Spatial confounding in Bayesian species distribution modeling

Species distribution models (SDMs) are currently the main tools to derive species niche estimates and spatially explicit predictions for species geographical distribution. However, unobserved environmental conditions and ecological processes may confound the model estimates if they have a direct imp...

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Bibliographic Details
Main Authors: Mäkinen, Jussi, Numminen, Elina, Niittynen, Pekka, Luoto, Miska, Vanhatalo, Jarno
Format: Other/Unknown Material
Language:unknown
Published: Zenodo 2022
Subjects:
estimation bias
Gaussian process
spatial confounfing
spatial random effect
Species distribution model
Northern Norway
Online Access:https://doi.org/10.5061/dryad.hdr7sqvm5
Description
Summary:Species distribution models (SDMs) are currently the main tools to derive species niche estimates and spatially explicit predictions for species geographical distribution. However, unobserved environmental conditions and ecological processes may confound the model estimates if they have a direct impact on the species and, at the same time, they are correlated with the observed environmental covariates. This, so-called spatial confounding, is a general property of spatial models but it has not been studied in the context of SDMs before. Here we examine how the estimation accuracy of SDMs depends on the type of spatial confounding. We construct two simulation studies where we alter spatial structures of the observed and unobserved covariates and the level of dependence between them. We fit generalized linear models with and without spatial random effects applying Bayesian inference and record the bias induced to model estimates by spatial confounding. After this, we examine spatial confounding also with real vegetation data from northern Norway. Our results show that model estimates for coarse-scale covariates, such as climate covariates, are likely to be biased if a species distribution depends also on an unobserved covariate operating on a finer spatial scale. Pushing higher probability for a relatively weak and spatially smoothly varying spatial random effect compared to the observed covariates improved estimation accuracy. The improvement was independent of the actual spatial structure of the unobserved covariate. Our study addresses the major factors of spatial confounding in SDMs and provides a list of recommendations for pre-inference assessment of spatial confounding and for inference-based methods to decrease the chance of biased model estimates. Matlab Funding provided by: Academy of Finland Crossref Funder Registry ID: http://dx.doi.org/10.13039/501100002341 Award Number: 317255 Funding provided by: Jane ja Aatos Erkon Säätiö Crossref Funder Registry ID: http://dx.doi.org/10.13039/501100004012 Award ...

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