Nothing
R/loglikGmrf.R
In geostatsp: Geostatistical Modelling with Likelihood and Bayes
Defines functions
summaryGmrfFit.matrix
summaryGmrfFit.array
summaryGmrfFit
loglikGmrf
loglikGmrfOneRange
loglikGmrfOneRange = function(
oneminusar,
shape, NN,
adjustEdges, obsCov, xisqTausq,
reml, jacobian, control){
Q = geostatsp::maternGmrfPrec(NN,
param=c(
shape=as.vector(shape),
oneminusar=as.vector(oneminusar),
conditionalVariance=1),
adjustEdges=adjustEdges)
fromC = .Call(
C_gmrfLik,
Q,
obsCov,
as.double(xisqTausq),
reml,
as.double(jacobian),
as.double(
control$logXisqTausq[
c('lower','upper','tol')]
)
)
Nxy = ncol(obsCov)
Ny = length(jacobian)
Nobs = nrow(obsCov)
NxisqTausq = length(xisqTausq)
Nxysq = Nxy^2
logLstart = NxisqTausq*Nxysq*2
mlColNames = c('det','detReml','m2logLml',
'm2logLreml', 'profiledVarianceHatMl',
'profiledVarianceHatReml', 'xisqTausq')
mlDim = c(y=Ny,
varRatio=NxisqTausq,
output=length(mlColNames))
Lseq = 1:logLstart
result = array(
as.vector(fromC[
seq(logLstart+1, len=prod(mlDim))
]),
dim=mlDim,
dimnames=list(
colnames(obsCov)[1:Ny],
as.character(xisqTausq),
mlColNames
))
attributes(result)$ssq = array(fromC[Lseq],
dim=c(Nxy, Nxy, NxisqTausq,2),
dimnames = list(
colnames(obsCov), colnames(obsCov),
as.character(xisqTausq),
c('ssq','beta')
))
attributes(result)$param = attributes(Q)$info
result
}
loglikGmrf = function(
Yvec, Xmat, NN,
oneminusar = NULL,
propNugget=NULL,
boxcox=1,
fixBoxcox=TRUE,
seqBoxcox=outer(c(0.01, 0.02, 0.05, 0.1, 0.2, 0.5), c(-1,1)),
shape=1,
reml=TRUE,
adjustEdges=FALSE,
jacobian = 0,
control=list(
oneminusar = c(lower=1e-3, upper=0.8, tol= .Machine$double.eps^0.25),
propNugget = c(lower=1e-3, upper=1e3, tol= .Machine$double.eps^0.25)
),
mc.cores=1
) {
## something with reml and boxcox is broken
## getting Nan's in reml determinant matrix
Yvec = as.matrix(Yvec)
if(is.null(colnames(Yvec)))
colnames(Yvec) = paste("y", 1:ncol(Yvec), sep='')
Ny = ncol(Yvec)
if(Ny > 1 & !(length(oneminusar) & length(propNugget)))
stop("specify oneminusar and propNugget if there is more than one dataset in Y")
Nobs = nrow(Yvec)
Lcol = c('m2logLml', 'm2logLreml')[reml+1]
# boxcox
if(!fixBoxcox){
seqBoxcox = sort(unique(c(0, seqBoxcox)))
if(Ny>1) warning("need fixBoxcox=TRUE if Y has more than one column")
bcStuff = forBoxCox(y=Yvec,x=Xmat,seqBoxCox=seqBoxcox)
Ny = ncol(bcStuff$y)
Yvec = bcStuff$y
jacobian = bcStuff$jacobian
boxcox=bcStuff$boxcox
} else {
if(length(jacobian)==1)
jacobian = rep(jacobian, Ny)
if(length(boxcox)==1){
boxcox = rep(boxcox, Ny)
}
}
profBC = NULL # store profile likelihood of box-cox parameter
if(length(jacobian)!= Ny | length(boxcox)!= Ny)
