Generalized Dissimilarity Modeling is a statistical technique for modelling variation in biodiversity between pairs of geographical locations or through time. The gdm package provides functions to fit, evaluate, summarize, and plot Generalized Dissimilarity Models and to make predictions (across space and/or through time) and map biological patterns by transforming environmental predictor variables.
GDM fits biological distances to pairwise site geographical and environmental distances. Most users will need to first format their data to gdm's site-pair table format:
formatsitepair | To convert biodiversity and environmental data to site-pair format |
gdm | To fit a GDM |
gdm.crossvalidation | To evaluate a GDM |
gdm.partition.deviance | To asses predictor contributions to deviance explained |
gdm.varImp | To asses model significance and predictor importance |
summary | To summarize a GDM |
predict | To predict biological dissimilarities between sites in space or between time periods |
gdm.transform | To transform each environmental predictor to biological importance |
plot | To plot model fit and I-splines |
isplineExtract | To extract I-spline values to allow for custom plotting |
plotUncertainty | To estimate and plot model sensitivity using bootstrapping |
The gdm development team is Matt Fitzpatrick and Karel Mokany. The R package is based on code originally developed by Glenn Manion under the direction of Simon Ferrier. Where others have contributed to individual functions, credits are provided in function help pages.
The maintainer of the R version of gdm is Matt Fitzpatrick <mfitzpatrick@umces.edu>.
The functions in the gdm package provide the tools necessary for fitting GDMs, including functions to prepare biodiversity and environmental data. Major functionality includes:
Formatting various types of biodiversity and environmental data to gdm's site-pair format used in model fitting
Fitting GDMs using geographic and environmental distances between sites
Plotting fitted functions & extracting I-spline values
Estimating predictor importance using matrix permutation and predictor contributions using deviance paritioning
Using cross-validation to evaluate models
Predicting pairwise dissimiliarites between sites or times and transforming environmental predictors to biological importance and mapping these patterns.
To see the preferable citation of the package, type citation("gdm")
.