The package ‘SSDM’ (Stacked Species Distribution Models) is a computer platform implemented in R providing a range of methodological approaches and parameterization at each step of the SSDM building. This vignette presents a typical workflow in R. An additional vignette presents the same workflow using the graphic user interface with the gui function (see GUI vignette).

The workflow of the package ‘SSDM’ is based on three modelling levels:

  1. the individual Species Distribution Model (SDM) fitting the occurrences of a single species on environmental predictor variables with a single modelling algorithm,
  2. the ensemble SDM (ESDM) combining the outputs of several SDMs, each SDM using a different modelling algorithm,
  3. the stack SDM (SSDM) combining several SDM or ESDM outputs to model species assemblages and compute species diversity and species richness (Fig. 1).
Figure 1. Flow chart of the package ‘SSDM’
Figure 1. Flow chart of the package ‘SSDM’

Data inputs

Environmental variables

In order to build species distribution models you will need environmental variables. Currently ‘SSDM’ uses all raster formats supported by the R package ‘raster’. The package ‘SSDM’ supports both continuous (e.g., climate maps, digital elevation models, bathymetric maps) and categorical environmental variables (e.g., land cover maps, soil type maps) as inputs. The package also allows normalizing environmental variables, which may be useful to improve the fit of certain algorithms (like artificial neural networks or support vector machines).

Rasters of environmental data need to have the same coordinate reference system while spatial extent and resolution of the environmental layers can differ. During processing, the package will deal with between-variables discrepancies in spatial extent and resolution by rescaling all environmental rasters to the smallest common spatial extent then upscaling them to the coarsest resolution.

‘SSDM’ includes the load_var function to read raster files of your environmental variables. We will work with three 30 arcsec-resolution rasters covering the north part of the main island of New Caledonia ’Grande Terre’. Climatic variables (RAINFALL and TEMPERATURE) are from the WorldClim database, and the SUBSTRATE map is from the IRD Atlas of New Caledonia (2012) (see ?Env).

library(SSDM)
## The legacy packages maptools, rgdal, and rgeos, underpinning the sp package,
## which was just loaded, will retire in October 2023.
## Please refer to R-spatial evolution reports for details, especially
## https://r-spatial.org/r/2023/05/15/evolution4.html.
## It may be desirable to make the sf package available;
## package maintainers should consider adding sf to Suggests:.
## The sp package is now running under evolution status 2
##      (status 2 uses the sf package in place of rgdal)
## Welcome to the SSDM package, you can launch the graphical user interface by typing gui() in the console.
library(raster)
## Le chargement a nécessité le package : sp
Env <- load_var(system.file('extdata',  package = 'SSDM'), categorical = 'SUBSTRATE', verbose = FALSE)
Env
## class      : RasterStack 
## dimensions : 120, 120, 14400, 3  (nrow, ncol, ncell, nlayers)
## resolution : 0.008333333, 0.008333333  (x, y)
## extent     : 164, 165, -21, -20  (xmin, xmax, ymin, ymax)
## crs        : +proj=longlat +datum=WGS84 +no_defs 
## names      :  RAINFALL, SUBSTRATE, TEMPERATURE 
## min values : 0.4593978, 0.0000000,   0.6610169 
## max values :         1,         2,           1

Note that:

  • Specify which environmental variable is categorical with the categorical parameter.
  • Normalization is activated by default, check the Norm option.

Natural history records / occurrence data

Species distribution models are built on natural history records indicating where the species occurred in the past.

‘SSDM’ include load_occ function to read raw .csv or .txt files including your natural history records. We will work with natural history records from five Cryptocarya species native to New Caledonia (see ?Occurrences).

Occ <- load_occ(path = system.file('extdata',  package = 'SSDM'), Env,
         Xcol = 'LONGITUDE', Ycol = 'LATITUDE',
         file = 'Occurrences.csv', sep = ',', verbose = FALSE)
head(Occ)
##      SPECIES LONGITUDE  LATITUDE
## 1  elliptica  164.1833 -20.28333
## 4  elliptica  164.2166 -20.46666
## 5  elliptica  164.5166 -20.39999
## 6  elliptica  164.7333 -20.59999
## 8  elliptica  164.7666 -20.74999
## 11 elliptica  164.9166 -20.94999

Note that:

  • Occurrences are checked after environmental data are loaded, therefore environmental data need to be loaded before occurrences.
  • Use the GeoRes option to thin occurences. Thinning removes unnecessary (clustered) records, reducing the effect of sampling bias while retaining the greatest amount of information.
  • In case of file opening issues look at additional options of the read.csv function used to open your raw data.*

Model algorithms

Individual species distribution models (SDMs)

In the example below we build a distribution model of Cryptocarya elliptica with a subset of the occurrences of the species and for one single algorithm, here generalized linear models. The package ‘SSDM’ currently includes eight commonly used algorithms for modelling species distributions: generalized additive models (GAM), generalized linear models (GLM), multivariate adaptive regression splines (MARS), classification tree analysis (CTA), generalized boosted models (GBM), maximum entropy (MAXENT), artificial neural networks (ANN), random forests (RF), and support vector machines (SVM). Default parameters of the dependent R package of each algorithm were conserved but most of them remain settable (see section ‘Advanced settings’).