warning('length of jacobian or boxcox must be same as columns of Y')
if(is.null(colnames(Xmat))) colnames(Xmat) = paste('cov', 1:ncol(Xmat), sep='')
obsCov = as.matrix(cbind(Yvec, Xmat))
if(length(propNugget))
propNugget = sort(unique(c(0, propNugget)))
xisqTausq = 1/propNugget
xisqTausq[!is.finite(xisqTausq)] = 0
Nxysq = ncol(obsCov)^2
mlColNames = c(
'det','detReml','m2logLml', 'm2logLreml',
'profiledVarianceHatMl', 'profiledVarianceHatReml', 'xisqTausq','junk')
Ncols = length(mlColNames)*Ny+Nxysq
if(!length(control$xisqTausq)){
control$xisqTausq = c(
lower=as.vector(1/control$propNugget['upper']),
upper=as.vector(1/control$propNugget['lower']),
control$propNugget['tol']
)
}
if(!length(control$logXisqTausq)){
control$logXisqTausq = c(
log(control$xisqTausq[c('lower','upper')]),
control$xisqTausq['tol']
)
}
if(length(oneminusar)){
# not optimizing
fromC = parallel::mcmapply(
loglikGmrfOneRange,
oneminusar=oneminusar,
MoreArgs=list(
shape=shape, NN=NN,
adjustEdges=adjustEdges,
obsCov=obsCov,
xisqTausq=xisqTausq,
reml=reml,
jacobian=jacobian, control=control),
mc.cores=mc.cores, SIMPLIFY=FALSE
)
parInfo = lapply(fromC, function(qq) attributes(qq)$param)
ml = simplify2array(fromC)
names(dimnames(ml)) = c('dataset','propNugget','output','oneminusar')
dimnames(ml)$oneminusar = as.character(oneminusar)
dimnames(ml)$propNugget = as.character(propNugget)
if(any(dimnames(ml)[[2]]=='Inf')) {
ml[,'Inf','xisqTausq', ]= 0
}
oldDimNames = names(dimnames(ml))
ml=abind::abind(ml,
array(0, dim(ml)[-3]),
along=3)
names(dimnames(ml)) = oldDimNames
dimnames(ml)$output = gsub("^$",
"boxcox",dimnames(ml)$output)
ml[,,'boxcox',] = boxcox
ssq = simplify2array(lapply(fromC,
function(x) attributes(x)$ssq))
names(dimnames(ssq)) = c('datasetRow','datasetCol', 'propNugget','output','oneminusar')
dimnames(ssq)$propNugget = as.character(propNugget)
dimnames(ssq)$oneminusar = as.character(oneminusar)
covDim = seq(Ny+1, ncol(obsCov))
if( !length(propNugget)){
# retain only propNugget with best likelihood
bestN = apply(ml[,,Lcol,,drop=FALSE],c(1,3,4),
base::which.min)
newml = array(NA,
c(dim(ml)[1],1,dim(ml)[-(1:2)]),
dimnames=c(dimnames(ml)[1],
list('propNugget'),dimnames(ml)[-(1:2)])
)
newssq =array(NA,
c(dim(ssq)[1:2],1,dim(ssq)[4]),
dimnames=list(
dimnames(ssq)[[1]],dimnames(ssq)[[2]],
NULL, dimnames(ssq)[[4]])
)
for(Dbc in 1:dim(newml)[1]){
for(Dar in 1:dim(newml)[4]){
newml[Dbc,1,,Dar] = ml[
,
bestN[Dbc,1,Dar],
,Dar]
newssq[,,1,Dar]=ssq[
,,
bestN[Dbc,1,Dar],
Dar]
}
}
ml = newml
ssq=newssq
} # end no propNugget
# retain only the best box-cox parameter for each pair
# of oneminusar and propNugget
if(length(boxcox)>1 & !fixBoxcox){
profBC = cbind(
