Towards meaningful monitoring: A case study of a threatened rodent

Detecting trends in species’ distribution and abundance are essential for conserving threatened species, and depend upon effective monitoring programmes. Despite this, monitoring programmes are often designed without explicit consideration of their ability to deliver the information required by mana...

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Bibliographic Details
Published in:Austral ecology 2019-04, Vol.44 (2), p.223-236
Main Authors: Geyle, Hayley M., Guillera‐Arroita, Gurutzeta, Davies, Hugh F., Firth, Ronald S. C., Murphy, Brett P., Nimmo, Dale G., Ritchie, Euan G., Woinarski, John C. Z., Nicholson, Emily
Format: Article
Language:English
Subjects:
Animal models
Case studies
Change detection
Conilurus penicillatus
Dry season
Ecological monitoring
Endangered & extinct species
imperfect detection
Information management
Landscape
Monitoring
Occupancy
optimal monitoring
Polls & surveys
Population changes
Seasons
Statistical power
Threatened species
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Summary:Detecting trends in species’ distribution and abundance are essential for conserving threatened species, and depend upon effective monitoring programmes. Despite this, monitoring programmes are often designed without explicit consideration of their ability to deliver the information required by managers, such as their power to detect population changes. Here, we demonstrate the use of existing data to support the design of monitoring programmes aimed at detecting declines in species occupancy. We used single‐season occupancy models and baseline data to gain information on variables affecting the occupancy and detectability of the threatened brush‐tailed rabbit‐rat Conilurus penicillatus (Gould 1842) on the Tiwi Islands, Australia. This information was then used to estimate the survey effort required to achieve sufficient power to detect changes in occupancy of different magnitudes. We found that occupancy varied spatially, driven primarily by habitat (canopy height and cover, distance to water) and fire history across the landscape. Detectability varied strongly among seasons, and was three times higher in the late dry season (July–September), compared to the early dry season (April–June). Evaluation of three monitoring scenarios showed that conducting surveys at times when detectability is highest can lead to a substantial improvement in our ability to detect declines, thus reducing the survey effort and costs. Our study highlights the need for careful consideration of survey design related to the ecology of a species, as it can lead to substantial cost savings and improved insight into species population change via monitoring.
ISSN:1442-9985
1442-9993
DOI:10.1111/aec.12667