Spatial scales of habitat selection decisions: implications for telemetry-based movement modeling

Movement influences a myriad of ecological processes operating at multiple spatial and temporal scales. Yet our understanding of animal movement is limited by the resolution of data that can be obtained from individuals. Traditional approaches implicitly assume that movement decisions are made at th...

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Bibliographic Details
Main Authors: Guillaume Bastille-Rousseau, Dennis L. Murray, James A. Schaefer, Mark A. Lewis, Shane P. Mahoney, Jonathan R. Potts
Format: Other/Unknown Material
Language:English
Published: 2017
Subjects:
telemetry-based movement
Canada
caribou
Newfoundland
Rangifer tarandus
Online Access:https://era.library.ualberta.ca/items/66b9b7ce-1d03-45e2-a236-8347fa1874a0
https://doi.org/10.7939/r3-9hqm-y691
Description
Summary:Movement influences a myriad of ecological processes operating at multiple spatial and temporal scales. Yet our understanding of animal movement is limited by the resolution of data that can be obtained from individuals. Traditional approaches implicitly assume that movement decisions are made at the spatial and temporal scales of observation, although this scale is typically an artifact of data-gathering technology rather than biological realism. To address this limitation, we used telemetry-based movement data for caribou Rangifer tarandus in Newfoundland, Canada, and compared movement decisions estimated at the temporal resolution of GPS relocations (2 h) to a novel model describing directional movement to areas reachable over an extended period. We showed that this newer model is a better predictor of movement decisions by caribou, with decisions made at the scale of ∼2 km, including the strong avoidance of dense coniferous forest, an outcome not detectable at the scale of GPS relocations. These results illustrate the complexity of factors affecting animal movement decisions and the analytical challenges associated with their interpretation. Our novel modelling framework will help support increased accuracy in predictive models of animal spaceuse, and thereby aid in determining biologically meaningful scales for collecting movement and habitat data.

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