boxcox=boxcox,
# xisqTausq = ml[1,profBCind[,1],'xisqTausq',1],
# oneminusar = oneminusar[profBCind[,2]],
logLstuff = -apply(ml[,,Lcol,,drop=FALSE], 1, base::min)/2
)
colnames(profBC) = gsub("logLstuff",
gsub("^m2", "", Lcol),
colnames(profBC))
# only keep best box-cox
profBCind = arrayInd(
apply(ml[,,Lcol,,drop=FALSE], 1, base::which.min),
dim(ml)[c(2,4)])
bestBcList = apply(ml[,,Lcol,,drop=FALSE],
c(2,4),
base::which.min)
theIndex = unlist(bestBcList[1,1])[1]
newml = ml[theIndex,,,,drop=FALSE]
newssq = ssq[
c(theIndex, covDim),
c(theIndex, covDim),,,,drop=FALSE]
if(length(unique(as.vector(bestBcList)))>=1){
# no one box-cox parameter maximizes every likelihood
# retain only the best box-cox for each par of parameters
bestBc = array(as.double(bestBcList), dim(bestBcList))
dimnames(newml)[[1]] = dimnames(newssq)[[1]][1] =
dimnames(newssq)[[2]][1] = 'y'
for(Dar in 1:dim(newml)[4]){
for(Dnugget in 1:dim(newml)[2]){
thisBc = bestBc[Dnugget,Dar]
if(!is.na(thisBc)){
newml[1,Dnugget,,Dar] =
ml[thisBc,Dnugget,,Dar]
newssq[,,Dnugget,,Dar] =
ssq[c(thisBc,covDim),c(thisBc,covDim),Dnugget,,Dar]
}
}
}
ml = newml
ssq=newssq
} # end retain best box cox
} # end have boxcox
theInf = ml[,,'xisqTausq',,drop=FALSE] != Inf
xisqHatRemlArray = theInf*ml[,,'profiledVarianceHatReml',,drop=FALSE]*ml[,,'xisqTausq',,drop=FALSE]
dimnames(xisqHatRemlArray)$output = 'xisqHatReml'
xisqHatRemlArray[,'0','xisqHatReml',] = ml[,'0','profiledVarianceHatReml',,drop=FALSE]
xisqHatMlArray = theInf*ml[,,'profiledVarianceHatMl',,drop=FALSE]*ml[,,'xisqTausq',,drop=FALSE]
dimnames(xisqHatMlArray)$output = 'xisqHatMl'
xisqHatMlArray[,'0','xisqHatMl',] = ml[,'0','profiledVarianceHatMl',,drop=FALSE]
forml = abind::abind(
tausqHatMl=ml[,,'profiledVarianceHatMl',,drop=FALSE]*theInf,
tausqHatReml=ml[,,'profiledVarianceHatReml',,drop=FALSE]*theInf,
xisqHatMlArray,
xisqHatRemlArray,
boxcox = ml[,,'boxcox',,drop=FALSE],
along=3
)
names(dimnames(forml)) = names(dimnames(ml))
dimnames(forml)$output[1:2] = c(
'tausqHatMl','tausqHatReml')
forml[,'0',c('tausqHatMl','tausqHatReml'),] = 0
Ny = dim(ml)[1]
betaHat = ssq[-(1:Ny),1:Ny,,'beta',,drop=FALSE]
names(dimnames(betaHat))[1] = 'covariate'
names(dimnames(betaHat))[2] = 'dataset'
dimnames(betaHat)$covariate = paste(
dimnames(betaHat)[[1]], 'BetaHat',sep=''
)
ssqX = ssq[-(1:Ny),-(1:Ny),,'beta',,drop=FALSE]
seBetaHat = apply(ssqX,c(3,4,5),diag)
# if there's only one covariate
# there won't be a dimension for covariate
if(length(dim(seBetaHat))==3) {
seBetaHat = array(
seBetaHat, c(1,dim(seBetaHat)),
dimnames = c(dimnames(betaHat)['covariate'], dimnames(seBetaHat))
)
}
# add dataset dimension
seBetaHat = array(
