The poems package provides a framework of interoperable R6 (Chang, 2020) classes for building ensembles of viable models via the pattern-oriented modeling (POM) approach (Grimm et al., 2005). Pattern-oriented modeling is a vigorous form of statistical validation in which simulations and their parameter settings are summarized using key metrics and converged toward multiple observed patterns, or targets.
The package provides a process-based population model related to the functionality of RAMAS or Vortex, but in a free and open source format, with high customizability. The package includes classes for encapsulating and generating model parameters, and managing the POM workflow. The workflow includes:
- Model setup including generated spatial layers and demographic population model parameters.
- Generating model parameters via Latin hypercube sampling (Iman & Conover, 1980).
- Running multiple sampled model simulations.
- Collating summary results metrics via user-defined functions.
- Validating and selecting an ensemble of models that best match known patterns.
By default, model validation and selection utilizes an approximate Bayesian computation (ABC) approach (Beaumont et al., 2002) using the abc package (Csillery et al., 2015). However, alternative user-defined functionality could be employed.
The package includes a spatially explicit demographic population model simulation engine, which incorporates default functionality for density dependence, correlated environmental stochasticity, stage-based transitions, and distance-based dispersal. The user may customize the simulator by defining functionality for translocations, harvesting, mortality, and other processes, as well as defining the sequence order for the simulator processes. The framework could also be adapted for use with other model simulators by utilizing its extendable (inheritable) base classes.
You can install poems from the CRAN repository:
install.packages("poems")
Or you can install the development version of poems from GitHub using:
# install.packages("devtools")
remotes::install_github("GlobalEcologyLab/poems")
poems
can do spatial population models on its own, but it also
provides the engine behind two extension packages:
paleopop and
epizootic. paleopop
is
an extension for simulating populations over very long timescales, and
epizootic
is an extension for simulating disease dynamics in wild
populations.
The following simple example demonstrates how to run a single spatially explicit demographic population model using poems:
library(poems)
# Demonstration example region (U Island) and initial abundance
coordinates <- data.frame(
x = rep(seq(177.01, 177.05, 0.01), 5),
y = rep(seq(-18.01, -18.05, -0.01), each = 5)
)
template_raster <- Region$new(coordinates = coordinates)$region_raster # full extent
template_raster[][-c(7, 9, 12, 14, 17:19)] <- NA # make U Island
region <- Region$new(template_raster = template_raster)
initial_abundance <- seq(0, 300, 50)
raster::plot(region$raster_from_values(initial_abundance),
main = "Initial abundance", xlab = "Longitude (degrees)",
ylab = "Latitude (degrees)", zlim = c(0, 300), colNA = "blue"
)
# Set population model
pop_model <- PopulationModel$new(
region = region,
time_steps = 5,
populations = 7,
initial_abundance = initial_abundance,
stage_matrix = matrix(c(
0, 2.5, # Leslie/Lefkovitch matrix
0.8, 0.5
), nrow = 2, ncol = 2, byrow = TRUE),
carrying_capacity = rep(200, 7),
density_dependence = "logistic",
dispersal = (!diag(nrow = 7, ncol = 7)) * 0.05,
result_stages = c(1, 2)
)
# Run single simulation
results <- population_simulator(pop_model)
results # examine
#> $all
#> $all$abundance
#> [1] 1010 1077 1229 1288 1405
#>
#> $all$abundance_stages
#> $all$abundance_stages[[1]]
#> [1] 604 615 761 744 841
#>
#> $all$abundance_stages[[2]]
#> [1] 406 462 468 544 564
#>
#>
#>
#> $abundance
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 50 91 143 174 204
#> [2,] 91 139 167 190 204
#> [3,] 126 136 162 201 196
#> [4,] 161 159 175 195 193
#> [5,] 185 181 182 170 202
#> [6,] 195 189 195 174 198
#> [7,] 202 182 205 184 208
#>
#> $abundance_stages
#> $abundance_stages[[1]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 33 54 90 107 134
#> [2,] 56 83 100 113 126
#> [3,] 64 79 98 111 103
#> [4,] 102 82 110 115 114
#> [5,] 100 113 109 103 118
#> [6,] 125 107 118 88 126
#> [7,] 124 97 136 107 120
#>
#> $abundance_stages[[2]]
#> [,1] [,2] [,3] [,4] [,5]
#> [1,] 17 37 53 67 70
#> [2,] 35 56 67 77 78
#> [3,] 62 57 64 90 93
#> [4,] 59 77 65 80 79
#> [5,] 85 68 73 67 84
#> [6,] 70 82 77 86 72
#> [7,] 78 85 69 77 88
raster::plot(region$raster_from_values(results$abundance[, 5]),
main = "Final abundance", xlab = "Longitude (degrees)",
ylab = "Latitude (degrees)", zlim = c(0, 300), colNA = "blue"
)
Further examples utilizing the POM workflow and more advanced features of poems can be found in the accompanying vignettes.
You may cite poems in publications using our software paper in Methods in Ecology and Evolution:
Fordham, D. A., Haythorne, S., Brown, S. C., Buettel, J. C., & Brook, B. W. (2021). poems: R package for simulating species’ range dynamics using pattern‐oriented validation. Methods in Ecology and Evolution, 12(12), 2364-2371.
Beaumont, M. A., Zhang, W., & Balding, D. J. (2002). ‘Approximate Bayesian computation in population genetics’. Genetics, vol. 162, no. 4, pp, 2025–2035. doi:10.1093/genetics/162.4.2025
Chang, W. (2020). ‘R6: Encapsulated Classes with Reference Semantics’. R package version 2.5.0. Retrieved from https://CRAN.R-project.org/package=R6
Csillery, K., Lemaire L., Francois O., & Blum M. (2015). ‘abc: Tools for Approximate Bayesian Computation (ABC)’. R package version 2.1. Retrieved from https://CRAN.R-project.org/package=abc
Grimm, V., Revilla, E., Berger, U., Jeltsch, F., Mooij, W. M., Railsback, S. F., Thulke, H. H., Weiner, J., Wiegand, T., DeAngelis, D. L., (2005). ‘Pattern-Oriented Modeling of Agent-Based Complex Systems: Lessons from Ecology’. Science vol. 310, no. 5750, pp. 987–991. doi:10.1126/science.1116681
Iman R. L., Conover W. J. (1980). ‘Small sample sensitivity analysis techniques for computer models, with an application to risk assessment’. Commun Stat Theor Methods A9, pp. 1749–1842. doi:10.1080/03610928008827996