knitr::opts_chunk$set( collapse = TRUE, comment = "#>" )
library(landsepi)
See also the tutorial on how to simulate a simple simulation for details on basic parameterisation.
## Initialisation of the simulation simul_params <- createSimulParams(outputDir = getwd()) ## Seed simul_params@Seed simul_params <- setSeed(simul_params, seed = 1) simul_params@Seed ## Time parameters Nyears = 6 nTSpY = 120 simul_params <- setTime(simul_params, Nyears = Nyears, nTSpY = nTSpY) ## Inoculum simul_params <- setInoculum(simul_params, val = 5e-4) ## Landscape landscape <- loadLandscape(id = 1) simul_params <- setLandscape(simul_params, land = landscape)
See also the tutorial on how to parameterise landscape and dispersal to use your own landscape and compute your own dispersal matrices.
A built-in parameterisation different pathogens (e.g. rusts of cereal crops) is available using the function loadPathogen()
:
basic_patho_param <- loadPathogen(disease = "rust")
The built-in parameterisation for "rust" simulates a pathogen which reproduces purely clonally (repro_sex_prob = 0). It is also possible to simulate a pathogen which reproduces purely sexually, or both sexually and clonally at every timestep:
basic_patho_param$repro_sex_prob <- 1 ## at every time step all pathogen individuals reproduces sexually basic_patho_param$repro_sex_prob <- 0 ## at every time step all pathogen individuals reproduces clonally basic_patho_param$repro_sex_prob <- 0.5 ## at every time step half of the pathogen population ## reproduce clonally and half sexually basic_patho_param
To simulate a pathogen with a mixed reproduction system composed of multiple events of clonal reproduction
during the epidemic phase, followed by a single event of sexual reproduction at the end of the cropping season,
a vector of probabilities of sexual reproduction (one for each timestep of the cropping season)
can be given (i.e. repro_sex_prob = 0
during the epidemic period [1:nTSpY]
, and repro_sex_prob = 1
at the
end of the cropping season).
repro_sex_probs <- c(rep(0.0, nTSpY), 1.0)
The vector containing the probability of sexual reproduction for each timestep is used
to fuel the object simul_params
via the function setReproSexProb()
:
simul_params <- setReproSexProb(simul_params, repro_sex_probs) simul_params@ReproSexProb
Sexual propagules may be released gradually during the following seasons (i.e. years). The following parameters set the average number of cropping seasons after which a sexual propagule is released and the maximum number of cropping seasons up to which a sexual propagule is viable:
basic_patho_param$sex_propagule_release_mean = 1 basic_patho_param$sex_propagule_viability_limit = 5 simul_params <- setPathogen(simul_params, basic_patho_param)
Within a cropping season, the day of release of every sexual propagule is sampled from a uniform distribution with parameters {0;nTSpY}.
Clonal propagules produced at the end of a cropping season are released during the
following season only, either altogether at the first day of the season (by setting
the parameter clonal_propagule_gradual_release = FALSE
), or progressively
(clonal_propagule_gradual_release = TRUE
). In the second case
the day of release of each propagule is sampled from a uniform distribution with parameters {0;nTSpY}.
basic_patho_param$clonal_propagule_gradual_release = TRUE ## clonal propagules are progressively ## released during the next cropping season basic_patho_param$clonal_propagule_gradual_release = FALSE ## clonal propagules are released at ## the first day of the next cropping season
Dispersal for both sexual and clonal propagules is given by vectorised matrices giving
the probability of dispersal from any field of the landscape to any other field.
The size of these matrices must be the square of the number of fields in the landscape.
