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AusHumanSpreadGSAGithub.R
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AusHumanSpreadGSAGithub.R
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###################################################################
## Cellular automaton model of human spread through Sahul ##
## SINGLE-SCENARIO GLOBAL SENSITIVITY ANALYSIS ##
## July 2020 ##
## Corey JA Bradshaw, Flinders University ##
## [email protected] ##
## http://GlobalEcologyFlinders.com ##
## http://github.com/cjabradshaw ##
###################################################################
#####################################################################################
## testing effect on time to saturation (≥ 97% occupied)
## of modifying the following variables:
##
## human rmax at generational scale (arbitrarily double)
## set in model: r.max.NEE = 2 * log(lambda.ann^gen.l) = 0.2081606; test uniform sample between 0.18 and 0.22
##
## minimum maximum dispersal distance
## set in model: D.max.lo = A.lo*M^B.lo = 22.37669; test uniform sample from 15 to 30
##
## maximum maximum dispersal distance
## set in model: D.max.up <- A.up*M^B.up = 69.27189; test uniform sample from 60 to 80
##
## D.max multiplier (D.vec.mult) instead
## set in model to 1
## 1 to 5
##
## minimum viable population size threshold
## set in model to: min.pop.size = 100; test uniform sample from 50 to 200
##
## mean (beta resampled) additional mortality expected for cells meeting criteria
## set in model to: ltMVP.red = 0.2; test uniform sample from 0.1 to 0.3
##
## set resistance of landscape for distance-to-water function
## set in model to: watmovresist = 3; test uniform sample from 1.5 to 4
##
## mean mortality during a catastrophe event
## set in model to: M.cat = 0.75; test uniform sample from 0.50 to 0.90
##
## modifier of maximum ruggedness effect on movement
## set in model to: rugmov.mod = 1; test uniform sample from 0.5 to 2.0
##
## mu for beta function indicating proportion of people immigrating/emigrating
## set in model to: pmov.mean = 1/3; test uniform sample from 1/5 to 1/2
##
## minimum N/K when pmov.mean emigrates
## set in model to: NK.emig.min = 0.3; test uniform sample from 0.2 to 0.4
##
## maximum N/K when pmov.mean emigrates
## set in model to: NK.emig.max = 0.7; test uniform sampel from 0.6 to 0.8
##
## increase mortality in cells with N < MVP.thresh
## set in model to: MVP.thresh = 100; test uniform sample from 50 to 200
##
#####################################################################################
## remove everything
rm(list = ls())
## libraries
library(sp)
library(rgdal)
library(raster)
library(Scale)
library(oceanmap)
library(insol)
library(OceanView)
library(abind)
library(pracma)
library(binford)
library(rgl)
library(scatterplot3d)
library(spatstat)
library(spatialEco)
library(SpatialPack)
library(doSNOW)
library(iterators)
library(snow)
library(foreach)
library(lhs)
library(data.table)
## source (update when appropriate)
source("matrixOperators.r")
## Set up parallel processing (nproc is the number of processing cores to use)
nproc <- 6
cl.tmp = makeCluster(rep('localhost',nproc), type='SOCK')
registerDoSNOW(cl.tmp)
getDoParWorkers()
## ancient human founding population simulation function
ahspread_sim <- function(input, dir.nm, rowNum) {
## assign all parameter values
for (d in 1:ncol(input)) {assign(names(input)[d], input[,d])}
####################################################
## necessary input calculations for stochastic model
####################################################
## define necessary functions
# gradient function for immigration
# pI ~ a / (1 + (b * exp(-c * Rk)))
aI <- 0.95; bI <- 5000; cI <- 3
pI.func <- function(Rk) {
pI <- aI / (1 + (bI * exp(-cI * Rk)))
return(pI)}
#pI.func(4)
xI <- seq(1,10,0.01)
yI <- pI.func(xI)
# gradient function for emigration
aE <- 1; bE <- -3.2
pE.func <- function(Rk) {
pE <- aE * exp(bE * Rk)
return(pE)}
xE <- seq(0.01,1,0.01)
yE <- pE.func(xE)
pE.out <- data.frame(xE,yE)
# stochastic beta sampler (single sample)
stoch.beta.func <- function(mu, var) {
Sx <- rbeta(length(mu), (((1 - mu) / var - 1 / mu) * mu ^ 2), ((((1 - mu) / var - 1 / mu) * mu ^ 2)*(1 / mu - 1)))
return(params=Sx)
}
# stochastic beta sampler (n samples)
stoch.n.beta.func <- function(n, mu, var) {
Sx <- rbeta(n, (((1 - mu) / var - 1 / mu) * mu ^ 2), ((((1 - mu) / var - 1 / mu) * mu ^ 2)*(1 / mu - 1)))
return(params=Sx)
}
# dynamics model function
Nproj.func <- function(Nt, rm, K) {
Nt1 <- round(Nt * exp(rm*(1-(Nt/K))), 0)
return(Nt1)
}
# rescale a range
rscale <- function (x, nx1, nx2, minx, maxx) {
nx = nx1 + (nx2 - nx1) * (x - minx)/(maxx - minx)
return(nx)
}
# matrix rotation
rot.mat <- function(x) t(apply(x, 2, rev))
# matrix poisson resampler
rpois.fun <- function(x,y,M) {
rpois(1,M[x,y])
}
rpois.vec.fun <- Vectorize(rpois.fun,vectorize.args = c('x','y'))
## import necessary data (place in appropriate directory)
####################################################
## set grids
####################################################
## relative density, carrying capacity & feedbacks
## NPP (LOVECLIM)
npp <- read.table("NppSahul(0-140ka).csv", header=T, sep=",") # 0.5 deg lat resolution
not.na <- which(is.na(npp[,3:dim(npp)[2]]) == F, arr.ind=T)
upper.row <- as.numeric(not.na[1,1])
lower.row <- as.numeric(not.na[dim(not.na)[1],1])
min.lat <- max(npp[not.na[,1], 1])
max.lat <- min(npp[not.na[,1], 1])
min.lon <- min(npp[not.na[,1], 2])
max.lon <- max(npp[not.na[,1], 2])
sahul.sub <- rep(0, dim(npp)[1])
for (n in 1:dim(npp)[1]) {
sahul.sub[n] <- ifelse(npp[n,1] <= min.lat & npp[n,1] >= max.lat & npp[n,2] >= min.lon & npp[n,2] <= max.lon, 1, 0)
