Published October 6, 2022 | Version v1

spectre: An R package to estimate spatially-explicit community composition using sparse data

  • 1. University of Auckland
  • 2. University of Göttingen
  • 3. University of Michigan-Ann Arbor

Description

An understanding of how biodiversity is distributed across space is key to much of ecology and conservation. Many predictive modelling approaches have been developed to estimate the distribution of biodiversity over various spatial scales. Community modelling techniques may offer many benefits over single-species modelling. However, techniques capable of estimating precise species makeups of communities are highly data intensive and thus often limited in their applicability. Here we present an R package, spectre, which can predict regional community composition at a fine spatial resolution using only sparsely sampled biological data. The package can predict the presence and absence of all species in an area, both known and unknown, at the sample site scale. Underlying the spectre package is a min-conflicts optimisation algorithm that predicts species' presences and absences throughout an area using estimates of α-, β-, and γ-diversity. We demonstrate the utility of the spectre package using a spatially-explicit simulated ecosystem to assess the accuracy of the package's results. spectre offers a simple-to-use tool with which to accurately predict community compositions across varying scales, facilitating further research and knowledge acquisition into this fundamental aspect of ecology.

Notes

The data is stored here in .RDS format and as such can be directly loaded into any R environment using the `readRDS()` function. Additionally, the data can be recreated and fully re-analysed by accessing it via the spectre usecase GitHub repo https://github.com/r-spatialecology/spectre_usecase.

Funding provided by: Deutsche Forschungsgemeinschaft
Crossref Funder Registry ID: http://dx.doi.org/10.13039/501100001659
Award Number: 192626868 – SFB 990

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