Data from: Hide and seek in vegetation: time-to-detection is an efficient design for estimating detectability and occurrence
Bornand, Christophe N., University of Bern
Kéry, Marc, Swiss Ornithological Institute
Bueche, Lena, University of Bern
Fischer, Markus, University of Bern
Published Jan 13, 2015 on Dryad.
Cite this dataset
Bornand, Christophe N.; Kéry, Marc; Bueche, Lena; Fischer, Markus (2015). Data from: Hide and seek in vegetation: time-to-detection is an efficient design for estimating detectability and occurrence [Dataset]. Dryad. https://doi.org/10.5061/dryad.v2c17
1. Ecology and conservation require reliable data on the occurrence of animals and plants. A major source of bias is imperfect detection, which, however, can be corrected for by estimation of detectability. In traditional occupancy models, this requires repeat or multi-observer surveys. Recently, time-to-detection models have been developed as a cost-effective alternative, which requires no repeat surveys and hence costs could be halved. 2. We compared the efficiency and reliability of time-to-detection and traditional occupancy models under varying survey effort. Two observers independently searched for 17 plant species in 44 100 m2 Swiss grassland quadrats and recorded the time-to-detection for each species, enabling detectability to be estimated with both time-to-detection and traditional occupancy models. In addition, we gauged the relative influence on detectability of species, observer, plant height and two measures of abundance (cover and frequency). 3.Estimates of detectability and occupancy under both models were very similar. Rare species were more likely to be overlooked; detectability was strongly affected by abundance. As a measure of abundance, frequency outperformed cover in its predictive power. The two observers differed significantly in their detection ability. 4. Time-to-detection models were as accurate as traditional occupancy models, but their data easier to obtain; thus they provide a cost-effective alternative to traditional occupancy models for detection-corrected estimation of occurrence.
Data used in the hierarchical multispecies occupancy model with detection/non-detection data in the BUGS language
Data used in the hierarchical multispecies time-to-detection occupancy model in the BUGS language