}
sah.keep <- which(sahul.sub == 1)
npp.sah <- npp[sah.keep,]
## import sea level & palaeo-lakes layer (1 = land; 2 = palaeo-lake)
sll <- read.table("SeaLevelSahul(0-140ka)&LakeC.csv", header=T, sep=",") # 0.5 deg lat resolution
sll.sah <- sll[sah.keep,]
## import ruggedness (average elevational slope) per cell
rug <- read.table("RuggednessSahul(0-140ka).csv", header=T, sep=",") # 0.5 deg lat resolution
sah.keep <- which(sahul.sub == 1)
rug.sah <- rug[sah.keep,]
# Siler hazard h(x) (Gurven et al. 2007)
# average hunter-gatherer
a1 <- 0.422 # initial infant mortality rate (also known as αt)
b1 <- 1.131 # rate of mortality decline (also known as bt)
a2 <- 0.013 # age-independent mortality (exogenous mortality due to environment); also known as ct
a3 <- 1.47e-04 # initial adult mortality rate (also known as βt)
b3 <- 0.086 # rate of mortality increase
longev <- 80
x <- seq(0,longev,1) # age vector
h.x <- a1 * exp(-b1*x) + a2 + a3 * exp(b3 * x) # Siler's hazard model
l.x <- exp((-a1/b1) * (1 - exp(-b1*x))) * exp(-a2 * x) * exp(a3/b3 * (1 - exp(b3 * x))) # Siler's survival (proportion surviving) model
l.inf <- exp(-a1/b1) # survival at infinite time
T.m <- 1/b1 # time constant at which maturity is approached
h.m <- a2 # hazard for mature animals
l.m <- exp(-a2*x) # survival
h.s <- a3*exp(b3*x) # hazard for senescence
l.s <- exp((a3/b3)*(1 - exp(b3*x))) # survival for senescence
f.x <- a3*exp(b3*x)*exp((a3/b3)/(1-exp(b3*x))) # probability density function
T.s <- (1/b3) # modal survival time
## survival
init.pop <- 10000
lx <- round(init.pop*l.x,0)
len.lx <- length(lx)
dx <- lx[1:(len.lx-1)]-lx[2:len.lx]
qx <- dx/lx[1:(length(lx)-1)]
Sx <- 1 - qx
sx <- lx[2:len.lx]/lx[1:(len.lx-1)]
mx <- 1 - sx
Lx <- (lx[1:(len.lx-1)] + lx[2:len.lx])/2
ex <- rev(cumsum(rev(Lx)))/lx[-len.lx]
ex.avg <- ex + x[-len.lx]
# set SD for Sx
Sx.sd <- 0.05 # can set to any value
# fertility (Walker et al. 2006)
primiparity.walker <- c(17.7,18.7,19.5,18.5,18.5,18.7,25.7,19,20.5,18.8,17.8,18.6,22.2,17,16.2,18.4)
prim.mean <- round(mean(primiparity.walker),0)
prim.lo <- round(quantile(primiparity.walker,probs=0.025),0)
prim.hi <- round(quantile(primiparity.walker,probs=0.975),0)
dat.world13 <- read.table("world2013lifetable.csv", header=T, sep=",")
fert.world13 <- dat.world13$m.f
fert.trunc <- fert.world13[1:(longev+1)]
pfert.trunc <- fert.trunc/sum(fert.trunc)
fert.bentley <- 4.69/2 # Bentley 1985 for !Kung
fert.vec <- fert.bentley * pfert.trunc
## construct matrix
stages <- len.lx
popmat <- matrix(0,nrow=stages,ncol=stages)
colnames(popmat) <- x
rownames(popmat) <- x
## populate matrix
popmat[1,] <- fert.vec
diag(popmat[2:stages,]) <- Sx
popmat[stages,stages] <- 0 # Sx[stages-1]
popmat.orig <- popmat ## save original matrix
## matrix properties
r.ann <- max.r(popmat) # rate of population change, 1-yr
gen.l <- G.val(popmat,stages) # mean generation length
## for r.max (set Sx=1)
Sx.1 <- Sx
Sx.1[] <- 1
popmat.max <- popmat.orig
diag(popmat.max[2:stages,]) <- Sx.1
popmat.max[stages,stages] <- 0 # Sx[stages-1]
#max.lambda(popmat.max) ## 1-yr lambda
rm.ann <- max.r(popmat.max) # rate of population change, 1-yr
gen.l <- G.val(popmat,stages) # mean generation length
### population dynamics parameters
# dynamical model
# Nt+1 = Nt * exp(rm*(1-(Nt/K))) - (E - I)
lambda.ann <- exp(r.ann) # annual lambda
lambda.max.ann <- exp(rm.ann)
rm.max.NEE <- log(lambda.max.ann^gen.l) # human rmax at generational scale (from Sx=1 Leslie matrix)
# Cole's allometric calculation (high)
alpha.Ab <- 15
a.Cole <- -0.16
a.lo.Cole <- -0.41
a.up.Cole <- 0.10
a.sd.Cole <- mean(c((a.Cole - a.lo.Cole)/1.96, (a.up.Cole - a.Cole)/1.96))
b.lo.Cole <- -1.2
b.up.Cole <- -0.79
b.Cole <- -0.99
b.sd.Cole <- mean(c((b.Cole - b.lo.Cole)/1.96, (b.up.Cole - b.Cole)/1.96))
r.max.Cole <- 10^(a.Cole + b.Cole*log10(alpha.Ab)) # from Hone et al. 2003-JApplEcol
r.max.lo.Cole <- 10^(a.lo.Cole + b.lo.Cole*log10(alpha.Ab))
r.max.up.Cole <- 10^(a.up.Cole + b.up.Cole*log10(alpha.Ab))
r.max.up.gen.Cole <- log((exp(r.max.up.Cole))^gen.l)
r.max.gen.Cole <- log((exp(r.max.Cole))^gen.l)
r.max.lo.gen.Cole <- log((exp(r.max.lo.Cole))^gen.l)
r.max.gen.Cole.sd <- mean(c((r.max.gen.Cole - r.max.lo.gen.Cole)/1.96, (r.max.up.gen.Cole - r.max.gen.Cole)/1.96))
## dispersal calculations
# natal dispersal distance function (from Sutherland et al. 2000 Conserv Biol)
# median
a.mid <- 1.45
b.mid <- 0.54
a.lo <- a.mid - 1.05
a.up <- a.mid + 1.05
b.lo <- b.mid - 0.01
b.up <- b.mid + 0.01
M <- 50 # average mass of hunter-gatherer adult
D.med.lo <- a.lo*M^b.lo
D.med.up <- a.up*M^b.up
D.vec <- 1:round((D.vec.mult*10*111/2), 0)
Pr.Dmed.lo <- exp(-D.vec/D.med.lo)
Pr.Dmed.up <- exp(-D.vec/D.med.up)
# max
A.mid <- 3.31
B.mid <- 0.65
A.lo <- A.mid - 1.17
A.up <- A.mid + 1.17
B.lo <- B.mid - 0.05
B.up <- B.mid + 0.05
D.max.lo <- A.lo*M^B.lo
D.max.up <- D.vec.mult*A.up*M^B.up
Pr.Dmx.lo <- exp(-D.vec/D.max.lo)
Pr.Dmx.up <- exp(-D.vec/D.max.up)
cellD <- D.vec/(111/2)
disp.max.out <- data.frame(cellD,Pr.Dmx.lo,Pr.Dmx.up)
## Hiscock rainfall-territory size relationsip (2008)
terr.rain <- read.table("territory.rainfall.Hiscock.csv", header=T, sep=",")
fit.terr.rain <- lm(log10(terr.rain$terrkm2) ~ log10(terr.rain$annrainmm))
fit.dispkm.rain <- lm(log10(terr.rain$terr.rkm) ~ log10(terr.rain$annrainmm))
## make rainfall relative to minimum
fit.dispkm.rain <- lm(log10(terr.rain$terr.rkm) ~ log10(terr.rain$annrainmm/min(terr.rain$annrainmm)))
yDmaxup <- (log10(D.max.up) - as.numeric(coef(fit.dispkm.rain)[1]))/as.numeric(coef(fit.dispkm.rain)[2])
yDminlo <- (log10(D.med.lo) - as.numeric(coef(fit.dispkm.rain)[1]))/as.numeric(coef(fit.dispkm.rain)[2])
hiscock.out <- data.frame(terr.rain$annrainmm/min(terr.rain$annrainmm), log10(terr.rain$terr.rkm))
