Editor: Gary Mittelbach
Performance of species richness estimators across assemblage types and survey parameters
Article first published online: 21 JAN 2014
© 2014 John Wiley & Sons Ltd
Global Ecology and Biogeography
Volume 23, Issue 5, pages 585–594, May 2014
How to Cite
Reese, G. C., Wilson, K. R. and Flather, C. H. (2014), Performance of species richness estimators across assemblage types and survey parameters. Global Ecology and Biogeography, 23: 585–594. doi: 10.1111/geb.12144
- Issue published online: 27 MAR 2014
- Article first published online: 21 JAN 2014
- community ecology;
- nonparametric estimator;
- sample coverage;
- selection framework;
A raw count of the species encountered across surveys usually underestimates species richness. Statistical estimators are often less biased. Nonparametric estimators of species richness are widely considered the least biased, but no particular estimator has consistently performed best. This is partly a function of estimators responding differently to assemblage-level factors and survey design parameters. Our objective was to evaluate the performance of raw counts and nonparametric estimators of species richness across various assemblages and with different survey designs.
We used both simulated and published field data.
We evaluated the bias, precision and accuracy of raw counts and 13 nonparametric estimators using simulations that systematically varied assemblage characteristics (number of species, species abundance distribution, total number of individuals, spatial configuration of individuals and species detection probability), sampling effort and survey design. Results informed the development of an estimator selection framework that we evaluated with field data.
When averaged across assemblages, most nonparametric estimators were less negatively biased than a raw count. Estimators based on the similarity of repeated subsets of surveys were most accurate and their accumulation curves appeared to reach asymptotes fastest. Number of species, species abundance distribution and effort had the largest effects on performance, ultimately by affecting the proportion of the species pool contained in a sample. Our estimator selection framework showed promising results when applied to field data.
A raw count of the number of species in an area is far from the best estimate of true species richness. Nonparametric estimators are less biased. Newer largely unused, estimators perform better than more well known and longer established counterparts under certain conditions. Given that there is generally a trade-off between bias and precision, we believe that estimator variance, which is often not reported when presenting species richness estimates, should always be included.