Social network models predict movement and connectivity in ecological landscapes

Network analysis is on the rise across scientific disciplines because of its ability to reveal complex, and often emergent, patterns and dynamics. Nonetheless, a growing concern in network analysis is the use of limited data for constructing networks. This concern is strikingly relevant to ecology a...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2011-11, Vol.108 (48), p.19282-19287
Main Authors: Fletcher, Robert J. Jr, Acevedo, Miguel A, Reichert, Brian E, Pias, Kyle E, Kitchens, Wiley M
Format: Article
Language:English
Subjects:
Animals
Biological Sciences
Connectivity
Conservation
Conservation biology
Conservation of Natural Resources - methods
Ecological modeling
Ecology
Ecology - methods
Ecosystem
Florida
Habitat conservation
Hemiptera - physiology
Landscape
Landscape ecology
Landscapes
Mathematical models
Metapopulation ecology
metapopulations
Modeling
Models, Biological
Movement - physiology
Network analysis
Opuntia
Social networking
Social networks
Social Support
Statistical analysis
statistical models
wildlife management
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Summary:Network analysis is on the rise across scientific disciplines because of its ability to reveal complex, and often emergent, patterns and dynamics. Nonetheless, a growing concern in network analysis is the use of limited data for constructing networks. This concern is strikingly relevant to ecology and conservation biology, where network analysis is used to infer connectivity across landscapes. In this context, movement among patches is the crucial parameter for interpreting connectivity but because of the difficulty of collecting reliable movement data, most network analysis proceeds with only indirect information on movement across landscapes rather than using observed movement to construct networks. Statistical models developed for social networks provide promising alternatives for landscape network construction because they can leverage limited movement information to predict linkages. Using two mark-recapture datasets on individual movement and connectivity across landscapes, we test whether commonly used network constructions for interpreting connectivity can predict actual linkages and network structure, and we contrast these approaches to social network models. We find that currently applied network constructions for assessing connectivity consistently, and substantially, overpredict actual connectivity, resulting in considerable overestimation of metapopulation lifetime. Furthermore, social network models provide accurate predictions of network structure, and can do so with remarkably limited data on movement. Social network models offer a flexible and powerful way for not only understanding the factors influencing connectivity but also for providing more reliable estimates of connectivity and metapopulation persistence in the face of limited data.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1107549108