## Binford's environmental and hunter-gatherer frames of reference (Binford 2001)
## to estimate effect of rugosity on dispersal
binforddat = NULL
binforddat$annual_move <- LRB$dismov
binforddat$annual_rain <- LRB$bio.12
binforddat$ID <- seq(1:length(binforddat$annual_rain))
binford.dat <- as.data.frame(binforddat)
binford.dat$altitude_max <- LRB$h25
binford.dat$altitude_min <- LRB$l25
binford.dat$altitude_dif <- binford.dat$altitude_max - binford.dat$altitude_min
binford.dat <- binford.dat[complete.cases(binford.dat),]
binford.dat <- binford.dat [binford.dat$altitude_dif>0,] # remove the one case with negative altitude difference
# cube root
binford.dat$annual_move_tr <- binford.dat$annual_move^(1/3)
binford.dat$annual_rain_tr <- binford.dat$annual_rain^(1/3)
binford.dat$altitude_dif_tr <- binford.dat$altitude_dif^(1/3)
resis <- lm(annual_move_tr ~ + annual_rain + altitude_dif_tr, data = binford.dat)
altdiff.vec <- seq(from=range(binford.dat$altitude_dif)[1], to=range(binford.dat$altitude_dif)[2], by=1)
altdiff.st <- altdiff.vec / max(altdiff.vec)
annmov.pred <- (coef(resis)[1] + (altdiff.vec^(1/3) * coef(resis)[3]^3) + (mean(binford.dat$annual_rain, na.rm=T) * coef(resis)[2]))^3
annmov.st <- annmov.pred / max(annmov.pred)
altmov.dat <- data.frame(altdiff.st, annmov.st)
# exponential decay function fit
# y=a+b(x)^(1/3)
param.init <- c(1, -0.01)
fit.expd <- nls(annmov.st ~ a + b*(altdiff.st)^(1/3),
data = altmov.dat,
algorithm = "port",
start = c(a = param.init[1], b = param.init[2]),
trace = TRUE,
nls.control(maxiter = 1000, tol = 1e-05, minFactor = 1/1024))
altdiff.st.vec <- seq(0,1,0.01)
pred.annmov.st <- as.numeric(coef(fit.expd)[1]) + as.numeric(coef(fit.expd)[2]) * (altdiff.st.vec)^(1/3)
## distance to water (based on modern-day water distribution; Damien O'grady)
dir.tmp <- pwd()
rastlist <- list.files(path = dir.tmp, pattern='.tif$', all.files=TRUE, full.names=FALSE)
allrasters <- lapply(rastlist, raster)
d2w <- read.table("Distance2Freshwater.csv", header=T, sep=",") # 0.5 deg lat resolution / units in dd
d2w.sah <- d2w[sah.keep,]
## data from Fagan & Holmes to estimate > mortality rate < MVP size
max.r.decl <- c(-3.24, -1.09, -1.96, -2.28, -0.69, -0.68, -1.88, -1.76, -2.05)
max.lam.decl <- exp(max.r.decl)
########################################################
########################################################
########################################################
## start diffusion model - iterate for average output ##
########################################################
########################################################
########################################################
### date of first colonisation?
entry.date <- 50000
### how many generations to run?
gen.run <- 300 # number of generations to run
### choose linear relationship between NPP and K, or 180 deg-rotated parabolic relationship
#K.NPP <- "linear"
K.NPP <- "rotated parabolic"
#K.NPP <- "rotated quadratic yield density"
## K reduction scalar
#modify.K <- "yes"
modify.K <- "no"
if (modify.K == "yes") {
Kreduce <- 0.75 # if yes, by how much?
}
### for unknown SDs, choose % of mean (i.e., for M.cat.sd, pmov.sd, rm.max.NEE.sd)
#SD.prop.xbar <- 0.05 # 5%
SD.prop.xbar <- 0.10 # 10%
# impose higher extinction probability below MVP size
small.pop.ext <- "yes"
#small.pop.ext <- "no"
#MVP.thresh <- 100 # increase mortality in cells with N < MVP.thresh
#ltMVP.red <- 0.2 # mean (beta resampled) additional mortality expected for cells meeting criteria
### choose low (2*NEE estimate) or high (generationally scaled Cole's estimate from alpha) rmax
rmax.sel <- "low" # more defensible
#rmax.sel <- "high" # seems unrealistically high
### if a lake is present, how much to reduce K in that grid (0 = 0 K; 1 = full K)?
lake.red <- 0.01 # cannot be zero
### max long-distance dispersal modifier
ldp.mult <- 1 # modify to deviate from theoretical expectations (0 - ∞)
## modifier of maximum ruggedness effect on movement
#rugmov.mod <- 1
## set resistance of landscape for distance-to-water function
#watmovresist <- 3 # from Saltré et al. 2009 Ecol Model
### apply catastrophe function (Reed et al. 2005)?
catastrophe <- "yes"
#catastrophe <- "no"
pop.adjacency <- 0 # to account for 'population' area of influence, in incrementing neighbourhood (1 = immediate neighbours; 2 = 2 cells away in every direction, ...)
cat.pr <- 0.14/((2*pop.adjacency+1)^2) # probability of catastrophe per generation (Reed et al. 2003) = 0.14, modified by adjacency from above
M.cat.sd <- SD.prop.xbar*M.cat # sd mortality during a catastrophe event
### are catastrophe's spatially clustered?
spatial.cluster <- "yes"
#spatial.cluster <- "no"
# generate a random point pattern (Thomas cluster process)
rpp.scale <- 0.015 # controls intensity of clustering (lower values = more clustering)
kappa.mod <- 1 # modifies Thomas cluster process kappa upward or downward; ~ simulates changes to Pr(catastrophe)
### pick entry cell
#start.col1 <- 45; start.row1 <- 1 # north of Bird's head, N Guinea
#start.col1 <- 40; start.row1 <- 4 # west of Bird's head, N Guinea
#start.col1 <- 38; start.row1 <- 21 # N Sahul shelf
start.col1 <- 31; start.row1 <- 27 # S Sahul shelf
#start.col1 <- 8; start.row1 <- 58 # SWA
#start.col1 <- 87; start.row1 <- 59 # SNSW
start.col2 <- 40; start.row2 <- 4 # west of Bird's head, N Guinea (just to initialise; not required in some situations)
if (entry.date > 75000 & start.col1 == 31) {
start.col1 <- 32}
### add secondary colonisation event?
second.col <- "no"
#second.col <- "yes"
### lag between first and second colonisation events
lag.l <- 1000 # lag (between 1st & 2nd colonisation events) length?