seBetaHat,
c(dim(seBetaHat)[1],1,dim(seBetaHat)[-1]),
dimnames = c(
dimnames(betaHat)['covariate'],
list(dataset = 'all'),
dimnames(seBetaHat)[-1])
)
# make seBetaHat the same as betaHat
seBetaHat = seBetaHat[,rep(1, length(dimnames(betaHat)$dataset)),,,,drop=FALSE]
dimnames(seBetaHat)$dataset = dimnames(betaHat)$dataset
betaHat = aperm(betaHat, c(2,3,1,5, 4))
seBetaHat = aperm(seBetaHat, c(2,3,1,5, 4))
# drop last dimension that's 'beta'
betaHat = array(
betaHat, dim(betaHat)[1:4],
dimnames = dimnames(betaHat)[1:4]
)
seBetaHat = array(
seBetaHat, dim(seBetaHat)[1:4],
dimnames = dimnames(seBetaHat)[1:4]
)
seBetaHatMl = seBetaHat * ml[,,rep('profiledVarianceHatMl',dim(seBetaHat)[3]),,drop=FALSE]
seBetaHatReml = seBetaHat *
ml[,,rep('profiledVarianceHatReml',dim(seBetaHat)[3]),,drop=FALSE]
dimnames(seBetaHatMl)$covariate = paste(dimnames(seBetaHatMl)$covariate,'SeMl',sep='')
dimnames(seBetaHatReml)$covariate = paste(dimnames(seBetaHatReml)$covariate,'SeReml',sep='')
logLml = -ml[,,c('m2logLreml','m2logLml'),,drop=FALSE]/2
dimnames(logLml)[[3]] = gsub("^m2","", dimnames(logLml)[[3]])
parMat = lapply(parInfo, function(qq){
c(
qq$theo[c('range','shape')],
sigmasqXisq = as.numeric(qq$theo['variance']),
optimalShape=as.numeric(qq$optimalShape['shape']),
optimalVarianceAndShape=qq$optimal[c('shape','variance')]
)
})
parMat = simplify2array(parMat)
parArray = aperm(
array(parMat,c(dim(parMat),dim(ml)[1:2])),
c(length(dim(parMat))+c(1,2), 1:length(dim(parMat))))
dimnames(parArray)[[3]] = rownames(parMat)
sigmasqHat = forml[,,c('xisqHatMl', 'xisqHatReml'),,drop=FALSE] *
parArray[,,rep('sigmasqXisq',2),,drop=FALSE]
dimnames(sigmasqHat)[[3]] = gsub("^xi", "sigma",
dimnames(sigmasqHat)[[3]])
sigmasqHat[,'0',,] = ml[,'0',c('profiledVarianceHatMl','profiledVarianceHatReml'),]
# deviance
theMin = apply(
ml[,,c('m2logLml','m2logLreml'),,drop=FALSE],
c(1,3), min)
theMin = array(
theMin,
c(dim(ml)[1],1,2,1)
)
deviance =
ml[,,c('m2logLml','m2logLreml'),,drop=FALSE] -
theMin[
,
rep(1, dim(ml)[2]),
,
rep(1, dim(ml)[4]), drop=FALSE
]
dimnames(deviance)[[3]] = paste(
gsub(
'm2logL', '', dimnames(deviance)[[3]]
),
'Deviance', sep='')
res = abind::abind(logLml, deviance,
forml, sigmasqHat,
betaHat, seBetaHatMl, seBetaHatReml, parArray,
along=3)
names(dimnames(res)) = names(dimnames(ml))
theMle = apply(
res[,,gsub("^m2","",Lcol),,drop=FALSE],
1, which.max)
mleIndex = arrayInd(theMle, dim(res)[-c(1,3)])
mle = NULL
for(D in 1:nrow(mleIndex))
mle = cbind(mle,
c(res[D,mleIndex[D,1],,mleIndex[D,2]],
oneminusar = as.numeric(dimnames(res)$oneminusar[mleIndex[D,2]]),
propNugget = as.numeric(dimnames(res)$propNugget[mleIndex[D,1]])))
