Within reach? Habitat availability as a function of individual mobility and spatial structuring

Organisms need access to particular habitats for their survival and reproduction. However, even if all necessary habitats are available within the broader environment, they may not all be easily reachable from the position of a single individual. Many species distribution models consider populations...

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Bibliographic Details
Published in:The American Naturalist
Main Authors: Matthiopoulos, Jason, Fieberg, John, Aarts, Geert, Barraquand, Frédéric, Kendall, Bruce E.
Format: Article in Journal/Newspaper
Language:English
Published: 2020
Subjects:
Conditional availability
Gaussian mixtures
Habitat selection
Resource selection
Species distribution modeling
Step-selection functions
harbor seal
Online Access:https://research.wur.nl/en/publications/within-reach-habitat-availability-as-a-function-of-individual-mob
https://doi.org/10.1086/708519
Description
Summary:Organisms need access to particular habitats for their survival and reproduction. However, even if all necessary habitats are available within the broader environment, they may not all be easily reachable from the position of a single individual. Many species distribution models consider populations in environmental (or niche) space, hence overlooking this fundamental aspect of geographical accessibility. Here, we develop a formal way of thinking about habitat availability in environmental spaces by describing how limitations in accessibility can cause animals to experience a more limited or simply different mixture of habitats than those more broadly available. We develop an analytical framework for characterizing constrained habitat availability based on the statistical properties of movement and environmental autocorrelation. Using simulation experiments, we show that our general statistical representation of constrained availability is a good approximation of habitat availability for particular realizations of landscape-organism interactions. We present two applications of our approach, one to the statistical analysis of habitat preference (using step-selection functions to analyze harbor seal telemetry data) and a second that derives theoretical insights about population viability from knowledge of the underlying environment. Analytical expressions for habitat availability, such as those we develop here, can yield gains in analytical speed, biological realism, and conceptual generality by allowing us to formulate models that are habitat sensitive without needing to be spatially explicit.

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