lag.n <- 0 # how many lag increments?
start.time2 <- ifelse((lag.n * round(lag.l/gen.l)) == 0, 1, (lag.n * round(lag.l/gen.l))) # generations after first colonisation event (increments of ~ lag years)
if (second.col == "yes") {
#start.col2 <- 38; start.row2 <- 21 # N Sahul shelf
#start.col2 <- 31; start.row2 <- 27 # S Sahul shelf
start.col2 <- 40; start.row2 <- 4 # west of Bird's head, N Guinea
}
if (entry.date > 75000 & start.col2 == 31) {
start.col2 <- 32}
# add this to jpg file names for scenario description
name.add <- paste(entry.date/1000, "ka.", gen.run, "gen.", ifelse(K.NPP=="rotated quadratic yield density", "rqydK", ifelse(K.NPP=="linear", "linK", "parK")), ".rmax", ifelse(rmax.sel == "low","-lo","-hi"), ifelse(ldp.mult != 1, paste(".ldispmod", ldp.mult, sep=""), ""), ifelse(catastrophe=="yes",".CAT", ".NOCAT"), M.cat*100, ifelse(spatial.cluster=="yes",paste("cl",rpp.scale,sep=""),""), ".neigh-adj", pop.adjacency, ".", "intro", ifelse(second.col=="no",1,2), ifelse(start.row1==1, "nBH", ifelse(start.row1==4, "wBH", "SSh")), ifelse(second.col=="yes", ifelse(second.col=="yes" & start.row2==21,"-SSh", ifelse(start.row2==4, "-wBH", "-nBH")), ""), ifelse(second.col=="yes", paste("-lag", round(lag.l*lag.n/gen.l), "g", sep=""), ""), sep="")
### start founding population in 1 cell
N.found.mod <- 1
N.found.lo <- 1300*N.found.mod; N.found.up <- 1500*N.found.mod
## estimate SD of rmax according to SD proportions et above
rm.max.NEE.sd <- SD.prop.xbar * rm.max.NEE
### dispersal parameters
pmov.sd <- SD.prop.xbar*pmov.mean # sd for beta function
# update ruggedness movement function with rugmov.mod
rugmovmod.func <- function(x) {
rugmovmod <- as.numeric(coef(fit.expd)[1]) + rugmov.mod*as.numeric(coef(fit.expd)[2]) * (x)^(1/3)
return(rugmovmod=rugmovmod)
}
# npp @ entry date ka
sub.entry <- which(colnames(npp.sah) == paste("X",entry.date,sep=""))
npp.sah.entry <- npp.sah[,c(1,2,sub.entry)]
# plot raster
coordinates(npp.sah.entry) = ~ Lon + Lat
proj4string(npp.sah.entry)=CRS("+proj=longlat +datum=WGS84") # set it to lat-long
gridded(npp.sah.entry) = TRUE
npp.entry = raster(npp.sah.entry)
lim.exts <- 5
# transform to array
lz <- dim(npp.sah)[2] - 2
npp.array <- array(data=NA, dim=c(dim(raster2matrix(npp.entry)),lz))
for (k in 3:(lz+2)) {
npp.sah.k <- npp.sah[,c(1,2,k)]
coordinates(npp.sah.k) = ~ Lon + Lat
proj4string(npp.sah.k)=CRS("+proj=longlat +datum=WGS84") # set it to lat-long
gridded(npp.sah.k) = TRUE
npp.k = raster(npp.sah.k)
npp.array[,,k-2] <- raster2matrix(npp.k)
}
## calculate all Ks as relative to current
npp.sah.rel <- npp.array
for (z in 1:lz) {
npp.sah.rel[,,z] <- npp.array[,,z] / npp.array[,,3]
}
npp.sah.rel[,,3] <- npp.array[,,1]
# npp to K
hum.dens.med <- 6.022271e-02
hum.dens.lq <- 3.213640e-02
hum.dens.uq <- 1.439484e-01
hum.dens.max <- 1.152206e+00
hum.dens.min <- 1.751882e-02
cell.area <- (111.12/2)*(111.12/2) # km2
# create vector of K reduction scalars for projection interval
if (modify.K == "yes") {
Kreduce.vec <- stoch.n.beta.func(lz, Kreduce, 0.05*Kreduce)
}
if (modify.K == "no") {
Kreduce <- rep(1,lz)
}
# modify underlying K magnitude by modifying NPP across the board
K.array <- npp.sah.rel
for (z in 1:lz) {
K.array[,,z] <- rscale(npp.array[,,z], round(hum.dens.min*cell.area, 0), round(hum.dens.max*cell.area, 0), min(npp.array[,,z], na.rm=T), max(npp.array[,,z], na.rm=T))
}
# 180-deg rotated parabola
# y = a(x - h)^2 + k
# h = median NPP; k = max K; a = negative for 180 flipped
k.Kmax <- max(K.array, na.rm=T)/2
h.NPPmed <- mean(npp.array, na.rm=T)
h.NPPmed <- mean(range(npp.array, na.rm=T))
Kmin <- min(K.array, na.rm=T)
NPP.seq <- seq(min(npp.array, na.rm=T), max(npp.array, na.rm=T), 0.01)
K.parab.pred <- (-3 * (NPP.seq - h.NPPmed)^2) + k.Kmax
K.parab.pred.rescale <- rscale(K.parab.pred, round(hum.dens.min*cell.area, 0), 0.5*round(hum.dens.max*cell.area, 0), min(K.parab.pred), max(K.parab.pred))
# slow exponential increase combined with peak
# reciprocal quadratic yield density
# y = x/(a + b*x + c*x^2)
# y = K, x = NPP
a.rqyd <- 200; b.rqyd <- 0.60; c.rqyd <- 0.2
K.rqyd.pred <- a.rqyd * exp(-(NPP.seq-b.rqyd)^2/(2*c.rqyd^2))
K.rqyd.pred.rescale <- rscale(K.rqyd.pred, round(hum.dens.min*cell.area, 0), 0.5*round(hum.dens.max*cell.area, 0), min(K.rqyd.pred), max(K.rqyd.pred))
K.lin.x <- c(min(npp.array, na.rm=T), max(npp.array, na.rm=T))
K.lin.y <- c(min(K.array, na.rm=T), max(K.array, na.rm=T))
fit.K.lin <- lm(K.lin.y ~ K.lin.x)
K.lin.pred <- as.numeric(coef(fit.K.lin)[1]) + as.numeric(coef(fit.K.lin)[2])*NPP.seq
# rotated parabolic
K.array.parab <- (-3 * (npp.array - h.NPPmed)^2) + k.Kmax
K.array.parab.rescale <- K.array.parab
for (z in 1:lz) {
K.array.parab.rescale[,,z] <- rscale(K.array.parab[,,z], round(hum.dens.min*cell.area, 0), round(hum.dens.max*cell.area, 0), min(K.array.parab[,,z], na.rm=T), max(K.array.parab[,,z], na.rm=T))
}
# reciprocal quadratic yield density
K.array.rqyd <- a.rqyd * exp(-(npp.array - b.rqyd)^2 / (2*c.rqyd^2))
K.array.rqyd.rescale <- K.array.rqyd
for (z in 1:lz) {
