatives. Environment Canada, Canadian Forestry Service, Forest Fire Research Institute, Technical Report 15. (Ottawa, ON, Canada)

Taylor SW, Woolford DG, Dean CB, Martell DL (2013) Wildfire prediction to inform management: statistical science challenges. Statistical Science 28, 586–615.
Wildfire prediction to inform management: statistical science challenges.Crossref | GoogleScholarGoogle Scholar |

Thomas PA, McAlpine RS (2010) ‘Fire in the forest.’ (Cambridge University Press: New York, NY, USA)

Thompson MP, Scott J, Helmbrecht D, Calkin DE (2013) Integrated wildland fire risk assessment: framework development and application on the Lewis and Clark National Forest in Montana, USA. Integrated Environmental Assessment and Management 9, 329–342.
Integrated wildland fire risk assessment: framework development and application on the Lewis and Clark National Forest in Montana, USA.Crossref | GoogleScholarGoogle Scholar | 22987567PubMed |

Thompson MP, MacGregor DG, Dunn CJ, Calkin DE, Phipps J (2018) Rethinking the wildland fire management system. Journal of Forestry 116, 382–390.
Rethinking the wildland fire management system.Crossref | GoogleScholarGoogle Scholar |

Tversky A, Kahneman D (1975) Judgment under uncertainty: heuristics and biases. In ‘Utility, probability, and human decision-making’. (Eds D Wendt, CA Vlek) pp. 141–162. (Springer: Dordrecht, The Netherlands)

Van Wagner CE (1987) Development and structure of the Canadian forest fire weather index system. Canadian Forestry Service, Forestry Technical Report 35. (Ottawa, ON, Canada)

Vilar L, Woolford DG, Martell DL, Martín MP (2010) A model for predicting human-caused wildfire occurrence in the region of Madrid, Spain. International Journal of Wildland Fire 19, 325–337.
A model for predicting human-caused wildfire occurrence in the region of Madrid, Spain.Crossref | GoogleScholarGoogle Scholar |

Wilson RS, Winter PL, Maguire LA, Ascher T (2011) Managing wildfire events: risk‐based decision-making among a group of federal fire managers. Risk Analysis 31, 805–818.
Managing wildfire events: risk‐based decision-making among a group of federal fire managers.Crossref | GoogleScholarGoogle Scholar | 21143258PubMed |

Wood SN (2017) ‘Generalized additive models: an introduction with R, 2nd edn.’ (Chapman and Hall/CRC: Boca Raton, FL, USA)

Woolford DG, Bellhouse DR, Braun WJ, Dean CB, Martell DL, Sun J (2011) A spatiotemporal model for people-caused forest fire occurrence in the Romeo Malette Forest. Journal of Environmental Statistics 2, 2–16.

Woolford DG, Dean CB, Martell DL, Cao J, Wotton BM (2014) Lightning‐caused forest fire risk in north-western Ontario, Canada, is increasing and associated with anomalies in fire weather. Environmetrics 25, 406–416.
Lightning‐caused forest fire risk in north-western Ontario, Canada, is increasing and associated with anomalies in fire weather.Crossref | GoogleScholarGoogle Scholar |

Woolford DG, Wotton BM, Martell DL McFayden C, Stacey A (2016) Daily lightning- and person-caused fire prediction models used in Ontario. Poster presented at Wildland Fire Canada Conference, 24–26 October 2016, Kelowna, BC, Canada. Available at http://www.wildlandfire2016.ca/wp-content/uploads/2019/11/McFayden-Fire-Occurence-Prediction-Poster-Ontario-2016-10-17V2Final.pdf [Verified 14 November 2019]

Wotton BM, Martell DL (2005) A lightning fire occurrence model for Ontario. Canadian Journal of Forest Research 35, 1389–1401.

Wotton BM, Stocks BJ, Martell DL (2005) An index for tracking sheltered forest floor moisture within the Canadian Forest Fire Weather Index System. International Journal of Wildland Fire 14, 169–182.
An index for tracking sheltered forest floor moisture within the Canadian Forest Fire Weather Index System.Crossref | GoogleScholarGoogle Scholar |

Xi DD, Taylor SW, Woolford DG, Dean CB (2019) Statistical models of key components of wildfire risk. Annual Review of Statistics and Its Application 6, 197–222.
Statistical models of key components of wildfire risk.Crossref | GoogleScholarGoogle Scholar |

Yuan C, Zhang Y, Liu Z (2015) A survey on technologies for automatic forest fire monitoring, detection, and fighting using unmanned aerial vehicles and remote sensing techniques. Canadian Journal of Forest Research 45, 783–792.
A survey on technologies for automatic forest fire monitoring, detection, and fighting using unmanned aerial vehicles and remote sensing techniques.Crossref | GoogleScholarGoogle Scholar |