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Determining alternative models for vegetation response analysis: a non‐parametric approach

Determining alternative models for vegetation response analysis: a non‐parametric approach Abstract. Vegetation models based on multiple logistic regression are of growing interest in environmental studies and decision making. The relatively simple sigmoid Gaussian optimum curves are most common in current vegetation models, although several different other response shapes are known. However, improvements in the technical means for handling statistical data now facilitate fast and interactive calculation of alternative complex, more data‐related, non‐parametric models. The aim in this study was to determine whether, and if so how often, a complex response shape could be more adequate than a linear or quadratic one. Using the framework of Generalized Additive Models, both parametric (linear and quadratic) and non‐parametric (smoothed) stepwise multiple logistic regression techniques were applied to a large data set on wetlands and water plants and to six environmental variables: pH, chloride, orthophosphate, inorganic nitrogen, thickness of the sapropelium layer and depth of the water‐body. All models were tested for their goodness‐of‐fit and significance. Of all 156 generalized additive models calculated, 77 % were found to contain at least one smoothed predictor variable, i.e. an environmental variable with a response better fitted by a complex, non‐parametric, than by a linear or quadratic parametric curve. Chloride was the variable with the highest incidence of smoothed responses (48 %). Generally, a smoothed curve was preferable in 23 % of all species‐variable correlations calculated, compared to 25 % and 18 % for sigmoid and Gaussian shaped curves, respectively. Regression models of two plant species are presented in detail to illustrate the potential of smoothers to produce good fitting and biologically sound response models in comparison to linear and polynomial regression models. We found Generalized Additive Modelling a useful and practical technique for improving current regression‐based vegetation models by allowing for alternative, complex response shapes. http://www.deepdyve.com/assets/images/DeepDyve-Logo-lg.png Journal of Vegetation Science Wiley

Determining alternative models for vegetation response analysis: a non‐parametric approach

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Publisher
Wiley
Copyright
1998 IAVS ‐ the International Association of Vegetation Science
ISSN
1100-9233
eISSN
1654-1103
DOI
10.2307/3237218
Publisher site
See Article on Publisher Site

Abstract

Abstract. Vegetation models based on multiple logistic regression are of growing interest in environmental studies and decision making. The relatively simple sigmoid Gaussian optimum curves are most common in current vegetation models, although several different other response shapes are known. However, improvements in the technical means for handling statistical data now facilitate fast and interactive calculation of alternative complex, more data‐related, non‐parametric models. The aim in this study was to determine whether, and if so how often, a complex response shape could be more adequate than a linear or quadratic one. Using the framework of Generalized Additive Models, both parametric (linear and quadratic) and non‐parametric (smoothed) stepwise multiple logistic regression techniques were applied to a large data set on wetlands and water plants and to six environmental variables: pH, chloride, orthophosphate, inorganic nitrogen, thickness of the sapropelium layer and depth of the water‐body. All models were tested for their goodness‐of‐fit and significance. Of all 156 generalized additive models calculated, 77 % were found to contain at least one smoothed predictor variable, i.e. an environmental variable with a response better fitted by a complex, non‐parametric, than by a linear or quadratic parametric curve. Chloride was the variable with the highest incidence of smoothed responses (48 %). Generally, a smoothed curve was preferable in 23 % of all species‐variable correlations calculated, compared to 25 % and 18 % for sigmoid and Gaussian shaped curves, respectively. Regression models of two plant species are presented in detail to illustrate the potential of smoothers to produce good fitting and biologically sound response models in comparison to linear and polynomial regression models. We found Generalized Additive Modelling a useful and practical technique for improving current regression‐based vegetation models by allowing for alternative, complex response shapes.