K.array.rqyd.rescale[,,z] <- rscale(K.array.rqyd[,,z], round(hum.dens.min*cell.area, 0), round(hum.dens.max*cell.area, 0), min(K.array.rqyd[,,z], na.rm=T), max(K.array.rqyd[,,z], na.rm=T))
}
# rescale so that parabolic total K = linear total K
hist.K.array <- hist(K.array, br=12)
hist.K.array.dat <- data.frame(hist.K.array$mids, hist.K.array$density)
# rescale K.array.parab.rescale to same sum as K.array (distribution of Ks = same total)
K.array.parab.rescale2 <- K.array.parab.rescale / (sum(K.array.parab.rescale, na.rm=T)/sum(K.array, na.rm=T))
K.parab.pred.rescale2 <- K.parab.pred.rescale / (sum(K.array.parab.rescale, na.rm=T)/sum(K.array, na.rm=T))
hist.K.parab.pred.rescale2 <- hist(K.parab.pred.rescale2,br=12)
hist.K.parab.pred.rescale2.dat <- data.frame(hist.K.parab.pred.rescale2$mids, hist.K.parab.pred.rescale2$density)
# rescale so that rotated quadratic yield density total K = linear total K
# rescale K.array.parab.rescale to same sum as K.array (distribution of Ks = same total)
K.array.rqyd.rescale2 <- K.array.rqyd.rescale / (sum(K.array.rqyd.rescale, na.rm=T)/sum(K.array, na.rm=T))
K.rqyd.pred.rescale2 <- K.rqyd.pred.rescale / (sum(K.array.rqyd.rescale, na.rm=T)/sum(K.array, na.rm=T))
hist.K.rqyd.pred.rescale2 <- hist(K.rqyd.pred.rescale2,br=12)
hist.K.rqyd.pred.rescale2.dat <- data.frame(hist.K.rqyd.pred.rescale2$mids, hist.K.rqyd.pred.rescale2$density)
NPP.K.out <- data.frame(NPP.seq,K.lin.pred,K.parab.pred.rescale2,K.rqyd.pred.rescale2)
colnames(NPP.K.out) <- c("NPP","K.lin","K.para","K.rqyd")
# rotate matrix -90 & renumber from oldest to youngest
if (K.NPP == "linear") {
K.array.use <- K.array
}
if (K.NPP == "rotated parabolic") {
K.array.use <- K.array.parab.rescale
}
if (K.NPP == "rotated quadratic yield density") {
K.array.use <- K.array.rqyd.rescale
}
K.rot.array <- array(data=NA, c(dim(K.array.use)[2], dim(K.array.use)[1], lz))
for (z in 1:lz) {
K.rot.array[,,z] <- apply(t(K.array.use[,,142-z]),2,rev)
}
if (modify.K == "yes") {
for (z in 1:lz) {
K.rot.array[,,z] <- K.rot.array[,,z] * Kreduce.vec[z]
}
}
## block out Indonesia & never-connected islands (make NA)
K.rot.array[1:20, 1:39, ] <- NA
K.rot.array[6:20, 40:44, ] <- NA
K.rot.array[9:17, 45:46, ] <- NA
K.rot.array[21:22, 24:33, ] <- NA
K.rot.array[27:28, 24:26, ] <- NA
K.rot.array[34:35, 77:83, ] <- NA
K.rot.array[22:23, 85:87, ] <- NA
K.rot.array[18, 84:85, ] <- NA
K.rot.array[9:12, 77:86, ] <- NA
K.rot.array[2:6, 70:87, ] <- NA
K.rot.array[20, 71, ] <- NA
K.rot.array[2, 52, ] <- NA
# block passage to Tasmania (70 to 67K; 60 to 46K; 43-42K cannot cross)
K.rot.array[80, 68:77, c(71:101)] <- NA
K.rot.array[79, 68:77, c(71:101)] <- NA
# interpolate between 1000-year NPP intervals per human generation
# interpolate Ks at gen.l intervals between 1000-yr slices
mill.gen.div <- round(1000/gen.l, 0)
subtentry <- dim(K.rot.array)[3] - (entry.date/1000)
Kentry.array <- K.rot.array[,,subtentry:(dim(K.rot.array)[3])]
K.start <- entry.date
K.end <- 0
yr.proj.vec <- seq(K.start, K.end, -round((1000/mill.gen.div),0))
Kentry.interp.array <- array(data=0, dim=c(dim(Kentry.array[,,1])[1],dim(Kentry.array[,,1])[2],length(yr.proj.vec)))
mill.vec <- seq(K.start,K.end,-1000)
for (i in 1:dim(Kentry.array)[1]) {
for (j in 1:dim(Kentry.array)[2]) {
if (length(which(is.na(Kentry.array[i,j,]))==T) < (dim(Kentry.array)[3]-1))
Kentry.interp.array[i,j,] <- approx(mill.vec, Kentry.array[i,j,], xout=yr.proj.vec, method="linear")$y
else {
Kentry.interp.array[i,j,] <- rep(NA, length(yr.proj.vec))
}
}
}
# transform sea level & palaeo-lakes file (sll) to an array
lz <- dim(sll.sah)[2] - 2
sll.array <- array(data=NA, dim=c(dim(raster2matrix(npp.entry)),lz))
for (k in 3:(lz+2)) {
sll.sah.k <- sll.sah[,c(1,2,k)]
coordinates(sll.sah.k) = ~ Lon + Lat
proj4string(sll.sah.k)=CRS("+proj=longlat +datum=WGS84") # set it to lat-long
gridded(sll.sah.k) = TRUE
sll.k = raster(sll.sah.k)
sll.array[,,k-2] <- raster2matrix(sll.k)
}
# example plots (entry & another)
# rotate matrix -90 & renumber from oldest to youngest
sll.rot.array <- array(data=NA, c(dim(sll.array)[2], dim(sll.array)[1], lz))
for (z in 1:lz) {
sll.rot.array[,,z] <- apply(t(sll.array[,,142-z]),2,rev)
}
## copy values between 1000-yr intervals
sllentry.array <- sll.rot.array[,,subtentry:(dim(sll.rot.array)[3])]
sllentry.copy.array <- array(data=0, dim=c(dim(sllentry.array[,,1])[1],dim(sllentry.array[,,1])[2],length(yr.proj.vec)))
for (i in 1:dim(sllentry.array)[1]) {
for (j in 1:dim(sllentry.array)[2]) {
if (length(which(is.na(sllentry.array[i,j,]))==T) < (dim(sllentry.array)[3]-1))
sllentry.copy.array[i,j,] <- approx(mill.vec, sllentry.array[i,j,], xout=yr.proj.vec, method="linear")$y
else {
sllentry.copy.array[i,j,] <- rep(NA, length(yr.proj.vec))
}
}
}
# transform distance to water file (d2w) to an array
lz <- dim(d2w.sah)[2] - 2
d2w.array <- array(data=NA, dim=c(dim(raster2matrix(npp.entry)),lz))
for (k in 3:(lz+2)) {
d2w.sah.k <- d2w.sah[,c(1,2,k)]
coordinates(d2w.sah.k) = ~ Lon + Lat
proj4string(d2w.sah.k)=CRS("+proj=longlat +datum=WGS84") # set it to lat-long
gridded(d2w.sah.k) = TRUE
d2w.k = raster(d2w.sah.k)
d2w.array[,,k-2] <- raster2matrix(d2w.k)
}
