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Species distribution modelling for plant communities: stacked single species or multivariate modelling approaches?

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Title Species distribution modelling for plant communities: stacked single species or multivariate modelling approaches?
Names Henderson, Emilie B. (creator)
Ohmann, Janet L. (creator)
Gregory, Matthew J. (creator)
Roberts, Heather M. (creator)
Zald, Harold (creator)
Date Issued 2014-07 (iso8601)
Note To the best of our knowledge, one or more authors of this paper were federal employees when contributing to this work. This is the publisher’s final pdf. The article is copyrighted by the International Association for Vegetation Science and published by John Wiley & Sons Ltd. It can be found at: http://onlinelibrary.wiley.com/journal/10.1111/%28ISSN%291654-109X.
Abstract AIM: Landscape management and conservation planning require maps of vegetation
composition and structure over large regions. Species distribution models
(SDMs) are often used for individual species, but projects mapping multiple species
are rarer. We compare maps of plant community composition assembled by
stacking results from many SDMs with multivariate maps constructed using
nearest-neighbor imputation.
LOCATION: Western Cascades ecoregion, Oregon and California, USA.
METHODS: We mapped distributions and abundances of 28 tree species over
4,007,110 ha at 30-m resolution using three approaches: SDMs using machine
learning (random forest) to yield: (1) binary (RF_Bin); (2) basal area (abundance;
RF_Abund) predictions; and (3) multi-species basal area predictions
using a nearest-neighbor imputation variant based on random forest (RF_NN).
We evaluated accuracy of binary predictions for all models, compared area
mapped with plot-based areal estimates, assessed species abundance at two spatial
scales and evaluated communities for species richness, problematic compositional
errors and overall community composition.
RESULTS: RF_Bin yielded the strongest binary predictions (median True Skill
Statistics; RF_Bin: 0.57, RF_NN: 0.38, RF_Abund: 0.27). Plot-scale predictions
of abundance were poor for RF_Abund and RF_NN (median Agreement
Coefficient (AC): -1.77 and -2.28), but strong when summarized
over 50-km radius tessellated hexagons (median AC for both: 0.79). RF_Abund’s
strength with abundance and weakness with binary predictions
stems from predicting small values instead of zeros. The number of zero
value predictions from RF_NN was closest to counts of zeros in the plot
data. Correspondingly, RF_NN’s map-based species area estimates closely
matched plot-based area estimates. RF_NN also performed best for community-level accuracy metrics.
CONCLUSIONS: RF_NN was the best technique for building a broad-scale map
of diversity and composition because the modelling framework maintained
inter-species relationships from the input plot data. Re-assembling communities
from single variable maps often yielded unrealistic communities.
Although RF_NN rarely excelled at single species predictions of presence or
abundance, it was often adequate to many (but not all) applications in both
dimensions. We discuss our results in the context of map utility for applications
in the fields of ecology, conservation and natural resource management
planning. We highlight how RF_NN is well-suited for mapping current
but not future vegetation.
Genre Article
Topic Nearest-neighbor imputation
Identifier Henderson, E. B., Ohmann, J. L., Gregory, M. J., Roberts, H. M., Zald, H. (2014), Species distribution modelling for plant communities: stacked single species or multivariate modelling approaches?. Applied Vegetation Science, 17: 516–527. doi:10.1111/avsc.12085

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