SDM <- modelling('GLM', subset(Occurrences, Occurrences$SPECIES == 'elliptica'), 
                 Env, Xcol = 'LONGITUDE', Ycol = 'LATITUDE', verbose = FALSE)
plot(SDM@projection, main = 'SDM\nfor Cryptocarya elliptica\nwith GLM algorithm')

Note that: The package ‘SSDM’ encompasses a large methodology offered by literature. Have a look at all parameters for the modelling function with ?modelling.

Ensemble species distribution models (ESDMs)

In this next example we build an ensemble elliptica distribution model combining CTA and MARS based SDMs of this species. Because uncertainty in distribution projections can skew policy making and planning, a recommendation is to fit a number of alternative model algorithm, explore the range of projections across the different SDMs and then to find consensus in SDM projections. Two consensus methods are implemented in the package ‘SSDM’:

  1. a simple average of the SDM outputs
  2. a weighted average (default option, used below), with weigths based on a user-specified metric or group of metrics.

Additionally, data sampling uncertainties (presences, pseudo-absences) may be addressed by running several replicates for each algorithm (rep argument).

The package also provides an uncertainty map representing the between-algorithms variance. The degree of agreement between each pair of algorithms can be assessed through a correlation matrix giving the Pearson’s coefficient.

ESDM <- ensemble_modelling(c('CTA', 'MARS'), subset(Occurrences, Occurrences$SPECIES == 'elliptica'),
                           Env, rep = 1, Xcol = 'LONGITUDE', Ycol = 'LATITUDE',
                          ensemble.thresh = 0, verbose = FALSE)
plot(ESDM@projection, main = 'ESDM\nfor Cryptocarya elliptica\nwith CTA and MARS algorithms')

Note that: the package ‘SSDM’ includes a large methodology offered by literature. Have a look at all parameters for the ensemble_modelling function with ?ensemble_modelling.

Stacked species distribution models (SSDMs)

Finally, we build a stacked species distribution model using CTA and SVM algorithms and multiple species. The outputs of the different species are aggregated in SSDM maps of local species richness and endemism using the summing continuous habitat suitability maps stacking method (pSSDM).

SSDM <- stack_modelling(c('CTA', 'SVM'), Occurrences, Env, rep = 1, ensemble.thresh = 0,
                       Xcol = 'LONGITUDE', Ycol = 'LATITUDE',
                       Spcol = 'SPECIES', method = "pSSDM", verbose = FALSE)
plot(SSDM@diversity.map, main = 'SSDM\nfor Cryptocarya genus\nwith CTA and SVM algorithms')

Five other stacking methods are available (see references in ?stack_modelling for details):

  • by summing discrete presence/absence maps (bSSDM) derived from one of the six metrics available to compute binary maps
  • by summing discrete presence/absence maps obtained by drawing repeatedly from a Bernoulli distribution
  • by applying the ‘probability ranking’ rule (PRR) of the SESAM framework (a number of species equal to the prediction of species richness is selected on the basis of decreasing probability of presence calculated by the SDMs) with species richness as estimated by a pSSDM (referred to as ‘PRR.pSSDM’)
  • by applying the PRR with species richness as estimated by a MEM (‘PRR.MEM’)
  • by using the maximum-likelihood adjustment approach (‘MaximumLikelihood’)

Outputs

Model accuracy assessment

A range of model evaluation metrics included in the package ‘SDMTools’ have been integrated in the package ‘SSDM’. They include the area under the receiving operating characteristic (ROC) curve (AUC), the Cohen’s Kappa coefficient, the omission rate, the sensitivity (true positive rate) and the specificity (true negative rate). These metrics are all based on the confusion matrix (also called ‘error matrix’, which represents the instances in a predicted class versus the instances in an actual class). The confusion matrix is computed converting the habitat suitability maps into binary presence/absence maps. Most of these criteria only test the discrimination capacity of a model (how well it may distinguish/correctly predict presences and absences), but do not tell, how well the model performs on unseen data. For this purpose, we also included a calibration metric (Naimi & Arauja), which is an important measure for model transferability over space and time (e.g. for climate change projections).

knitr::kable(ESDM@evaluation)
threshold AUC omission.rate sensitivity specificity prop.correct Kappa calibration
fp 0.5048407 0.8130556 0.3069307 0.8333333 0.6916667 0.6930693 0.1905158 0.7003343