It is thus specific to both the pathogen and the landscape. For rusts pathogens,
built-in dispersal matrices (for sexual and clonal propagules)
are available for each landscape using the function loadDispersalPathogen()
:
disp_patho <- loadDispersalPathogen(id = 1)
The first element of the list disp_patho
contains the vectorized dispersal matrix
for clonal propagules, while the second element contains the vectorized dispersal matrix
for sexual propagules (by default this is a diagonal matrix, i.e. sexual propagules spread only locally
and there is no between-field dispersal of sexual propagules).
disp_patho_clonal <- disp_patho[[1]] disp_patho_sex <- disp_patho[[2]] head(disp_patho_clonal) head(disp_patho_sex)
Dispersal matrices can be modified, for example, to simulate a pathogen whose sexual propagules have the same dispersal ability as clonal propagules:
disp_patho_clonal <- disp_patho[[1]] disp_patho_sex <- disp_patho[[1]] head(disp_patho_clonal) head(disp_patho_sex)
Then, the object simul_params
is updated with the dispersal matrices via the
function setDispersalPathogen()
:
simul_params <- setDispersalPathogen(simul_params, disp_patho_clonal, disp_patho_sex)
For a given parental pair, the genotype of each propagule is issued from random loci segregation of parental qualitative resistance genes. For each quantitative resistance gene, the value of each propagule trait is issued from a normal distribution around the average of the parental traits, with standard deviation defined by the parameter recombination_sd
, following the infinitesimal model (Fisher 1919).
# Resistance genes gene1 <- loadGene(name = "gene 1", type = "majorGene") gene2 <- loadGene(name = "gene 2", type = "QTL") #gene2$recombination_sd <- 0.8 gene2$Nlevels_aggressiveness <- 3 genes <- data.frame(rbind(gene1, gene2), stringsAsFactors = FALSE)
All the other steps (e.g. setting croptypes, cultivars, resistance genes ...) are not impacted by pathogen reproduction system, they are fully described in running a simple simulation
# Cultivars cultivar1 <- loadCultivar(name = "Susceptible", type = "growingHost") cultivar2 <- loadCultivar(name = "Resistant1", type = "growingHost") cultivar3 <- loadCultivar(name = "Resistant2", type = "growingHost") cultivars <- data.frame(rbind(cultivar1, cultivar2, cultivar3) , stringsAsFactors = FALSE) # Allocating genes to cultivars simul_params <- setGenes(simul_params, dfGenes = genes) simul_params <- setCultivars(simul_params, dfCultivars = cultivars) simul_params <- allocateCultivarGenes(simul_params , cultivarName = "Resistant1" , listGenesNames = c("gene 1")) simul_params <- allocateCultivarGenes(simul_params , cultivarName = "Resistant2" , listGenesNames = c("gene 2")) # Allocating cultivars to croptypes croptypes <- loadCroptypes(simul_params, names = c("Susceptible crop" , "Resistant crop 1" , "Resistant crop 2")) croptypes <- allocateCroptypeCultivars(croptypes , croptypeName = "Susceptible crop" , cultivarsInCroptype = "Susceptible") croptypes <- allocateCroptypeCultivars(croptypes , croptypeName = "Resistant crop 1" , cultivarsInCroptype = "Resistant1") croptypes <- allocateCroptypeCultivars(croptypes , croptypeName = "Resistant crop 2" , cultivarsInCroptype = "Resistant2") simul_params <- setCroptypes(simul_params, dfCroptypes = croptypes) # Allocating croptypes to fields of the landscape rotation_sequence <- croptypes$croptypeID ## No rotation -> 1 rotation_sequence element rotation_period <- 0 # number of years before rotation of the landscape prop <- c(1/3,1/3,1/3) # proportion (in surface) of each croptype aggreg <- 0 # level of spatial aggregation simul_params <- allocateLandscapeCroptypes(simul_params , rotation_period = rotation_period , rotation_sequence = rotation_sequence , prop = prop , aggreg = aggreg , graphic = FALSE) # Choosing output variables outputlist <- loadOutputs(epid_outputs = "all", evol_outputs = "all") simul_params <- setOutputs(simul_params, outputlist)
checkSimulParams(simul_params) runSimul(simul_params, graphic = TRUE, videoMP4 = FALSE)
system(paste("rm -rf ", simul_params@OutputDir))
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