Journal

Journal of Vegetation ScienceWiley

Published: Feb 1, 1998

References

  • On non‐linear species response models in ordination
    Austin, Austin
  • Models for the analysis of species response to environmental gradients
    Austin, Austin
  • Current problems of environmental gradients and species response curves in relation to continuum theory
    Austin, Austin; Gaywood, Gaywood
  • Current approaches to modelling the environmental riche of eucalypts: implication for forest biodiversity
    Austin, Austin; Meyers, Meyers
  • A new model for the continuum concept
    Austin, Austin; Smith, Smith
  • New approaches to direct gradient analysis using environmental scalars and statistical curve‐fitting procedures
    Austin, Austin; Cunningham, Cunningham; Fleming, Fleming
  • Determining species response functions to an environmental gradient by means of a beta‐function
    Austin, Austin; Nicholls, Nicholls; Doherty, Doherty; Meyers, Meyers
  • Measurement of the realized qualitative niche: environmental niches of five Eucalyptus species
    Austin, Austin; Nicholls, Nicholls; Margules, Margules
  • Statistical approaches to interpreting diversity patterns in the Norwegian mountain flora
    Birks, Birks
  • Environmental conditions and fen vegetation in three lowland mires
    Bootsma, Bootsma; Wassen, Wassen
  • Experimental evaluation of realized niche models for predicting responses of plant species to a change in environmental conditions
    Swart, Swart; Valk, Valk; Koehler, Koehler; Barendregt, Barendregt
  • Competition and coexistence: the contribution of modelling to the formation of ecological concepts
    Ekschmitt, Ekschmitt; Breckling, Breckling
  • On the use of three performance measures for fitting species response curves
    Ferrer‐Castán, Ferrer‐Castán; Calvo, Calvo; Esteve‐Selma, Esteve‐Selma; Torres‐Martinéz, Torres‐Martinéz; Ramirez‐Diaz, Ramirez‐Diaz
  • Coenocline simulation
    Gauch, Gauch; Whittaker, Whittaker
  • Ordination of vegetation samples by Gaussian species distributions
    Gauch, Gauch; Chase, Chase; Whittaker, Whittaker
  • Goodness‐offit testing for the logistic regression model when the estimated probabilities are small
    Hosmer, Hosmer; Lemeshow, Lemeshow; Klar, Klar
  • A hierarchical set of models for species response analysis
    Huisman, Huisman; Olff, Olff; Fresco, Fresco
  • Modelling present and future ranges of some European higher plants using climate response surfaces
    Huntley, Huntley; Berry, Berry; Cramer, Cramer; McDonald, McDonald
  • Multivariate analysis in ecology and systematics: Panacea or Pandora's box
    James, James; McCulloch, McCulloch
  • A multiple stress model for vegetation (‘move’): a tool for scenario studies and standard‐setting
    Latour, Latour; Reiling, Reiling
  • Ecological standards for eutrophication and desiccation: perspectives for a risk assessment
    Latour, Latour; Reiling, Reiling; Slooff, Slooff
  • The niche concept revisited: mechanistic models and community context
    Leibold, Leibold
  • Diversity of Eucalyptus species predicted by a multi‐variable environmental gradient
    Margules, Margules; Nicholls, Nicholls; Austin, Austin
  • Generalized linear models
    Nelder, Nelder; Wedderburn, Wedderburn
  • How to make biological surveys go further with generalised linear models
    Nicholls, Nicholls
  • A hydrology‐vegetation interaction model for predicting the occurrence of plant species in dune slacks
    Noest, Noest
  • Why the beta‐function cannot be used to estimate skewness of species responses
    Oksanen, Oksanen
  • Effects of vegetation management and raising the water table on nutrient dynamics and vegetation change in a wet grassland
    Oomes, Oomes; Olff, Olff; Altena, Altena
  • Regression smoothers for estimating parameters of growth analyses
    Shipley, Shipley; Hunt, Hunt
  • A model of species density in shoreline vegetation
    Shipley, Shipley; Keddy, Keddy; Gaudet, Gaudet; Moore, Moore
  • Autocorrelation in logistic regression modelling of species distributions
    Smith, Smith
  • Correspondence analysis of incidence and abundance data: properties in terms of a unimodal response model
    Braak, Braak
  • Canonical correspondence analysis: a new eigenvector technique for multivariate direct gradient analysis
    Braak, Braak
  • The analysis of vegetation‐environment relationships by canonical correspondence analysis
    Braak, Braak
  • Ecological amplitudes of plant species and the internal consistency of Ellenberg's indicator values for moisture
    Braak, Braak; Gremmen, Gremmen
  • Weighted averaging, logistic regression and the Gaussian response model
    Braak, Braak; Looman, Looman
  • Nontraditional regression analysis
    Trexler, Trexler; Travis, Travis
  • Vegetation zonation in a former tidal area: a vegetation‐type response model based on DCA and logistic regression using GIS
    Rijt, Rijt; Hazelhoff, Hazelhoff; Blom, Blom
  • Generalized additive models in plant ecology
    Yee, Yee; Mitchell, Mitchell

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