# just use matrix
d2w.mat <- t(as.matrix(d2w.array[,,1]))
# transform ruggedness file to array
lz <- dim(rug.sah)[2] - 2
rug.array <- array(data=NA, dim=c(dim(raster2matrix(npp.entry)),lz))
for (k in 3:(lz+2)) {
rug.sah.k <- rug.sah[,c(1,2,k)]
coordinates(rug.sah.k) = ~ Lon + Lat
proj4string(rug.sah.k)=CRS("+proj=longlat +datum=WGS84") # set it to lat-long
gridded(rug.sah.k) = TRUE
rug.k = raster(rug.sah.k)
rug.array[,,k-2] <- raster2matrix(rug.k)
}
# rescale rugosity from 0-1
rug.array.rescale <- rug.array
for (z in 1:lz) {
rug.array.rescale[,,z] <- rscale(rug.array[,,z], 0, 1, min(rug.array[,,z], na.rm=T), max(rug.array[,,z], na.rm=T))
}
# rotate matrix -90 & renumber from oldest to youngest
rug.rot.array <- array(data=NA, c(dim(rug.array.rescale)[2], dim(rug.array.rescale)[1], lz))
for (z in 1:lz) {
rug.rot.array[,,z] <- apply(t(rug.array.rescale[,,142-z]),2,rev)
}
## interpolate between 1000-yr intervals
rugentry.array <- rug.rot.array[,,subtentry:(dim(rug.rot.array)[3])]
rugentry.interp.array <- array(data=0, dim=c(dim(rugentry.array[,,1])[1],dim(rugentry.array[,,1])[2],length(yr.proj.vec)))
for (i in 1:dim(rugentry.array)[1]) {
for (j in 1:dim(rugentry.array)[2]) {
if (length(which(is.na(rugentry.array[i,j,]))==T) < (dim(rugentry.array)[3]-1))
rugentry.interp.array[i,j,] <- approx(mill.vec, rugentry.array[i,j,], xout=yr.proj.vec, method="linear")$y
else {
rugentry.interp.array[i,j,] <- rep(NA, length(yr.proj.vec))
}
}
}
# spatial clustering of catastraphe events controlling parameters
kappa.mult <- 0.9
cellslo <- 1
cellshi <- 3772
kappa.mult.up <- 1.2*kappa.mod
kappa.mult.lo <- 0.3*kappa.mod
kappa.rep <- seq(kappa.mult.up,kappa.mult.lo,-(kappa.mult.up-kappa.mult.lo)/cellshi)
cells.rep <- seq(cellslo,cellshi, (cellshi-cellslo)/cellshi)
kappa.fit <- lm(kappa.rep ~ cells.rep)
kappaP.func <- function(cells.occ) {
kappa.pred <- (as.numeric(coef(kappa.fit)[1])) + as.numeric(coef(kappa.fit)[2])*cells.occ
return(kappa.pred)
}
rpp.mu.mult <- 0.6 # this, with the fluctuating kappa multiplier, keeps overall mean proportion of cells experiencing catastrophic mortality ~ 0.14
for (m in 1:iter) {
# set up NA array
NA.array <- Kentry.interp.array * 0
NA.array <- NA.array[,,1:(gen.run+1)]
# set direction codes
dir.vec <- c("NW", "N", "NE", "W", "E", "SW", "S", "SE")
# set up N array
array.N <- Kentry.interp.array * 0
array.N <- array.N[,,1:(gen.run+1)]
# set up direction array (dominant direction of influx)
dir.array <- array.N
array.N[start.row1, start.col1, 1] <- round(runif(1, N.found.lo, N.found.up), 0)
# log10 relative K array
Kentry.interp.lrel.array <- log10(Kentry.interp.array / min(Kentry.interp.array, na.rm=T)) # log10 relative K
## assume same slope between relative NPP and radius movement
disp.npp.slope <- as.numeric(coefficients((fit.dispkm.rain))[2])
disp.npp.int <- as.numeric(coefficients((fit.dispkm.rain))[1])
#disp.npp.max.int <- 1.6646371
disp.npp.max.int <- disp.npp.int + (log10(D.max.up) - disp.npp.int) # move intercept to account for shift from median to max D
i.rows <- dim(array.N[,,1])[1]
j.cols <- dim(array.N[,,1])[2]
z.layers <- dim(array.N)[3]
# storage vectors
N.vec <- poparea.vec <- pc.complete <- cat.pr.est <- rep(0,z.layers)
N.vec[1] <- array.N[start.row1,start.col1,1]
if (second.col == "yes") {
N.vec[start.time2] <- array.N[start.row1,start.col1,start.time2]
}
poparea.vec[1] <- cell.area/1000
proc.start <- proc.time()
#############################
## project
for (t in 1:(z.layers-1)) {
# Poisson-resampled K matrix
Kentry.interp.poiss <- outer(1:nrow(round(Kentry.interp.array[,,t],0)), 1:ncol(round(Kentry.interp.array[,,t],0)), rpois.vec.fun, round(Kentry.interp.array[,,t],0))
# reduce Ks if lake present
Kentry.interp.pois <- Kentry.interp.poiss
for (i in 1:i.rows) { # i rows
for (j in 1:j.cols) { # j columns
Kentry.interp.pois[i,j] <- ifelse(sllentry.copy.array[i,j,t] > 1, lake.red * Kentry.interp.poiss[i,j], Kentry.interp.poiss[i,j])
}
}
# step through array in t for immigration & emigration
for (i in 1:i.rows) { # i rows
for (j in 1:j.cols) { # j columns
if (second.col == "yes") {
if (t == start.time2) {
array.N[start.row2, start.col2, start.time2] <- round(runif(1, N.found.lo, N.found.up), 0)
}
}
# set cell-cell gradients relative to focal cell
NW.RK <- ifelse(i > 1 & j > 1, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i-1,j-1]) > 0, Kentry.interp.pois[i-1,j-1], NA)), NA) # NW
N.RK <- ifelse(i > 1, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i-1,j]) > 0, Kentry.interp.pois[i-1,j], NA)), NA) # N
NE.RK <- ifelse(i > 1 & j < j.cols, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i-1,j+1]) > 0, Kentry.interp.pois[i-1,j+1], NA)), NA) # NE
W.RK <- ifelse(j > 1, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i,j-1]) > 0, Kentry.interp.pois[i,j-1], NA)), NA) # W
E.RK <- ifelse(j < j.cols, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i,j+1]) > 0, Kentry.interp.pois[i,j+1], NA)), NA) # E
SW.RK <- ifelse(i < i.rows & j > 1, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i+1,j-1]) > 0, Kentry.interp.pois[i+1,j-1], NA)), NA) # SW