colsToKeep = grep(paste(c('Reml','Ml')[1+reml],'$',sep=''),
rownames(mle), invert=TRUE)
mle = mle[colsToKeep,,drop=FALSE]
mle = mle[grep("^logL", rownames(mle), invert=TRUE),,drop=FALSE]
rownames(mle) = gsub("(Beta)?(Hat)?(Reml|Ml)?$", "", rownames(mle))
res = list(
mle=mle,
mlArray = res,
extras = list(ml=ml, ssq=ssq)
)
} else { # if (!length)
#oneminusar is NULL
########################
# optimizing
######################################################
resEnv = new.env()
assign('allPar', list(), envir=resEnv)
assign('allFromC', NULL, envir=resEnv)
assign('oneminusar', NULL, envir=resEnv)
oneL = function(x){
Q = geostatsp::maternGmrfPrec(NN,
param=c(
shape=as.vector(shape),
oneminusar=as.vector(x),
conditionalVariance=1),
adjustEdges=adjustEdges)
fromC = .Call(
C_gmrfLik,
Q,
obsCov,
as.double(xisqTausq),
reml,
as.double(jacobian),
as.double(
control$logXisqTausq[
c('lower','upper','tol')]
)
)
assign('allFromC',
cbind(get('allFromC', resEnv), fromC),
resEnv)
assign('oneminusar',
c(get('oneminusar', resEnv), x),
resEnv)
assign('allPar',
c(get('allPar', resEnv),
list(attributes(Q)$info)),
resEnv
)
NxysqTausq = length(fromC)/Ncols
logLstart = NxysqTausq*(
Nxysq+Ny*(2 + reml)
)
# get the likelihood column
ml = fromC[seq(
logLstart, by=1, len=NxysqTausq
)]
#
ml = min(ml, na.rm=TRUE)
ml
}
optimize(oneL,
lower=control$oneminusar['lower'],
upper=control$oneminusar['upper'],
tol=control$oneminusar['tol']
)
oneminusarRes = get('oneminusar', resEnv)
fromC = as.matrix(get('allFromC', resEnv))
NxysqTausq = nrow(fromC)/(8*Ny+ncol(obsCov)^2)
logLstart = NxysqTausq*Nxysq
Lseq = 1:logLstart
ssq = fromC[Lseq,]
ssq=array(ssq,
dim=c(ncol(obsCov),ncol(obsCov),NxysqTausq, ncol(fromC)),
dimnames=list(colnames(obsCov), colnames(obsCov), NULL, oneminusarRes))
ml = fromC[-Lseq,,drop=FALSE]
ml = array(
as.vector(ml),
dim=c(Ny, NxysqTausq, length(mlColNames), ncol(fromC)),
dimnames=list(
colnames(Yvec),
NULL, mlColNames, oneminusarRes
)
)
minMl = min(ml[,,Lcol,],na.rm=TRUE)
mleIndex = arrayInd(
which((ml[,,Lcol,,drop=FALSE]-minMl) < 10),
dim(ml)[-3])
mlMat = NULL
for(D in 1:nrow(mleIndex)){
mlMat = rbind(mlMat,
ml[mleIndex[1],mleIndex[2],,mleIndex[3]])
}
mlMat = cbind(
mlMat,
boxcox=boxcox[mleIndex[1]],
oneminusar = oneminusarRes[mleIndex[,3]],
propNugget = 1/mlMat[,'xisqTausq']
)
mle = mlMat[which.min(mlMat[,Lcol]),]
Qinfo = get('allPar', resEnv)
thepar = Qinfo[[
which.min(abs(oneminusarRes-mle['oneminusar']))
]]
parMat = lapply(Qinfo, function(qq){
c(
qq$theo[c('range','shape')],
sigmasqXisq = as.numeric(qq$theo['variance']),
optimalShape=as.numeric(qq$optimalShape['shape']),
optimalVarianceAndShape=qq$optimal[c('shape','variance')]
