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Wildlife Research Wildlife Research Society
Ecology, management and conservation in natural and modified habitats
RESEARCH ARTICLE (Open Access)

Drone thermal imaging technology provides a cost-effective tool for landscape-scale monitoring of a cryptic forest-dwelling species across all population densities

Lachlan G. Howell https://orcid.org/0000-0003-1471-1674 A B C G , John Clulow https://orcid.org/0000-0001-8991-1449 A C , Neil R. Jordan https://orcid.org/0000-0002-0712-8301 D E , Chad T. Beranek https://orcid.org/0000-0001-9747-2917 A C , Shelby A. Ryan https://orcid.org/0000-0001-7958-2645 A C , Adam Roff https://orcid.org/0000-0002-0457-8251 A F and Ryan R. Witt https://orcid.org/0000-0003-3696-6395 A C
+ Author Affiliations
- Author Affiliations

A School of Environmental and Life Sciences, Biology Building, University of Newcastle, University Drive, Callaghan, NSW 2308, Australia.

B Centre for Integrative Ecology, School of Life and Environmental Sciences, Deakin University Geelong, Melbourne Burwood Campus, 221 Burwood Highway, Burwood, Vic. 3125, Australia

C FAUNA Research Alliance, PO Box 5092, Kahibah, NSW 2290, Australia.

D Centre for Ecosystem Science, School of BEES, University of New South Wales (UNSW Sydney), Sydney, NSW 2052, Australia.

E Taronga Institute of Science and Learning, Taronga Conservation Society Australia, Taronga Western Plains Zoo, Dubbo, NSW 2830, Australia.

F Science Division, Department of Planning, Industry and Environment, Newcastle, NSW 2300, Australia.

G Corresponding author. Email: lachlan.howell@newcastle.edu.au

Wildlife Research 49(1) 66-78 https://doi.org/10.1071/WR21034
Submitted: 11 February 2021  Accepted: 17 September 2021   Published: 20 December 2021

Journal Compilation © CSIRO 2022 Open Access CC BY-NC

Abstract

Context: Drones, or remotely piloted aircraft systems, equipped with thermal imaging technology (RPAS thermal imaging) have recently emerged as a powerful monitoring tool for koala populations. Before wide uptake of novel technologies by government, conservation practitioners and researchers, evidence of greater efficiency and cost-effectiveness than with other available methods is required.

Aims: We aimed to provide the first comprehensive analysis of the cost-effectiveness of RPAS thermal imaging for koala detection against two field-based methods, systematic spotlighting (Spotlight) and the refined diurnal radial search component of the spot-assessment technique (SAT).

Methods: We conducted various economic comparisons, particularly comparative cost-effectiveness of RPAS thermal imaging, Spotlight and SAT for repeat surveys of a low-density koala population. We compared methods on cost-effectiveness as well as long-term costs by using accumulating cost models. We also compared detection costs across population density using a predictive cost model.

Key results: Despite substantial hardware, training and licensing costs at the outset (>A$49 900), RPAS thermal imaging surveys were cost-effective, detecting the highest number of koalas per dollar spent. Modelling also suggested that RPAS thermal imaging requires the lowest survey effort to detect koalas within the range of publicly available koala population densities (~0.006–18 koalas ha−1) and would provide long-term cost reductions across longitudinal monitoring programs. RPAS thermal imaging would also require the lowest average survey effort costs at a landscape scale (A$3.84 ha−1), providing a cost-effective tool across large spatial areas.

Conclusions: Our analyses demonstrated drone thermal imaging technology as a cost-effective tool for conservation practitioners monitoring koala populations. Our analyses may also form the basis of decision-making tools to estimate survey effort or total program costs across any koala population density.

Implications: Our novel approach offers a means to perform various economic comparisons of available survey techniques and guide investment decisions towards developing standardised koala monitoring approaches. Our results may assist stakeholders and policymakers to confidently invest in RPAS thermal imaging technology and achieve optimal conservation outcomes for koala populations, with standardised data collection delivered through evidence-based and cost-effective monitoring programs.