S.RK <- ifelse(i < i.rows, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i+1,j]) > 0, Kentry.interp.pois[i+1,j], NA)), NA) # S
SE.RK <- ifelse(i < i.rows & j < j.cols, (Kentry.interp.pois[i,j] / ifelse(length(Kentry.interp.pois[i+1,j+1]) > 0, Kentry.interp.pois[i+1,j+1], NA)), NA) # SE
## current population distances from K in each cell
focal.dK1 <- array.N[i,j,t] / Kentry.interp.pois[i,j]
NW.dK1 <- ifelse(i > 1 & j > 1, array.N[i-1,j-1,t] / Kentry.interp.pois[i-1,j-1], NA)
N.dK1 <- ifelse(i > 1, array.N[i-1,j,t] / Kentry.interp.pois[i-1,j], NA)
NE.dK1 <- ifelse(i > 1 & j < j.cols, array.N[i-1,j+1,t] / Kentry.interp.pois[i-1,j+1], NA)
W.dK1 <- ifelse(j > 1, array.N[i,j-1,t] / Kentry.interp.pois[i,j-1], NA)
E.dK1 <- ifelse(j < j.cols, array.N[i,j+1,t] / Kentry.interp.pois[i,j+1], NA)
SW.dK1 <- ifelse(i < i.rows & j > 1, array.N[i+1,j-1,t] / Kentry.interp.pois[i+1,j-1], NA)
S.dK1 <- ifelse(i < i.rows, array.N[i+1,j,t] / Kentry.interp.pois[i+1,j], NA)
SE.dK1 <- ifelse(i < i.rows & j < j.cols, array.N[i+1,j+1,t] / Kentry.interp.pois[i+1,j+1], NA)
focal.dK <- ifelse(focal.dK1 == 0 | is.na(focal.dK1) == T, 0, focal.dK1)
NW.dK <- ifelse(length(NW.dK1) == 0 | is.na(NW.dK1) == T, 0, NW.dK1)
N.dK <- ifelse(length(N.dK1) == 0 | is.na(N.dK1) == T, 0, N.dK1)
NE.dK <- ifelse(length(NE.dK1) == 0 | is.na(NE.dK1) == T, 0, NE.dK1)
W.dK <- ifelse(length(W.dK1) == 0 | is.na(W.dK1) == T, 0, W.dK1)
E.dK <- ifelse(length(E.dK1) == 0 | is.na(E.dK1) == T, 0, E.dK1)
SW.dK <- ifelse(length(SW.dK1) == 0 | is.na(SW.dK1) == T, 0, SW.dK1)
S.dK <- ifelse(length(S.dK1) == 0 | is.na(S.dK1) == T, 0, S.dK1)
SE.dK <- ifelse(length(SE.dK1) == 0 | is.na(SE.dK1) == T, 0, SE.dK1)
# direction indices initialised as NA
NWdir <- Ndir <- NEdir <- Wdir <- Edir <- SWdir <- Sdir <- SEdir <- NA
# immigration into focal cell
if (is.na(NW.RK) == F & NW.RK > 1 & NW.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
NW.I <- (pI.func(NW.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i-1,j-1,t] * (rugmovmod.func(rugentry.interp.array[i-1,j-1,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], NW.I), na.rm=T)
array.N[i-1,j-1,t] <- sum(c(array.N[i-1,j-1,t], -NW.I), na.rm=T)
NWdir <- ifelse(is.na(NW.RK) == F & NW.RK > 1, NW.I, NA)}
if (is.na(N.RK) == F & N.RK > 1 & N.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
N.I <- (pI.func(N.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i-1,j,t] * (rugmovmod.func(rugentry.interp.array[i-1,j,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], N.I), na.rm=T)
array.N[i-1,j,t] <- sum(c(array.N[i-1,j,t], -N.I), na.rm=T)
Ndir <- ifelse(is.na(N.RK) == F & N.RK > 1, N.I, NA)}
if (is.na(NE.RK) == F & NE.RK > 1 & NE.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
NE.I <- (pI.func(NE.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i-1,j+1,t] * (rugmovmod.func(rugentry.interp.array[i-1,j+1,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], NE.I), na.rm=T)
array.N[i-1,j+1,t] <- sum(c(array.N[i-1,j+1,t], -NE.I), na.rm=T)
NEdir <- ifelse(is.na(NE.RK) == F & NE.RK > 1, NE.I, NA)}
if (is.na(W.RK) == F & W.RK > 1 & W.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
W.I <- (pI.func(W.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j-1,t] * (rugmovmod.func(rugentry.interp.array[i,j-1,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], W.I), na.rm=T)
array.N[i,j-1,t] <- sum(c(array.N[i,j-1,t], -W.I), na.rm=T)
Wdir <- ifelse(is.na(W.RK) == F & W.RK > 1, W.I, NA)}
if (is.na(E.RK) == F & E.RK > 1 & E.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
E.I <- (pI.func(E.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j+1,t] * (rugmovmod.func(rugentry.interp.array[i,j+1,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], E.I), na.rm=T)
array.N[i,j+1,t] <- sum(c(array.N[i,j+1,t], -E.I), na.rm=T)
Edir <- ifelse(is.na(E.RK) == F & E.RK > 1, E.I, NA)}
if (is.na(SW.RK) == F & SW.RK > 1 & SW.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
SW.I <- (pI.func(SW.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i+1,j-1,t] * (rugmovmod.func(rugentry.interp.array[i+1,j-1,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], SW.I), na.rm=T)
array.N[i+1,j-1,t] <- sum(c(array.N[i+1,j-1,t], -SW.I), na.rm=T)
SWdir <- ifelse(is.na(SW.RK) == F & SW.RK > 1, SW.I, NA)}
if (is.na(S.RK) == F & S.RK > 1 & S.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
S.I <- (pI.func(S.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i+1,j,t] * (rugmovmod.func(rugentry.interp.array[i+1,j,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], S.I), na.rm=T)
array.N[i+1,j,t] <- sum(c(array.N[i+1,j,t], -S.I), na.rm=T)
Sdir <- ifelse(is.na(S.RK) == F & S.RK > 1, S.I, NA)}
if (is.na(SE.RK) == F & SE.RK > 1 & SE.dK >= runif(1, min=NK.emig.min, max=NK.emig.max)) {
SE.I <- (pI.func(SE.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i+1,j+1,t] * (rugmovmod.func(rugentry.interp.array[i+1,j+1,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], SE.I), na.rm=T)
array.N[i+1,j+1,t] <- sum(c(array.N[i+1,j+1,t], -SE.I), na.rm=T)
SEdir <- ifelse(is.na(SE.RK) == F & SE.RK > 1, SE.I, NA)}
