Abstract
Biodiversity conservation requires modeling tools capable of predicting the presence or absence (i.e., occurrence‐state) of species in habitat patches. Local habitat characteristics of a patch (lh), the cost of traversing the landscape matrix between patches (weighted connectivity [wc]), and the position of the patch in the habitat network topology (nt) all influence occurrence‐state. Existing models are data demanding or consider only local habitat characteristics. We address these shortcomings and present a network‐based modeling approach, which aims to predict species occurrence‐state in habitat patches using readily available presence‐only records.For the tree frog Hyla arborea in the Swiss Plateau, we delineated habitat network nodes from an ensemble habitat suitability model and used different cost surfaces to generate the edges of three networks: one limited only by dispersal distance (Uniform), another incorporating traffic, and a third based on inverse habitat suitability. For each network, we calculated explanatory variables representing the three categories (lh, wc, and nt). The response variable, occurrence‐state, was parametrized by a sampling intensity procedure assessing observations of comparable species over a threshold of patch visits. The explanatory variables from the three networks and an additional non‐topological model were related to the response variable with boosted regression trees.The habitat network models had a similar fit; they all outperformed the non‐topological model. Habitat suitability index (lh) was the most important predictor in all networks, followed by third‐order neighborhood (nt). Patch size (lh) was unimportant in all three networks.We found that topological variables of habitat networks are relevant for the prediction of species occurrence‐state, a step‐forward from models considering only local habitat characteristics. For any habitat patch, occurrence‐state is most prominently influenced by its habitat suitability and then by the number of patches in a wide neighborhood. Our approach is generic and can be applied to multiple species in different habitats.
Highlights
Knowledge about the spatial distribution of species is a key element for any conservation effort
For the tree frog Hyla arborea in the Swiss Plateau, we delineated habitat network nodes from an ensemble habitat suitability model and used different cost surfaces to generate the edges of three networks: one limited only by dispersal distance (Uniform), another incorporating traffic, and a third based on inverse habitat suit‐ ability
We found that topological variables of habitat networks are relevant for the prediction of species occurrence‐state, a step‐forward from models consider‐ ing only local habitat characteristics
Summary
Knowledge about the spatial distribution of species is a key element for any conservation effort. To better capture the factors influencing the occurrence‐state of a species, and to be able to make predictions about this state, it is necessary to develop new modeling approaches that do consider the local conditions in a habitat patch, and the connectivity between patches This was the main goal of the present study. We defined the edges based on least‐cost calculations on different cost surfaces, which incorpo‐ rated different environmental, biological, and human influences on the landscape, generating three different networks From these networks, we calculated several variables quantifying the three cat‐ egories of factors (i.e., lh, wc, and nt) in Equation (1), which were used as explanatory variables in models that related them to the response variable occurrence‐state. By means of boosted regression trees (BRTs), we tested the explanatory power of predictor variables related to the three factors of Equation (1) on occurrence‐state
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