Keywords: cost-effectiveness, density, drones, koala, population monitoring, Phascolarctos cinereus, survey methods.


References

Beranek, C. T., Roff, A., Denholm, B., Howell, L. G., and Witt, R. R. (2021). Trialling a real-time drone detection and validation protocol for the koala (Phascolarctos cinereus). Australian Mammalogy 43, 260–264.

Brown, G., McAlpine, C., Rhodes, J., Lunney, D., Goldingay, R., Fielding, K., Hetherington, S., Hopkins, M., Manning, C., and Wood, M. (2018). Assessing the validity of crowdsourced wildlife observations for conservation using public participatory mapping methods. Biological Conservation 227, 141–151.
Assessing the validity of crowdsourced wildlife observations for conservation using public participatory mapping methods.Crossref | GoogleScholarGoogle Scholar |

Burke, C., Rashman, M., Wich, S., Symons, A., Theron, C., and Longmore, S. (2019). Optimizing observing strategies for monitoring animals using drone-mounted thermal infrared cameras. International Journal of Remote Sensing 40, 439–467.
Optimizing observing strategies for monitoring animals using drone-mounted thermal infrared cameras.Crossref | GoogleScholarGoogle Scholar |

Corcoran, E., Denman, S., Hanger, J., Wilson, B., and Hamilton, G. (2019). Automated detection of koalas using low-level aerial surveillance and machine learning. Scientific Reports 9, 3208.
Automated detection of koalas using low-level aerial surveillance and machine learning.Crossref | GoogleScholarGoogle Scholar | 30824795PubMed |

Cristescu, R. H., Foley, E., Markula, A., Jackson, G., Jones, D., and Frere, C. (2015). Accuracy and efficiency of detection dogs: a powerful new tool for koala conservation and management. Scientific Reports 5, 8349.
Accuracy and efficiency of detection dogs: a powerful new tool for koala conservation and management.Crossref | GoogleScholarGoogle Scholar | 25666691PubMed |

Crowther, M. S., Dargan, J. R., Madani, G., Rus, A. I., Krockenberger, M. B., McArthur, C., Moore, B. D., Lunney, D., and Mella, V. S. A. (2021). Comparison of three methods of estimating the population size of an arboreal mammal in a fragmented rural landscape. Wildlife Research 48, 105–114.

Curtin, A., Lunney, D., and Matthews, A. (2001). A survey of a low-density koala population in a major reserve system, near Sydney, New South Wales. Australian Mammalogy 23, 135–144.
A survey of a low-density koala population in a major reserve system, near Sydney, New South Wales.Crossref | GoogleScholarGoogle Scholar |

Department of Planning, Industry and Environment (2020). NSW Government Response: Inquiry into koala populations and habitat in New South Wales. Sydney. Available at https://www.parliament.nsw.gov.au/lcdocs/inquiries/2536/Koala%20populations%20and%20habitat%20in%20New%20South%20Wales%20-%20Report%203%20-%20Government%20response.pdf.

Dickman, C., Driscoll, D., Garnett, S., Keith, D., Legge, S., Lindenmayer, D., Maron, M., Reside, A., Ritchie, E., Watson, J., Wintle, B., and Woinarski, J. (2020). After the catastrophe: a blueprint for a conservation response to large-scale ecological disaster, Threatened Species Recovery Hub, January 2020. Available at https://www.nespthreatenedspecies.edu.au/media/0akfale0/after-the-catastrophe-report_v5.pdf.