)
})
parMat =
c(
thepar$theo[c('range','shape')],
sigmasqXisq = as.numeric(thepar$theo['variance']),
optimalShape=as.numeric(thepar$optimalShape['shape']),
optimalVarianceAndShape=thepar$optimal[c('shape','variance')]
)
varMat = parMat[grep('variance', names(parMat))]
varMle = varMat * mle[c('varMl','varReml')[1+reml]]
nuggetMle = c(nugget=as.numeric(
mle['propNugget'] * mle[c('varMl','varReml')[1+reml]]
))
mle = c(mle,
varMle, nuggetMle,
parMat[grep('variance', names(parMat), invert=TRUE)])
mleIndex = drop(arrayInd(
which.min(ml[,,Lcol,,drop=FALSE]-minMl),
dim(ml)[-3]))
toKeep = c(mleIndex[1], seq(Ny+1, ncol(obsCov)))
mleSsq = ssq[toKeep[-1],toKeep,
mleIndex[2],
mleIndex[3]
]
colnames(mleSsq)[1] = 'mle'
betaHat = mleSsq[,'mle']
seBetaHat = diag(mleSsq[,-1])
seBetaHat = seBetaHat * mle[c('varMl','varReml')[1+reml]]
names(seBetaHat) = paste('stdErr',names(seBetaHat), sep='.')
res = list(
mle=c(mle[names(mle)!='junk'],
betaHat,
seBetaHat),
mlMat = mlMat,
Qinfo = thepar)
} # end optimizing
res$profileBoxCox = profBC
res
}
summaryGmrfFit= function(x) {
UseMethod("summaryGmrfFit")
}
summaryGmrfFit.array = function(x) {
x2 = aperm(x,seq(length(dim(x)),1))
x3 = array(x2, c(prod(dim(x2)[1:2]),dim(x2)[-(1:2)]),
dimnames=c(
list(as.vector(outer(dimnames(x2)[[1]], dimnames(x2)[[2]], paste))),
dimnames(x2)[-(1:2)]))
if(length(dim(x3))==2){
res = summaryGmrfFit.matrix(x3)
} else if(length(dim(x3))==3){
res=NULL
for(D in seq(dim(x3)[2],1)){
res = abind::abind(summaryGmrfFit.matrix(x3[,D,]),
res, along=4)
}
dimnames(res)[[4]]=dimnames(x3)[[2]]
}
return(res)
}
summaryGmrfFit.matrix = function(x) {
if(any(rownames(x)=='logL.ml')){
x = t(x)
}
result = list()
someL = c('ml','reml')
for(D1 in someL) {
D=paste('logL.',D1,sep='')
MLErow = x[which.max(x[ ,D]),]
withinCI = which(-2*(x[,D] - MLErow[D]) < qchisq(0.95, 2))
xsub = x[,grep("^se\\.",colnames(x),invert=TRUE),drop=FALSE]
parCI= t(apply(
xsub[withinCI, ,drop=FALSE],
2,range))
colnames(parCI) = c('q0.025', 'q0.975')
parMat = cbind(mle=MLErow[colnames(xsub)],parCI,se=NA)
notD = someL[someL != D1]
notD = grep(
paste("\\.",notD, "$",sep=''),
rownames(parMat),
invert=TRUE,value=TRUE)
parMat = parMat[notD,]
rownames(parMat) = gsub(paste("\\.", D1, "$",sep=""),
"",rownames(parMat))
se = grep("\\.se$", rownames(parMat), value=TRUE)
betahats = gsub("se$", "betaHat", se)
parMat[betahats,"se"] = parMat[se,"mle"]
parMat[betahats,"q0.025"] = as.numeric(parMat[betahats,"mle"]-2*parMat[betahats,"se"])
parMat[betahats,"q0.975"] = as.numeric(parMat[betahats,"mle"]+2*parMat[betahats,"se"])
parKeep = parMat[!rownames(parMat) %in% se,]
