Your search keyword '"Zarzo-Arias, Alejandra"' showing total 2 results

1. Species distribution models affected by positional uncertainty in species occurrences can still be ecologically interpretable.

Author

Gábor, Lukáš, Jetz, Walter, Zarzo‐Arias, Alejandra, Winner, Kevin, Yanco, Scott, Pinkert, Stefan, Marsh, Charles J., Rogan, Matthew S., Mäkinen, Jussi, Rocchini, Duccio, Barták, Vojtěch, Malavasi, Marco, Balej, Petr, and Moudrý, Vítězslav

Subjects

SPECIES distribution, INDEPENDENT variables, BIODIVERSITY monitoring, BIODIVERSITY conservation, REAL variables

Abstract

Species distribution models (SDMs) have become a common tool in studies of species–environment relationships but can be negatively affected by positional uncertainty of underlying species occurrence data. Previous work has documented the effect of positional uncertainty on model predictive performance, but its consequences for inference about species–environment relationships remain largely unknown. Here we use over 12 000 combinations of virtual and real environmental variables and virtual species, as well as a real case study, to investigate how accurately SDMs can recover species–environment relationships after applying known positional errors to species occurrence data. We explored a range of environmental predictors with various spatial heterogeneity, species' niche widths, sample sizes and magnitudes of positional error. Positional uncertainty decreased predictive model performance for all modeled scenarios. The absolute and relative importance of environmental predictors and the shape of species–environmental relationships co‐varied with a level of positional uncertainty. These differences were much weaker than those observed for overall model performance, especially for homogenous predictor variables. This suggests that, at least for the example species and conditions analyzed, the negative consequences of positional uncertainty on model performance did not extend as strongly to the ecological interpretability of the models. Although the findings are encouraging for practitioners using SDMs to reveal generative mechanisms based on spatially uncertain data, they suggest greater consequences for applications utilizing distributions predicted from SDMs using positionally uncertain data, such as conservation prioritization and biodiversity monitoring. [ABSTRACT FROM AUTHOR]

Published

2023

2. Scale mismatches between predictor and response variables in species distribution modelling: A review of practices for appropriate grain selection.

Author

Moudrý, Vítězslav, Keil, Petr, Gábor, Lukáš, Lecours, Vincent, Zarzo-Arias, Alejandra, Barták, Vojtěch, Malavasi, Marco, Rocchini, Duccio, Torresani, Michele, Gdulová, Kateřina, Grattarola, Florencia, Leroy, François, Marchetto, Elisa, Thouverai, Elisa, Prošek, Jiří, Wild, Jan, and Šímová, Petra

Subjects

INDEPENDENT variables, SPECIES distribution, GRAIN, LAND cover, GRAIN size

Abstract

There is a lack of guidance on the choice of the spatial grain of predictor and response variables in species distribution models (SDM). This review summarizes the current state of the art with regard to the following points: (i) the effects of changing the resolution of predictor and response variables on model performance; (ii) the effect of conducting multi-grain versus single-grain analysis on model performance; and (iii) the role of land cover type and spatial autocorrelation in selecting the appropriate grain size. In the reviewed literature, we found that coarsening the resolution of the response variable typically leads to declining model performance. Therefore, we recommend aiming for finer resolutions unless there is a reason to do otherwise (e.g. expert knowledge of the ecological scale). We also found that so far, the improvements in model performance reported for multi-grain models have been relatively low and that useful predictions can be generated even from single-scale models. In addition, the use of high-resolution predictors improves model performance; however, there is only limited evidence on whether this applies to models with coarser-resolution response variables (e.g. 100 km2 and coarser). Low-resolution predictors are usually sufficient for species associated with fairly common environmental conditions but not for species associated with less common ones (e.g. common vs rare land cover category). This is because coarsening the resolution reduces variability within heterogeneous predictors and leads to underrepresentation of rare environments, which can lead to a decrease in model performance. Thus, assessing the spatial autocorrelation of the predictors at multiple grains can provide insights into the impacts of coarsening their resolution on model performance. Overall, we observed a lack of studies examining the simultaneous manipulation of the resolution of predictor and response variables. We stress the need to explicitly report the resolution of all predictor and response variables. [ABSTRACT FROM AUTHOR]

Published

2023