Dique, D. S., de Villiers, D. L., and Preece, H. J. (2003). Evaluation of line-transect sampling for estimating koala abundance in the Pine Rivers Shire, south-east Queensland. Wildlife Research 30, 127–133.
Evaluation of line-transect sampling for estimating koala abundance in the Pine Rivers Shire, south-east Queensland.Crossref | GoogleScholarGoogle Scholar |

Ellis, W., FitzGibbon, S., Melzer, A., Wilson, R., Johnston, S., Bercovitch, F., Dique, D., and Carrick, F. (2013). Koala habitat use and population density: using field data to test the assumptions of ecological models. Australian Mammalogy 35, 160–165.
Koala habitat use and population density: using field data to test the assumptions of ecological models.Crossref | GoogleScholarGoogle Scholar |

Garden, J. G., McAlpine, C. A., Possingham, H. P., and Jones, D. N. (2007). Using multiple survey methods to detect terrestrial reptiles and mammals: What are the most successful and cost-efficient combinations? Wildlife Research 34, 218–227.
Using multiple survey methods to detect terrestrial reptiles and mammals: What are the most successful and cost-efficient combinations?Crossref | GoogleScholarGoogle Scholar |

Hamilton, G., Corcoran, E., Denman, S., Hennekam, M. E., and Koh, L. P. (2020). When you can’t see the koalas for the trees: using drones and machine learning in complex environments. Biological Conservation 247, 108598.
When you can’t see the koalas for the trees: using drones and machine learning in complex environments.Crossref | GoogleScholarGoogle Scholar |

Hennessy, K., Lucas, C., Nicholls, N., Bathols, J., Suppiah, R., and Ricketts, J. (2005). Climate change impacts on fire-weather in south-east Australia. CSIRO Marine and Atmospheric Research. (Melbourne). Available at http://www.cmar.csiro.au/e-print/open/hennessykj_2005b.pdf.

Hill, A. P., Prince, P., Snaddon, J. L., Doncaster, C. P., and Rogers, A. (2019). AudioMoth: a low-cost acoustic device for monitoring biodiversity and the environment. HardwareX 6, e00073.
AudioMoth: a low-cost acoustic device for monitoring biodiversity and the environment.Crossref | GoogleScholarGoogle Scholar |

Hodgson, J. C., Mott, R., Baylis, S. M., Pham, T. T., Wotherspoon, S., Kilpatrick, A. D., Raja Segaran, R., Reid, I., Terauds, A., and Koh, L. P. (2018). Drones count wildlife more accurately and precisely than humans. Methods in Ecology and Evolution 9, 1160–1167.
Drones count wildlife more accurately and precisely than humans.Crossref | GoogleScholarGoogle Scholar |

Hundloe, T., and Hamilton, C. (1997). Koalas and tourism: an economic evaluation. Available at https://australiainstitute.org.au/report/koalas-and-tourism-an-economic-evaluation/.

Lahoz-Monfort, J. J., and Tingley, R. (2018). The technology revolution: improving species detection and monitoring using new tools and statistical methods. In ‘Monitoring Threatened Species and Ecological Communities’. (Eds S. Legge, D. Lindenmayer, N. Robinson, B. Scheele, D. Southwell, and B. Wintle.) pp. 303–313. (CSIRO Publishing: Melbourne, Vic., Australia.)

Law, B. S., Brassil, T., Gonsalves, L., Roe, P., Truskinger, A., and McConville, A. (2018). Passive acoustics and sound recognition provide new insights on status and resilience of an iconic endangered marsupial (koala Phascolarctos cinereus) to timber harvesting. PLoS One 13, e0205075.
Passive acoustics and sound recognition provide new insights on status and resilience of an iconic endangered marsupial (koala Phascolarctos cinereus) to timber harvesting.Crossref | GoogleScholarGoogle Scholar | 30379836PubMed |

Law, B., Gonsalves, L., Bilney, R., Peterie, J., Pietsch, R., Roe, P., and Truskinger, A. (2020). Using passive acoustic recording and automated call identification to survey koalas in the southern forests of New South Wales. Australian Zoologist 40, 477–486.
Using passive acoustic recording and automated call identification to survey koalas in the southern forests of New South Wales.Crossref | GoogleScholarGoogle Scholar |

Legge, S., Robinson, N., Lindenmayer, D., Scheele, B., Southwell, D., and Wintle, B. (2018). ‘Monitoring Threatened Species and Ecological Communities.’ (CSIRO Publishing: Melbourne, Vic., Australia.)

