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References (36)
-
W. Thuiller (2004)
Patterns and uncertainties of species' range shifts under climate changeGlobal Change Biology, 10
-
N. Raes, H. Steege (2007)
A null‐model for significance testing of presence‐only species distribution modelsEcography, 30
-
J. Frey, M. Bogan, T. Yates (2007)
Mountaintop island age determines species richness of boreal mammals in the American SouthwestEcography, 30
-
J. Badsberg (2001)
A Guide to CoCoJournal of Statistical Software, 006
-
O. Broennimann, A. Guisan (2008)
Predicting current and future biological invasions: both native and invaded ranges matterBiology Letters, 4
-
M. Araújo, A. Guisan (2006)
Five (or so) challenges for species distribution modellingJournal of Biogeography, 33
-
Steven Phillips, R. Anderson, R. Schapire (2006)
Maximum entropy modeling of species geographic distributionsEcological Modelling, 190
-
J. Elith, Catherine Graham, Robert Anderson, Miroslav Dudı́k, Simon Ferrier, A. Guisan, R. Hijmans, F. Huettmann, J. Leathwick, Anthony Lehmann, Jin Li, Lúcia Lohmann, Bette Loiselle, G. Manion, Craig Moritz, Miguel Nakamura, Yoshinori Nakazawa, J. Overton, A. Peterson, Steven Phillips, Karen Richardson, R. Scachetti-Pereira, R. Schapire, Jorge Soberón, Stephen Williams, M. Wisz, N. Zimmermann (2006)
Novel methods improve prediction of species' distributions from occurrence dataEcography, 29
-
Hutchinson Hutchinson (1957)
Concluding remarksCold Spring Harbor Symposia on Quantitative Biology, 22
-
C. Graham, C. Graham, S. Ferrier, Falk Huettman, C. Moritz, A. Peterson (2004)
New developments in museum-based informatics and applications in biodiversity analysis.Trends in ecology & evolution, 19 9
-
(2002)
Controlling bias in biodiversity data -
C. Graham, S. Ron, Juan Santos, C. Schneider, C. Moritz (2004)
INTEGRATING PHYLOGENETICS AND ENVIRONMENTAL NICHE MODELS TO EXPLORE SPECIATION MECHANISMS IN DENDROBATID FROGS, 58
-
R. Anderson, D. Lew, A. Peterson (2003)
Evaluating predictive models of species’ distributions: criteria for selecting optimal modelsEcological Modelling, 162
-
G. Mulligan (1979)
The biology of Canadian weeds -
A. Baddeley, Rolf Turner (2005)
spatstat: An R Package for Analyzing Spatial Point PatternsJournal of Statistical Software, 12
-
N. Gotelli (2003)
Predicting Species Occurrences: Issues of Accuracy and Scale, 120
-
A. Estrada-Peña, Rupert Pegram, Nicolas Barré, J. Venzal (2007)
Using invaded range data to model the climate suitability for Amblyomma variegatum (Acari: Ixodidae) in the New WorldExperimental and Applied Acarology, 41
-
Hijmans Hijmans, Cameron Cameron, Parra Parra, Jones Jones, Jarvis Jarvis (2005)
Very high resolution interpolated climate surfaces for global land areasInternational Journal of Climatology, 25
-
Steven Phillips, Miroslav Dudík, J. Elith, C. Graham, A. Lehmann, J. Leathwick, S. Ferrier (2009)
Sample selection bias and presence-only distribution models: implications for background and pseudo-absence data.Ecological applications : a publication of the Ecological Society of America, 19 1
-
R. Anderson (2003)
Real vs. artefactual absences in species distributions: tests for Oryzomys albigularis (Rodentia: Muridae) in VenezuelaJournal of Biogeography, 30
-
R. Anderson, A. Peterson, Marcela Gómez‐Laverde, R. Anderson, A. Peterson, Gó Mez-Laverde (2002)
Using niche-based GIS modeling to test geographic predictions of competitive exclusion and competitive release in South American pocket miceOikos, 98
-
Townsend Peterson, D. Vieglais, On (2001)
Predicting Species Invasions Using Ecological Niche Modeling: New Approaches from Bioinformatics Attack a Pressing Problem, 51
-
A. Fielding, J. Bell (1997)
A review of methods for the assessment of prediction errors in conservation presence/absence modelsEnvironmental Conservation, 24
-
Centaarea Diftas, Maculosa WATSON', A. Renney (1974)
THE BIOLOGY OF CANADIAN WEEDS.: 6. CENTAUREA DIFFUSA AND C. MACULOSACanadian Journal of Plant Science, 54
-
C. Stern (1950)
CONCLUDING REMARKS OF THE CHAIRMANCold Spring Harbor Symposia on Quantitative Biology, 15
-
O. Broennimann, U. Treier, U. Treier, H. Müller-Schärer, W. Thuiller, A. Peterson, A. Guisan (2007)
Evidence of climatic niche shift during biological invasion.Ecology letters, 10 8
-
Tobias Sing, Oliver Sander, N. Beerenwinkel, Thomas Lengauer (2005)
