Incorporating landscape stochasticity into population viability analysis

The importance of incorporating landscape dynamics into population viability analysis (PVA) has previously been acknowledged, but the need to repeat the landscape generation process to encapsulate landscape stochasticity in model outputs has largely been overlooked. Reasons for this are that (1) the...

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Bibliographic Details
Published inEcological applications Vol. 17; no. 2; pp. 317 - 322
Main Authors Chisholm, R.A, Wintle, B.A
Format Journal Article
LanguageEnglish
Published United States 01.03.2007
Subjects
animal ecology
Animals
Certhia americana
computer software
DLMP model
dynamic landscape metapopulation model
Ecosystem
Environmental Monitoring - methods
landscapes
Passeriformes - physiology
Population Dynamics
population ecology
population viability analysis
Software
Stochastic Processes
wild birds
wildlife management
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Summary:The importance of incorporating landscape dynamics into population viability analysis (PVA) has previously been acknowledged, but the need to repeat the landscape generation process to encapsulate landscape stochasticity in model outputs has largely been overlooked. Reasons for this are that (1) there is presently no means for quantifying the relative effects of landscape stochasticity and population stochasticity on model outputs, and therefore no means for determining how to allocate simulation time optimally between the two; and (2) the process of generating multiple landscapes to incorporate landscape stochasticity is tedious and user-intensive with current PVA software. Here we demonstrate that landscape stochasticity can be an important source of variance in model outputs. We solve the technical problems with incorporating landscape stochasticity by deriving a formula that gives the optimal ratio of population simulations to landscape simulations for a given model, and by providing a computer program that incorporates the formula and automates multiple landscape generation in a dynamic landscape metapopulation (DLMP) model. Using a case study of a bird population, we produce estimates of DLMP model output parameters that are up to four times more precise than those estimated from a single landscape in the same amount of total simulation time. We use the DLMP modeling software RAMAS Landscape to run the landscape and metapopulation models, though our method is general and could be applied to any PVA platform. The results of this study should motivate DLMP modelers to consider landscape stochasticity in their analyses.
ISSN:1051-0761
1939-5582
DOI:10.1890/05-1580