Leigh, C., Heron, G., Wilson, E., Gregory, T., Clifford, S., Holloway, J., McBain, M., Gonzalez, F., McGree, J., and Brown, R. (2019). Using virtual reality and thermal imagery to improve statistical modelling of vulnerable and protected species. PLoS One 14, e0217809.
Using virtual reality and thermal imagery to improve statistical modelling of vulnerable and protected species.Crossref | GoogleScholarGoogle Scholar | 31825957PubMed |

Lucas, C., Hennessy, K., Mills, G., and Bathols, J. (2007). Bushfire weather in southeast Australia: recent trends and projected climate change impacts. Consultancy report prepared for the Climate Institute of Australia by the Bushfire Cooperative Research Centre. Available at https://publications.csiro.au/rpr/pub?list=BRO&pid=procite:5910842c-f62e-4006-b88f-1055d8e981fa.

Lunney, D., Phillips, S., Callaghan, J., and Coburn, D. (1998). Determining the distribution of koala habitat across a shire as a basis for conservation: a case study from Port Stephens, New South Wales. Pacific Conservation Biology 4, 186–196.
Determining the distribution of koala habitat across a shire as a basis for conservation: a case study from Port Stephens, New South Wales.Crossref | GoogleScholarGoogle Scholar |

Markwell, K. (2020). Getting close to a national icon: an examination of the involvement of the koala (Phascolarctos cinereus) in Australian tourism. Tourism Recreation Research 46, 473–486.

McAlpine, C., Lunney, D., Melzer, A., Menkhorst, P., Phillips, S., Phalen, D., Ellis, W., Foley, W., Baxter, G., De Villiers, D., Kavanagh, R., Adams-Hosking, C., Todd, C., Whisson, D., Molsher, R., Walter, M., Lawler, I., and Close, R. (2015). Conserving koalas: a review of the contrasting regional trends, outlooks and policy challenges. Biological Conservation 192, 226–236.
Conserving koalas: a review of the contrasting regional trends, outlooks and policy challenges.Crossref | GoogleScholarGoogle Scholar |

Nolan, R. H., Boer, M. M., Collins, L., Resco de Dios, V., Clarke, H., Jenkins, M., Kenny, B., and Bradstock, R. A. (2020). Causes and consequences of eastern Australia’s 2019–20 season of mega‐fires. Global Change Biology 26, 1039–1041.
Causes and consequences of eastern Australia’s 2019–20 season of mega‐fires.Crossref | GoogleScholarGoogle Scholar | 31916352PubMed |

NSW Legislative Council (2020). Koala populations and habitat in New South Wales/Portfolio Committee No. 7 – Planning and Environment. Sydney, NSW, Australia. Available at https://www.parliament.nsw.gov.au/lcdocs/inquiries/2536/Koala%20populations%20and%20habitat%20in%20New%20South%20Wales%20-%20Report%203.pdf.

Office of Environment and Heritage (2018). NSW Koala Strategy. Available at https://www.environment.nsw.gov.au/research-and-publications/publications-search/nsw-koala-strategy.

Perkins, G. C., Kutt, A. S., Vanderduys, E. P., and Perry, J. J. (2013). Evaluating the costs and sampling adequacy of a vertebrate monitoring program. Australian Zoologist 36, 373–380.
Evaluating the costs and sampling adequacy of a vertebrate monitoring program.Crossref | GoogleScholarGoogle Scholar |

Phillips, S. (2018). Kings Hill, Tomago and Medowie Koala Hub Assessment: draft report to Port Stephens Council. Uki, NSW, Australia.

Phillips, S., and Callaghan, J. (2011). The Spot Assessment Technique: a tool for determining localised levels of habitat use by koalas Phascolarctos cinereus. Australian Zoologist 35, 774–780.
The Spot Assessment Technique: a tool for determining localised levels of habitat use by koalas Phascolarctos cinereus.Crossref | GoogleScholarGoogle Scholar |

Phillips, S., and Callaghan, J. (2014). What faecal pellet surveys can and can’t reveal about the ecology of koalas Phascolarctos cinereus II: an interim response to Woosnam–Merchez et al. (2013). Available at https://www.biolink.com.au/sites/www.biolink.com.au/files/publications/Response%20to% 20Woosnam-Merchez.pdf.

