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R/pcPriorRange.R
In geostatsp: Geostatistical Modelling with Likelihood and Bayes
Defines functions
gammaScale
addNames
gammaSd
pcPriorRange
Documented in
pcPriorRange
pcPriorRange = function(q, p=0.5, cellSize=1) {
if(!is.numeric(cellSize)) {
cellSize = xres(cellSize)
}
# suppose lower 5% quantile of rangeKm is 50km
# ... of range is 50000/cellSize
# upper 5% quantile (lower 95%) of scale is cellSize / 50000
# 1-exp(-lambda x) = 1-p
# 1-0.05 = 1-exp(-lambda * cellSize/50000)
# log(0.05) = -lambda * cellSize / 50000
# lambda = -log(0.05) * 50000/cellSize
# lambda is a multiplicative parameter
# I call lambda a scale, wikipedia and R call it rate
quantileCells = q/cellSize
lambda = -log(p) * quantileCells / log(2)
resultInla = paste0(
"expression:
lambda = ", lambda, ";
scale = exp(-log_range);
logdens = -lambda*scale + log(lambda);
log_jacobian = - log_range;
return(logdens + log_jacobian);", sep='')
result= list(
string = paste0("list(prior=\"", resultInla, "\")" ),
param = c(q = q, prob = p),
extra = list(
lambda=unname(lambda),
medianRange = unname(cellSize*lambda),
medianScale = unname(1/(cellSize*lambda)),
meanScale = unname(1/(log(2)*cellSize*lambda))),
info = 'exponential prior for scale (pc prior)',
cellSize = unname(cellSize))
result$dprior = list(
range = eval(parse(text=paste0(
'function(x) x^(-2)*stats::dexp(1/x, rate=',
1/result$extra$meanScale, ')'))),
scale = eval(parse(text=paste0(
'function(x) stats::dexp(x, rate=', 1/result$extra$meanScale, ')')))
)
environment(result$dprior$range) = baseenv()
environment(result$dprior$scale) = baseenv()
result
}
gammaSd = function(param) {
param = addNames(param)
# sd is gamma
# log(sd) is loggamma
# log(prec) = -2*log(sd) is dist'n below
# a=1/3;b=3/4;stuff = rgamma(10000, a,b)
# hist(log(stuff^(-2)), prob=TRUE)
# xseq = seq(-20, 20, len=1001)
# lines(xseq,
# exp(a*log(b) - lgamma(a) -log(2) -
# (a-1)*(xseq/2)-b*exp(-xseq/2)-xseq/2))
# f(x)= 1/(s^a Gamma(a)) x^(a-1) e^-(x/s)
if(FALSE) {
bob2 <- function(log_precision) {
a = param['shape']
b = param['rate']
dens1 = stats::dgamma(exp(-log_precision/2),
shape = param['shape'], rate = param['rate'], log=TRUE) -
log_precision/2 - log(2)
logDens = -lgamma(a) - log(2) + a*log(b) - ((a-1)/2) * log_precision -
exp(-log_precision/2)*b - log_precision/2
exp(cbind(dens1, logDens))
}
# sample sd
mySample = stats::rgamma(10001,
shape = param['shape'],
rate = param['rate'])
# histogram of log range
hist(log(mySample^(-2)), breaks=100, prob=TRUE)
logSeq = seq(-5,25,len=1001)
matlines(logSeq, bob2(logSeq), col=c('blue','red'))
}
result = list(string = paste0(
"list(prior=\"expression:",
"\n am1d2 = ", (param['shape']-1)/2,
";\n b = ", param['rate'],
";\n lngammalambda =",
-lgamma(param['shape']) - log(2) - param['shape'] * log(param['rate']),
";\n return(lngammalambda - am1d2 * log_precision -",
"b*exp(-log_precision / 2.0) - log_precision/2.0);\")"
),
param = param,
info = 'gamma prior for sd',
dprior = eval(parse(text=paste0('function(x) stats::dgamma(x, shape=',
param['shape'],',rate=', param['rate'], ')')))
)
environment(result$dprior) = baseenv()
result
}
addNames = function(param) {
if(is.null(names(param)))
names(param) = c('shape','rate')
param
}
gammaScale = function(param, cellSize) {
param = addNames(param)
