stoch.projection: Simulate stochastic growth from a sequence of matrices

Description

Simulates stochastic growth by projection using whole matrix selection techniques in an independently and identically distributed (iid) environment from a set of 2 or more projection matrices

Usage

stoch.projection(matrices, n0, tmax = 50, nreps = 5000, prob = NULL, 
                           nmax = NULL, sumweight = rep(1, length(n0)), verbose=FALSE)

Arguments

matrices

a list with two or more projection matrices

initial population vector

tmax

number of time steps or projection intervals to predict future population size

nreps

number of iterations

prob

a vector of probability weights used by sample for selecting the projection matrices, defaults to equal probabilities

nmax

a maximum number of individuals beyond which population projections cannot exceed. Default is no density dependence

sumweight

A vector of ones and zeros used to omit stage classes when checking density threshold. Default is to sum across all stage classes

verbose

Print comments at start of iteration 1, 100, 200, 300, etc.

Value

A matrix listing final population sizes by stage class with one iteration per row.

References

Morris, W. F., and D. F. Doak. 2002. Quantitative conservation biology: Theory and practice of population viability analysis. Sinauer, Sunderland, Massachusetts, USA.

Examples

Run this code

# NOT RUN {
data(hudsonia)
n<-c(4264, 3,30,16,25,5)
names(n)<-c("seed",  "seedlings", "tiny", "small", "medium" , "large")

### use equal and unequal probabilities for matrix selection 
x.eq<-stoch.projection(hudsonia, n, nreps=1000)
x.uneq<-stoch.projection(hudsonia, n, nreps=1000, prob=c(.2,.2,.2,.4))

hist(apply(x.eq, 1, sum), xlim=c(0,5000), ylim=c(0,200), col="green", 
breaks=seq(0,5000, 100), xlab="Final population size at t=50", main='')

par(new=TRUE)

## use transparency for overlapping distributions - may not work on all systems
hist(apply(x.uneq, 1, sum), xlim=c(0,5000), ylim=c(0,200), col = rgb(0, 0, 1, 0.2), 
xaxt='n', yaxt='n', ylab='', xlab='', 
breaks=seq(0,10000, 100), main='')

legend(2500,200,  c("equal", "unequal"),fill=c("green", rgb(0, 0, 1, 0.2)))
title(paste("Projection of stochastic growth for Hudsonia
using equal and unequal probabilities"), cex.main=1)

## initial pop size  
sum(n)
abline(v=sum(n), lty=3)



# }

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