Extending vegetation site data and ensemble models to predict patterns of foliage cover and species richness for plant functional groups

Autor:	Ian Oliver, Simon Ferrier, Graeme Newell, Michael Somerville, Terry Koen, Matt White, Megan J. McNellie, Philip Gibbons, Glenn Manion, Peter Griffioen
Rok vydání:	2021
Předmět:	0106 biological sciences 010504 meteorology & atmospheric sciences Ecology Ensemble forecasting Geography Planning and Development Vegetation Native plant 010603 evolutionary biology 01 natural sciences Floristics Forb Cover (algebra) Species richness Physical geography Landscape ecology 0105 earth and related environmental sciences Nature and Landscape Conservation Mathematics
Zdroj:	Landscape Ecology. 36:1391-1407
ISSN:	1572-9761 0921-2973
DOI:	10.1007/s10980-021-01221-x
Popis:	Context Ensembles of artificial neural network models can be trained to predict the continuous characteristics of vegetation such as the foliage cover and species richness of different plant functional groups. Objectives Our first objective was to synthesise existing site-based observations of native plant species to quantify summed percentage foliage cover and species richness within four functional groups and in totality. Secondly, we generated spatially-explicit, continuous, landscape-scale models of these functional groups, accompanied by maps of the model residuals to show uncertainty. Methods Using a case study from New South Wales, Australia, we aggregated floristic observations from 6806 sites into four common plant growth forms (trees, shrubs, grasses and forbs) representing four different functional groups. We coupled these response data with spatially-complete surfaces describing environmental predictors and predictors that reflect landscape-scale disturbance. We predicted the distribution of foliage cover and species richness of these four plant functional groups over 1.5 million hectares. Importantly, we display spatially explicit model residuals so that end-users have a tangible and transparent means of assessing model uncertainty. Results Models of richness generally performed well (R2 0.43–0.63), whereas models of cover were more variable (R2 0.12–0.69). RMSD ranged from 1.42 (tree richness) to 29.86 (total native cover). MAE ranged from 1.0 (tree richness) to 20.73 (total native foliage cover). Conclusions Continuous maps of vegetation attributes can add considerable value to existing maps and models of discrete vegetation classes and provide ecologically informative data to support better decisions across multiple spatial scales.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::26ac4e21122cd79b1d6e8425f4b50fc7 https://doi.org/10.1007/s10980-021-01221-x Zobrazit plný text záznamu Full text from SpringerLink