# log gamma dens = - a * log(s) - loggamma(a) +
# (a-1) * log(x) -x/s
# log gamma dens = a * log(r) - loggamma(a) +
# (a-1) * log(x) -x*r
# y = log scale
# log gamma dens = a * log(r) - loggamma(a) +
# (a-1) * y -exp(y)*r
# z = log (1/scale)
# log gamma dens = a * log(r) - loggamma(a) +
# (a-1) / z - r * exp(-z)
# gsl_sf_lngamma(xx);
rangePrior = list(
param = param,
info = 'gamma prior for scale',
string = paste0(
"list(prior=\"expression:\n lambda = ", param['shape'],
";\n scale = ", param['rate'],
";\n lngammalambda = - lgamma(lambda)",
";\n return(-lngammalambda + lambda * log(scale) - (lambda - 1.0) * log_range - scale * exp(-log_range) - log_range);",
"\")"),
extra = list(
userParam = param[c('shape','rate')] * c(1,cellSize)
)
)
rangePrior$dprior = list(
range = eval(parse(text=paste0(
'function(x) x^(-2)*stats::dgamma(1/x, shape=',
rangePrior$extra$userParam['shape'],
',rate=',
rangePrior$extra$userParam['rate'], ')'))),
scale = eval(parse(text=paste0(
'function(x) stats::dgamma(x, shape=',
rangePrior$extra$userParam['shape'],
',rate=',
rangePrior$extra$userParam['rate'], ')')))
)
# should add - lgamma(a)
if(FALSE) {
bob2 <- function(log_range) {
a = param['shape']
r = param['rate']
dens1 = stats::dgamma(exp(-log_range),
shape = param['shape'], rate = param['rate'], log=TRUE) -
log_range
logDens = a * log(r) - lgamma(a) +
(a - 1.0) / log_range - r*exp(-log_range) - log_range
exp(cbind(dens1, logDens))
}
# sampe scale
mySample = rgamma(10000, shape = param['shape'], rate = param['rate'])
# histogram of log range
hist(log(1/mySample), breaks=100, prob=TRUE)
logRangeSeq = seq(-5,5,len=1001)
matlines(logRangeSeq, bob2(logRangeSeq), col=c('blue','red'))
}
rangePrior
}
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geostatsp documentation built on March 19, 2024, 3:08 a.m.
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Defines functions gammaScale addNames gammaSd pcPriorRange
Documented in pcPriorRange
pcPriorRange = function(q, p=0.5, cellSize=1) {
if(!is.numeric(cellSize)) {
cellSize = xres(cellSize)
}
# suppose lower 5% quantile of rangeKm is 50km
# ... of range is 50000/cellSize
# upper 5% quantile (lower 95%) of scale is cellSize / 50000
# 1-exp(-lambda x) = 1-p
# 1-0.05 = 1-exp(-lambda * cellSize/50000)
# log(0.05) = -lambda * cellSize / 50000
# lambda = -log(0.05) * 50000/cellSize
# lambda is a multiplicative parameter
# I call lambda a scale, wikipedia and R call it rate
quantileCells = q/cellSize
lambda = -log(p) * quantileCells / log(2)
resultInla = paste0(
"expression:
lambda = ", lambda, ";
scale = exp(-log_range);
logdens = -lambda*scale + log(lambda);
log_jacobian = - log_range;
return(logdens + log_jacobian);", sep='')
result= list(
string = paste0("list(prior=\"", resultInla, "\")" ),
param = c(q = q, prob = p),
extra = list(
lambda=unname(lambda),
medianRange = unname(cellSize*lambda),
medianScale = unname(1/(cellSize*lambda)),
meanScale = unname(1/(log(2)*cellSize*lambda))),
info = 'exponential prior for scale (pc prior)',
cellSize = unname(cellSize))
result$dprior = list(
range = eval(parse(text=paste0(
'function(x) x^(-2)*stats::dexp(1/x, rate=',
1/result$extra$meanScale, ')'))),
scale = eval(parse(text=paste0(
'function(x) stats::dexp(x, rate=', 1/result$extra$meanScale, ')')))
)
environment(result$dprior$range) = baseenv()
environment(result$dprior$scale) = baseenv()
result
}
gammaSd = function(param) {
param = addNames(param)