dele = grep("^shape|^sigmasq|^xisq|^tausq",rownames(parKeep))
parKeep[dele,grep("^q0\\.", colnames(parKeep))] = NA
result[[D1]] = parKeep
}
result = abind::abind(result[[1]], result[[2]], along=3)
dimnames(result)[[3]] = someL
return(result)
}
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Defines functions summaryGmrfFit.matrix summaryGmrfFit.array summaryGmrfFit loglikGmrf loglikGmrfOneRange
loglikGmrfOneRange = function(
oneminusar,
shape, NN,
adjustEdges, obsCov, xisqTausq,
reml, jacobian, control){
Q = geostatsp::maternGmrfPrec(NN,
param=c(
shape=as.vector(shape),
oneminusar=as.vector(oneminusar),
conditionalVariance=1),
adjustEdges=adjustEdges)
fromC = .Call(
C_gmrfLik,
Q,
obsCov,
as.double(xisqTausq),
reml,
as.double(jacobian),
as.double(
control$logXisqTausq[
c('lower','upper','tol')]
)
)
Nxy = ncol(obsCov)
Ny = length(jacobian)
Nobs = nrow(obsCov)
NxisqTausq = length(xisqTausq)
Nxysq = Nxy^2
logLstart = NxisqTausq*Nxysq*2
mlColNames = c('det','detReml','m2logLml',
'm2logLreml', 'profiledVarianceHatMl',
'profiledVarianceHatReml', 'xisqTausq')
mlDim = c(y=Ny,
varRatio=NxisqTausq,
output=length(mlColNames))
Lseq = 1:logLstart
result = array(
as.vector(fromC[
seq(logLstart+1, len=prod(mlDim))
]),
dim=mlDim,
dimnames=list(
colnames(obsCov)[1:Ny],
as.character(xisqTausq),
mlColNames
))
attributes(result)$ssq = array(fromC[Lseq],
dim=c(Nxy, Nxy, NxisqTausq,2),
dimnames = list(
colnames(obsCov), colnames(obsCov),
as.character(xisqTausq),
c('ssq','beta')
))
attributes(result)$param = attributes(Q)$info
result
}
loglikGmrf = function(
Yvec, Xmat, NN,
oneminusar = NULL,
propNugget=NULL,
boxcox=1,
fixBoxcox=TRUE,
seqBoxcox=outer(c(0.01, 0.02, 0.05, 0.1, 0.2, 0.5), c(-1,1)),
shape=1,
reml=TRUE,
adjustEdges=FALSE,
jacobian = 0,
control=list(
oneminusar = c(lower=1e-3, upper=0.8, tol= .Machine$double.eps^0.25),
propNugget = c(lower=1e-3, upper=1e3, tol= .Machine$double.eps^0.25)
),
mc.cores=1
) {
## something with reml and boxcox is broken
## getting Nan's in reml determinant matrix
Yvec = as.matrix(Yvec)
if(is.null(colnames(Yvec)))
colnames(Yvec) = paste("y", 1:ncol(Yvec), sep='')
Ny = ncol(Yvec)
if(Ny > 1 & !(length(oneminusar) & length(propNugget)))
stop("specify oneminusar and propNugget if there is more than one dataset in Y")
Nobs = nrow(Yvec)
Lcol = c('m2logLml', 'm2logLreml')[reml+1]
# boxcox
if(!fixBoxcox){
seqBoxcox = sort(unique(c(0, seqBoxcox)))
if(Ny>1) warning("need fixBoxcox=TRUE if Y has more than one column")
bcStuff = forBoxCox(y=Yvec,x=Xmat,seqBoxCox=seqBoxcox)
Ny = ncol(bcStuff$y)
Yvec = bcStuff$y
jacobian = bcStuff$jacobian
boxcox=bcStuff$boxcox
} else {
if(length(jacobian)==1)
jacobian = rep(jacobian, Ny)