To assess the accuracy of an SSDM, the package provides the opportunity to compare modeled species assemblages with species pools from independent inventories observed in the field. Six evaluation metrics are computed: (1) the species richness error, i.e. the difference between the predicted and observed species richness; (2) the assemblage prediction success, i.e. the proportion of correct predictions; (3) the assemblage Cohen’s kappa, i.e. the proportion of specific agreement; (4) the assemblage specificity, i.e. the proportion of true negatives (species that are both predicted and observed as being absent); (5) the assemblage sensitivity, i.e. the proportion of true positives (species that are both predicted and observed as present); and (6) the Jaccard index, a widely used metric of community similarity.

knitr::kable(SSDM@evaluation)
species.richness.error prediction.success kappa specificity sensitivity Jaccard
mean -0.6071429 0.7410714 1.0222388 0.7438272 0.3089286 0.2654762
SD 1.1001443 0.2498346 0.0222675 0.2694624 0.3005647 0.2648056

Importance analysis of environmental variables

The package ‘SSDM’ provides two methods to measure the relative contribution of environmental variables, which quantifies the relevance of an environmental variable to determine species distribution. The first method is based on a jack knife approach that evaluates the change in accuracy between a full model and the models where each environmental variable are omitted in turns. All metrics available in the package can serve to assess the change in accuracy. The second method is based on the Pearson’s correlation coefficient between a full model and the models where each environmental variable are omitted in turns.

knitr::kable(SSDM@variable.importance)
RAINFALL SUBSTRATE TEMPERATURE
Mean 25.04101 10.04650 64.91250
SD 17.33124 16.11292 22.91946

Endemism mapping

In addition to species richness, endemism is an important feature for conservation as it refers to species being unique to the defined geographic location. Species endemism maps can be computed using two metrics:

  1. the weighted endemism index (WEI)
  2. the corrected weighted endemism index
plot(SSDM@endemism.map, main = 'Endemism map\nfor Cryptocarya genus\nwith CTA and SVM algorithms')

Summary plot

All results can be summarized inside a shiny dashboard by calling plot method directly on an SSDM object.

# plot(SSDM)

Model forecasting

To investigate impacts of changing environmental conditions on species distribution and assemblages, it is often of interest to project an existing model using different environmental rasters than used for model building. In ‘SSDM’ this can be done by using the project function, which takes any SDM (Algorithm.SDM), ESDM (Ensemble.SDM) or SSDM (Stacked.SDM) object produced with modelling, ensemble_modelling or stack_modelling. The following example shows the projection of our previously built SDM object to an environment with reduced rainfall and increased temperature.

Env_new <- stack(Env[[1]]-0.3,Env[[2]],Env[[3]]+0.2)
SDM_projection <- project(SDM,Env_new)

The function by default takes the supplied SDM object and returns it with updated @projection slots and, in the case of ESDMs and SSDMs, also updates the @uncertainty, @diversity.map and @endemism.map. If the original model should be kept, the resulting maps can also be returned as a list by setting update.projections=FALSE. Further, for ESDMs or SSDMs the projections of the individual models they are composed of can be saved by setting SDM.projections=TRUE.

Advanced settings

Modelling methods

SSDM includes a collection of different modelling methods, which may be seen as a science in themselves. For easier use, all algorithms are set up with default settings, which may or may not be sufficient for your specific application. For better fine-tuning, custom settings can be easily passed to the original functions through algo.args lists (‘algo’ being the lowercase name of the respective algorithm). For example, if you want to set the singular.ok argument in the glm function use glm.args=list(singular.ok=FALSE). Disclaimer: When using custom argument settings to build models, please remember to also supply these argument lists in any consecutive steps (e.g. when calling project afterwards to project the model into a different environment). This is because - for reasons of efficiency and harmonization - SSDM objects only store information necessary to rebuild the models when needed instead of storing the original models.

If you need to access the original models for any reason, you may do so by using the internal function SSDM:::get_model(model) (mind the triple dots).

Performance and speed

Due to their very nature, ensemble and stacked models can become large in size and take a long time to finish. Depending on your hardware, this may cause problems with your available working memory, since R by habits stores objects in RAM.

To deal with these issues, we included several options to reduce memory load and optimize speed at the same time. Firstly, the number of cores that should be used for computing in parallel (using the parallel and foreach packages) can be set through the ncores arguments in ensemble_modelling, stack_modelling and project.

R objects are by default exported to each worker and increase the necessary memory with decreasing speed improvement. Here, we use the itertools package to only send the necessary chunks to each worker. By using the minimal.memory arguments, only one model is send to each worker at a time, decreasing memory load some more.

Finally, for the least memory use you may set the tmp argument to TRUE to save temporary files (raster projections) to the raster temporary folder. Please be aware, however, that the files may take up a lot of disk space. Alternatively, with tmp you may specify a path, where temporary files should be stored. Please keep in mind, that the temporary folders might be cleared when closing R, so you may want to write the projections before closing your session.