# sd is gamma
# log(sd) is loggamma
# log(prec) = -2*log(sd) is dist'n below
# a=1/3;b=3/4;stuff = rgamma(10000, a,b)
# hist(log(stuff^(-2)), prob=TRUE)
# xseq = seq(-20, 20, len=1001)
# lines(xseq,
# exp(a*log(b) - lgamma(a) -log(2) -
# (a-1)*(xseq/2)-b*exp(-xseq/2)-xseq/2))
# f(x)= 1/(s^a Gamma(a)) x^(a-1) e^-(x/s)
if(FALSE) {
bob2 <- function(log_precision) {
a = param['shape']
b = param['rate']
dens1 = stats::dgamma(exp(-log_precision/2),
shape = param['shape'], rate = param['rate'], log=TRUE) -
log_precision/2 - log(2)
logDens = -lgamma(a) - log(2) + a*log(b) - ((a-1)/2) * log_precision -
exp(-log_precision/2)*b - log_precision/2
exp(cbind(dens1, logDens))
}
# sample sd
mySample = stats::rgamma(10001,
shape = param['shape'],
rate = param['rate'])
# histogram of log range
hist(log(mySample^(-2)), breaks=100, prob=TRUE)
logSeq = seq(-5,25,len=1001)
matlines(logSeq, bob2(logSeq), col=c('blue','red'))
}
result = list(string = paste0(
"list(prior=\"expression:",
"\n am1d2 = ", (param['shape']-1)/2,
";\n b = ", param['rate'],
";\n lngammalambda =",
-lgamma(param['shape']) - log(2) - param['shape'] * log(param['rate']),
";\n return(lngammalambda - am1d2 * log_precision -",
"b*exp(-log_precision / 2.0) - log_precision/2.0);\")"
),
param = param,
info = 'gamma prior for sd',
dprior = eval(parse(text=paste0('function(x) stats::dgamma(x, shape=',
param['shape'],',rate=', param['rate'], ')')))
)
environment(result$dprior) = baseenv()
result
}
addNames = function(param) {
if(is.null(names(param)))
names(param) = c('shape','rate')
param
}
gammaScale = function(param, cellSize) {
param = addNames(param)
# log gamma dens = - a * log(s) - loggamma(a) +
# (a-1) * log(x) -x/s
# log gamma dens = a * log(r) - loggamma(a) +
# (a-1) * log(x) -x*r
# y = log scale
# log gamma dens = a * log(r) - loggamma(a) +
# (a-1) * y -exp(y)*r
# z = log (1/scale)
# log gamma dens = a * log(r) - loggamma(a) +
# (a-1) / z - r * exp(-z)
# gsl_sf_lngamma(xx);
rangePrior = list(
param = param,
info = 'gamma prior for scale',
string = paste0(
"list(prior=\"expression:\n lambda = ", param['shape'],
";\n scale = ", param['rate'],
";\n lngammalambda = - lgamma(lambda)",
";\n return(-lngammalambda + lambda * log(scale) - (lambda - 1.0) * log_range - scale * exp(-log_range) - log_range);",
"\")"),
extra = list(
userParam = param[c('shape','rate')] * c(1,cellSize)
)
)
rangePrior$dprior = list(
range = eval(parse(text=paste0(
'function(x) x^(-2)*stats::dgamma(1/x, shape=',
rangePrior$extra$userParam['shape'],
',rate=',
rangePrior$extra$userParam['rate'], ')'))),
scale = eval(parse(text=paste0(
'function(x) stats::dgamma(x, shape=',
rangePrior$extra$userParam['shape'],
',rate=',
rangePrior$extra$userParam['rate'], ')')))
)
# should add - lgamma(a)
if(FALSE) {
bob2 <- function(log_range) {
a = param['shape']
r = param['rate']
dens1 = stats::dgamma(exp(-log_range),
shape = param['shape'], rate = param['rate'], log=TRUE) -
log_range
logDens = a * log(r) - lgamma(a) +
(a - 1.0) / log_range - r*exp(-log_range) - log_range
exp(cbind(dens1, logDens))
}
# sampe scale
mySample = rgamma(10000, shape = param['shape'], rate = param['rate'])
# histogram of log range
hist(log(1/mySample), breaks=100, prob=TRUE)
logRangeSeq = seq(-5,5,len=1001)
matlines(logRangeSeq, bob2(logRangeSeq), col=c('blue','red'))
}
rangePrior
}
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