ROCR: visualizing classifier performance in RBioinformatics, 21 20
-
(2005)
Published online in Wiley InterScience (www.interscience.wiley.com). DOI: 10.1002/joc.1276 VERY HIGH RESOLUTION INTERPOLATED CLIMATE SURFACES FOR GLOBAL LAND AREAS -
David Stockwell (1999)
The GARP modelling system: problems and solutions to automated spatial predictionInt. J. Geogr. Inf. Sci., 13
-
J. Swets (1988)
Measuring the accuracy of diagnostic systems.Science, 240 4857
-
A. Peterson, Jorge Soberón, V. Sánchez‐Cordero (1999)
Conservatism of ecological niches in evolutionary timeScience, 285 5431
-
D. Warren, R. Glor, M. Turelli (2008)
Environmental Niche Equivalency versus Conservatism: Quantitative Approaches to Niche Evolution, 62
-
J. Elith, M. Burgman (2002)
Predictions and their validation: Rare plants in the Central Highlands, Victoria, Australia -
M. Andersen (1992)
Spatial analysis of two-species interactionsOecologia, 91
-
C. Dormann, J. McPherson, M. Araújo, R. Bivand, J. Bolliger, G. Carl, R. Davies, A. Hirzel, W. Jetz, W. Kissling, I. Kühn, R. Ohlemüller, P. Peres‐Neto, B. Reineking, B. Schröder, F. Schurr, R. Wilson (2007)
Methods to account for spatial autocorrelation in the analysis of species distributional data : a reviewEcography, 30
-
P. Hernández, C. Graham, L. Master, Deborah Albert (2006)
The effect of sample size and species characteristics on performance of different species distribution modeling methodsEcography, 29
- Publisher
- Wiley
- Copyright
- © 2009 Blackwell Publishing Ltd
- ISSN
- 0305-0270
- eISSN
- 1365-2699
- DOI
- 10.1111/j.1365-2699.2009.02174.x
- Publisher site
- See Article on Publisher Site
Abstract
Aim Environmental niche models that utilize presence‐only data have been increasingly employed to model species distributions and test ecological and evolutionary predictions. The ideal method for evaluating the accuracy of a niche model is to train a model with one dataset and then test model predictions against an independent dataset. However, a truly independent dataset is often not available, and instead random subsets of the total data are used for ‘training’ and ‘testing’ purposes. The goal of this study was to determine how spatially autocorrelated sampling affects measures of niche model accuracy when using subsets of a larger dataset for accuracy evaluation. Location The distribution of Centaurea maculosa (spotted knapweed; Asteraceae) was modelled in six states in the western United States: California, Oregon, Washington, Idaho, Wyoming and Montana. Methods Two types of niche modelling algorithms – the genetic algorithm for rule‐set prediction (GARP) and maximum entropy modelling (as implemented with Maxent) – were used to model the potential distribution of C. maculosa across the region. The effect of spatially autocorrelated sampling was examined by applying a spatial filter to the presence‐only data (to reduce autocorrelation) and then comparing predictions made using the spatial filter with those using a random subset of the data, equal in sample size to the filtered data. Results The accuracy of predictions from both algorithms was sensitive to the spatial autocorrelation of sampling effort in the occurrence data. Spatial filtering led to lower values of the area under the receiver operating characteristic curve plot but higher similarity statistic (I) values when compared with predictions from models built with random subsets of the total data, meaning that spatial autocorrelation of sampling effort between training and test data led to inflated measures of accuracy. Main conclusions The findings indicate that care should be taken when interpreting the results from presence‐only niche models when training and test data have been randomly partitioned but occurrence data were non‐randomly sampled (in a spatially autocorrelated manner). The higher accuracies obtained without the spatial filter are a result of spatial autocorrelation of sampling effort between training and test data inflating measures of prediction accuracy. If independently surveyed data for testing predictions are unavailable, then it may be necessary to explicitly account for the spatial autocorrelation of sampling effort between randomly partitioned training and test subsets when evaluating niche model predictions.
Journal
Journal of Biogeography – Wiley
Published: Dec 1, 2009