TY - JOUR
T1 - Empirical modelling of benthic species distribution, abundance, and diversity in the Baltic Sea: evaluating the scope for predictive mapping using different modelling approaches
AU - Bucas, M
AU - Bergstrom, U
AU - Downie, AL
AU - Sundblad, G
AU - Gullstrom, M
AU - von Numers, Mikael
AU - Siaulys, A
AU - Lindegarth, M
PY - 2013
Y1 - 2013
N2 - The predictive performance of distribution models of common benthic species in the Baltic Sea was compared using four non-linear methods: generalized additive models (GAMs), multivariate adaptive regression splines, random forest (RF), and maximum entropy modelling (MAXENT). The effects of data traits were also tested. In total, 292 occurrence models and 204 quantitative (abundance and diversity) models were assessed. The main conclusions are that (i) the spatial distribution, abundance, and diversity of benthic species in the Baltic Sea can be successfully predicted using several non-linear predictive modelling techniques; (ii) RF was the most accurate method for both models, closely followed by GAM and MAXENT; (iii) correlation coefficients of predictive performance among the modelling techniques were relatively low, suggesting that the performance of methods is related to specific responses; (iv) the differences in predictive performance among the modelling methods could only partly be explained by data traits; (v) the response prevalence was the most important explanatory variable for predictive accuracy of GAM and MAXENT on occurrence data; (vi) RF on the occurrence data was the only method sensitive to sampling density; (vii) a higher predictive accuracy of abundance models could be achieved by reducing variance in the response data and increasing the sample size.
AB - The predictive performance of distribution models of common benthic species in the Baltic Sea was compared using four non-linear methods: generalized additive models (GAMs), multivariate adaptive regression splines, random forest (RF), and maximum entropy modelling (MAXENT). The effects of data traits were also tested. In total, 292 occurrence models and 204 quantitative (abundance and diversity) models were assessed. The main conclusions are that (i) the spatial distribution, abundance, and diversity of benthic species in the Baltic Sea can be successfully predicted using several non-linear predictive modelling techniques; (ii) RF was the most accurate method for both models, closely followed by GAM and MAXENT; (iii) correlation coefficients of predictive performance among the modelling techniques were relatively low, suggesting that the performance of methods is related to specific responses; (iv) the differences in predictive performance among the modelling methods could only partly be explained by data traits; (v) the response prevalence was the most important explanatory variable for predictive accuracy of GAM and MAXENT on occurrence data; (vi) RF on the occurrence data was the only method sensitive to sampling density; (vii) a higher predictive accuracy of abundance models could be achieved by reducing variance in the response data and increasing the sample size.
KW - generalized additive models
KW - habitat suitability models
KW - marine benthic ecosystems
KW - maximum entropy modelling
KW - multivariate adaptive regression splines
KW - niche modelling
KW - prevalence and sampling density
KW - random forest
KW - species distribution modelling
KW - variance in the response data and sample size
KW - generalized additive models
KW - habitat suitability models
KW - marine benthic ecosystems
KW - maximum entropy modelling
KW - multivariate adaptive regression splines
KW - niche modelling
KW - prevalence and sampling density
KW - random forest
KW - species distribution modelling
KW - variance in the response data and sample size
KW - generalized additive models
KW - habitat suitability models
KW - marine benthic ecosystems
KW - maximum entropy modelling
KW - multivariate adaptive regression splines
KW - niche modelling
KW - prevalence and sampling density
KW - random forest
KW - species distribution modelling
KW - variance in the response data and sample size
U2 - 10.1093/icesjms/fst036
DO - 10.1093/icesjms/fst036
M3 - Artikel
SN - 1054-3139
VL - 70
SP - 1233
EP - 1243
JO - ICES Journal of Marine Science
JF - ICES Journal of Marine Science
IS - 6
ER -