Phillips, S., Hopkins, M., and Callaghan, J. (2007). Koala Habitat and Population Assessment for the Gold Coast City LGA: final report to Gold Coast City Council. Uki, NSW, Australia.

Reed, P., Lunney, D., and Walker, P. 1990. Survey of the koala Phascolarctos cinereus (Goldfuss) in New South Wales (1986–87), with an ecological interpretation of its distribution. In ‘Biology of the Koala’. (Eds A. K. Lee, K. A. Handasyde, and G. D. Sanson.) pp. 55–74. (Surrey Beatty: Sydney, NSW, Australia.)

Rhodes, J. R., Tyre, A. J., Jonzén, N., McAlpine, C. A., and Possingham, H. P. (2006). Optimizing presence–absence surveys for detecting population trends. The Journal of Wildlife Management 70, 8–18.
Optimizing presence–absence surveys for detecting population trends.Crossref | GoogleScholarGoogle Scholar |

Rhodes, J., Hood, A., Alistair, M., and Mucci, A. (2017). Queensland Koala Expert Panel: a new direction for the conservation of koalas in Queensland. A report to the Minister for Environment and Heritage Protection. Available at https://environment.des.qld.gov.au/__data/assets/pdf_file/0031/88582/qld-koala-expert-panel-report-2017.pdf.

Tisdell, C., and Nantha, H. S. (2006). Comparison of funding and demand for the conservation of the charismatic koala with those for the critically endangered wombat Lasiorhinus krefftii. In ‘Vertebrate Conservation and Biodiversity’. (Eds D. L. Hawksworth, and A. T. Bull.) pp. 435–455. (Springer.)

Wilmott, L., Cullen, D., Madani, G., Krogh, M., and Madden, K. (2019). Are koalas detected more effectively by systematic spotlighting or diurnal searches? Australian Mammalogy 41, 157–160.
Are koalas detected more effectively by systematic spotlighting or diurnal searches?Crossref | GoogleScholarGoogle Scholar |

Wintle, B. A., Cadenhead, N. C. R., Morgain, R. A., Legge, S. M., Bekessy, S. A., Cantele, M., Possingham, H. P., Watson, J. E. M., Maron, M., and Keith, D. A. (2019). Spending to save: what will it cost to halt Australia’s extinction crisis? Conservation Letters 12, e12682.
Spending to save: what will it cost to halt Australia’s extinction crisis?Crossref | GoogleScholarGoogle Scholar |

Witt, R. R., Beranek, C. T., Howell, L. G., Ryan, S. A., Clulow, J., Jordan, N. R., Denholm, B., and Roff, A. (2020). Real-time drone derived thermal imagery outperforms traditional survey methods for an arboreal forest mammal. PLoS One 15, e0242204.
Real-time drone derived thermal imagery outperforms traditional survey methods for an arboreal forest mammal.Crossref | GoogleScholarGoogle Scholar | 33196649PubMed |

Woinarski, J. C. Z. (2018). A framework for evaluating the adequacy of monitoring programs for threatened species. In ‘Monitoring Threatened Species and Ecological Communities’. pp. 13–20. (CSIRO Publishing: Melbourne, Vic., Australia.)

Woinarski, J., and Burbidge, A. A. (2016). Phascolarctos cinereus. The IUCN Red List of Threatened Species 2016:e T16892A21960344.

Woinarski, J. C. Z., Burbidge, A. A., and Harrison, P. L. (2018). The extent and adequacy of monitoring for Australian threatened mammal species. In ‘Monitoring Threatened Species and Ecological Communities’. pp. 21–42. (CSIRO Publishing: Melbourne, Vic., Australia.)