# direction of dominant influx per time layer
I.vec <- c(NWdir, Ndir, NEdir, Wdir, Edir, SWdir, Sdir, SEdir)
dir.array[i,j,t] <- ifelse((length(which(I.vec > 1))) > 0, (dir.vec[max(which(I.vec > 1))]), NA)
# emigration out of focal cell
if ((ifelse(focal.dK >= runif(1, min=NK.emig.min, max=NK.emig.max), 1, 0)) == 1) {
if (is.na(NW.RK) == F & NW.RK <= 1) {
NW.E <- (pE.func(NW.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t])))
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(NW.E < 0, 0, -NW.E)), na.rm=T)
array.N[i-1,j-1,t] <- sum(c(array.N[i-1,j-1,t], ifelse(NW.E < 0, 0, NW.E)), na.rm=T)}
if (is.na(N.RK) == F & N.RK <= 1) {
N.E <- (pE.func(N.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(N.E < 0, 0, -N.E)), na.rm=T)
array.N[i-1,j,t] <- sum(c(array.N[i-1,j,t], ifelse(N.E < 0, 0, N.E)), na.rm=T)}
if (is.na(NE.RK) == F & NE.RK <= 1) {
NE.E <- (pE.func(NE.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E - N.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(NE.E < 0, 0, -NE.E)), na.rm=T)
array.N[i-1,j+1,t] <- sum(c(array.N[i-1,j+1,t], ifelse(NE.E < 0, 0, NE.E)), na.rm=T)}
if (is.na(W.RK) == F & W.RK <= 1) {
W.E <- (pE.func(W.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E - N.E - NE.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(W.E < 0, 0, -W.E)), na.rm=T)
array.N[i,j-1,t] <- sum(c(array.N[i,j-1,t], ifelse(W.E < 0, 0, W.E)), na.rm=T)}
if (is.na(E.RK) == F & E.RK <= 1) {
E.E <- (pE.func(E.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E - N.E - NE.E - W.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(E.E < 0, 0, -E.E)), na.rm=T)
array.N[i,j+1,t] <- sum(c(array.N[i,j+1,t], ifelse(E.E < 0, 0, E.E)), na.rm=T)}
if (is.na(SW.RK) == F & SW.RK <= 1) {
SW.E <- (pE.func(SW.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E - N.E - NE.E - W.E - E.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(SW.E < 0, 0, -SW.E)), na.rm=T)
array.N[i+1,j-1,t] <- sum(c(array.N[i+1,j-1,t], ifelse(SW.E < 0, 0, SW.E)), na.rm=T)}
if (is.na(S.RK) == F & S.RK <= 1) {
S.E <- (pE.func(S.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E - N.E - NE.E - W.E - E.E - SW.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(S.E < 0, 0, -S.E)), na.rm=T)
array.N[i+1,j,t] <- sum(c(array.N[i+1,j,t], ifelse(S.E < 0, 0, S.E)), na.rm=T)}
if (is.na(SE.RK) == F & SE.RK <= 1) {
SE.E <- (pE.func(SE.RK) * stoch.beta.func(pmov.mean, pmov.sd) * array.N[i,j,t] * (rugmovmod.func(rugentry.interp.array[i,j,t]))) - NW.E - N.E - NE.E - W.E - E.E - SW.E - S.E
array.N[i,j,t] <- sum(c(array.N[i,j,t], ifelse(SE.E < 0, 0, -SE.E)), na.rm=T)
array.N[i+1,j+1,t] <- sum(c(array.N[i+1,j+1,t], ifelse(SE.E < 0, 0, SE.E)), na.rm=T)}
}
# reset emigration values to zero for next run
NW.E <- N.E <- NE.E <- W.E <- E.E <- SW.E <- S.E <- SE.E <- 0
# long-range dispersal
disp.prob <- (exp(-D.vec/(ifelse(Kentry.interp.lrel.array[i, j, t] >= log10(6.706985), D.max.lo, 10^(disp.npp.max.int + as.numeric(disp.npp.slope) * Kentry.interp.lrel.array[i, j, t])))))
if (is.na(disp.prob[1])==F) {
disp.prob.ran <- disp.prob}
if (is.na(disp.prob[1])==T) {
disp.prob.ran <- ((Pr.Dmx.up+Pr.Dmx.lo)/2)}
cellD.move <- ldp.mult * ((sample(cellD, size=1, replace=F, prob=disp.prob.ran)) * (2*focal.dK)) # multiply probability upwards if closer to focal cell K
# condition on distance 2 water, where
# P(reach) = 1 – ((D/max(D))^J); D = distance to water; higher J = more difficult reach gridcell; max(D) = max distance to water
if (is.na(d2w.mat[i,j]) == F & cellD.move < d2w.mat[i,j]) {
P.reach <- 1 - ((cellD.move / d2w.mat[i,j])^(watmovresist))
reach.trial <- rbinom(1, 1, prob=P.reach)
}
reach.succ <- ifelse(is.na(d2w.mat[i,j]) == F, reach.trial, 1)
if ((round(cellD.move)) > 0 & reach.succ == 1) {
dx <- sample(c(-1,1), 1) * rpois(1,(round(cellD.move)))
dy <- sample(c(-1,1), 1) * rpois(1,(round(cellD.move)))
if ((i+dy) > 0 & (i+dy) <= i.rows & (j+dx) > 0 & (j+dx) <= j.cols) {
if (length(which(is.na(array.N[(i+sign(dy)):(i+dy), (j+sign(dx)):(j+dx), t]) == T)) == 0) { # if there is an NA cell anywhere in block between [i,j] & [i+dy,j+dx], don't let dispersal happen
N.disp <- round(array.N[i, j, t] * stoch.beta.func(pmov.mean/10, pmov.sd/10) * (rugmovmod.func(rugentry.interp.array[i,j,t])), 0) # number dispersing to new cell
array.N[(i+dy), (j+dx), t] <- array.N[(i+dy), (j+dx), t] + N.disp
array.N[i, j, t] <- ifelse((array.N[i, j, t] - N.disp) < 0, 0, (array.N[i, j, t] - N.disp))
} # end if
} # end if
} # end if
} # end i loop
} # end j loop
# remove negative values
array.N[,,t] <- ifelse(array.N[,,t] < 0, 0, round(array.N[,,t], 0))
# apply dynamical model after movements from previous step
if (rmax.sel == "low") {
array.N[,,t+1] <- Nproj.func(Nt=array.N[,,t], rm=rnorm(1, rm.max.NEE, rm.max.NEE.sd), K=Kentry.interp.pois)
#array.N[,,t+1] <- Nproj.func(Nt=array.N[,,t], rm=stoch.beta.func(r.max.NEE, r.max.NEE.sd), K=Kentry.interp.pois)
}
if (rmax.sel == "high") {
array.N[,,t+1] <- Nproj.func(Nt=array.N[,,t], rm=log((exp(10^(rnorm(1, a.Cole, a.sd.Cole) + rnorm(1, b.Cole, b.sd.Cole) * log10(alpha.Ab))))^gen.l), K=Kentry.interp.pois)
}