Quantifying and reducing epistemic uncertainty of passive acoustic telemetry data from longitudinal aquatic systems

Passive acoustic telemetry data are used to study animal movement in aquatic environments, but tools to process the data are limited. In areas that are too large to be fully covered by the limited detection ranges of receivers or acoustic listening stations, researchers generally assume that animals...

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Bibliographic Details
Published in:Ecological Informatics
Main Authors: Bruneel, Stijn, Verhelst, Pieterjan, Reubens, Jan, Baetens, Jan, Coeck, Johan, Moens, Tom, Goethals, Peter
Format: Article in Journal/Newspaper
Language:English
Published: 2020
Subjects:
Earth and Environmental Sciences
Ecological Modelling
Ecology
Modelling and Simulation
Computational Theory and Mathematics
Applied Mathematics
Evolution
Behavior and Systematics
Computer Science Applications
Epistemic uncertainty
Estuary
Fish
Gates
Network design
Passive acoustic telemetry curtains
ANGUILLA-ANGUILLA
DETECTION RANGE
RESIDENCE TIME
DESIGN
POSITIONS
BEHAVIOR
ANIMALS
ARRAY
Anguilla anguilla
Online Access:https://biblio.ugent.be/publication/8669225
http://hdl.handle.net/1854/LU-8669225
https://doi.org/10.1016/j.ecoinf.2020.101133
https://biblio.ugent.be/publication/8669225/file/8669226
Description
Summary:Passive acoustic telemetry data are used to study animal movement in aquatic environments, but tools to process the data are limited. In areas that are too large to be fully covered by the limited detection ranges of receivers or acoustic listening stations, researchers generally assume that animals are residing in an area when they are detected frequently at specific receivers. There is, however, no consensus on how this area and frequency should be spatially and temporally defined respectively, thereby introducing some unaccounted uncertainty of this residency-at-receivers. In longitudinal aquatic systems such as rivers or estuaries, strategically placed receivers are often used as gates or curtains through which tagged animals have to pass. Rather than being a proxy for the time spent near receivers, the detections can serve as boundary conditions to delineate the durations that animals spent between receivers (i.e. residency-between-receivers). As such, providing a spatial and temporal context to the detections and enabling the quantification of epistemic uncertainty. To assess the usefulness of this approach, we analyzed telemetry data for migrating eel in a longitudinal estuarine acoustic tracking network of 21 gates. Results revealed a logarithmic relationship between epistemic uncertainty and gate network resolution, which indicates that transferring information from the spatial to the temporal level has a positive effect on the epistemic uncertainty. The poor correlation between the at-receivers and the between-receivers approach indicates that the latter, although less precise, may be more accurate. It should be noted that the suggested approach assumes that the gates of receivers are perfect detectors. If tagged animals are able to pass these gates undetected the uncertainty will actually be higher than assumed. Our approach is therefore less suited for large open areas such as lagoons or seas where gates with high detection probabilities are logistically challenging. This approach allows the ...

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