if(length(boxcox)==1){
boxcox = rep(boxcox, Ny)
}
}
profBC = NULL # store profile likelihood of box-cox parameter
if(length(jacobian)!= Ny | length(boxcox)!= Ny)
warning('length of jacobian or boxcox must be same as columns of Y')
if(is.null(colnames(Xmat))) colnames(Xmat) = paste('cov', 1:ncol(Xmat), sep='')
obsCov = as.matrix(cbind(Yvec, Xmat))
if(length(propNugget))
propNugget = sort(unique(c(0, propNugget)))
xisqTausq = 1/propNugget
xisqTausq[!is.finite(xisqTausq)] = 0
Nxysq = ncol(obsCov)^2
mlColNames = c(
'det','detReml','m2logLml', 'm2logLreml',
'profiledVarianceHatMl', 'profiledVarianceHatReml', 'xisqTausq','junk')
Ncols = length(mlColNames)*Ny+Nxysq
if(!length(control$xisqTausq)){
control$xisqTausq = c(
lower=as.vector(1/control$propNugget['upper']),
upper=as.vector(1/control$propNugget['lower']),
control$propNugget['tol']
)
}
if(!length(control$logXisqTausq)){
control$logXisqTausq = c(
log(control$xisqTausq[c('lower','upper')]),
control$xisqTausq['tol']
)
}
if(length(oneminusar)){
# not optimizing
fromC = parallel::mcmapply(
loglikGmrfOneRange,
oneminusar=oneminusar,
MoreArgs=list(
shape=shape, NN=NN,
adjustEdges=adjustEdges,
obsCov=obsCov,
xisqTausq=xisqTausq,
reml=reml,
jacobian=jacobian, control=control),
mc.cores=mc.cores, SIMPLIFY=FALSE
)
parInfo = lapply(fromC, function(qq) attributes(qq)$param)
ml = simplify2array(fromC)
names(dimnames(ml)) = c('dataset','propNugget','output','oneminusar')
dimnames(ml)$oneminusar = as.character(oneminusar)
dimnames(ml)$propNugget = as.character(propNugget)
if(any(dimnames(ml)[[2]]=='Inf')) {
ml[,'Inf','xisqTausq', ]= 0
}
oldDimNames = names(dimnames(ml))
ml=abind::abind(ml,
array(0, dim(ml)[-3]),
along=3)
names(dimnames(ml)) = oldDimNames
dimnames(ml)$output = gsub("^$",
"boxcox",dimnames(ml)$output)
ml[,,'boxcox',] = boxcox
ssq = simplify2array(lapply(fromC,
function(x) attributes(x)$ssq))
names(dimnames(ssq)) = c('datasetRow','datasetCol', 'propNugget','output','oneminusar')
dimnames(ssq)$propNugget = as.character(propNugget)
dimnames(ssq)$oneminusar = as.character(oneminusar)
covDim = seq(Ny+1, ncol(obsCov))
if( !length(propNugget)){
# retain only propNugget with best likelihood
bestN = apply(ml[,,Lcol,,drop=FALSE],c(1,3,4),
base::which.min)
newml = array(NA,
c(dim(ml)[1],1,dim(ml)[-(1:2)]),
dimnames=c(dimnames(ml)[1],
list('propNugget'),dimnames(ml)[-(1:2)])
)
newssq =array(NA,
c(dim(ssq)[1:2],1,dim(ssq)[4]),
dimnames=list(
dimnames(ssq)[[1]],dimnames(ssq)[[2]],
NULL, dimnames(ssq)[[4]])
)
for(Dbc in 1:dim(newml)[1]){
for(Dar in 1:dim(newml)[4]){
newml[Dbc,1,,Dar] = ml[
,
bestN[Dbc,1,Dar],
,Dar]
newssq[,,1,Dar]=ssq[
,,
bestN[Dbc,1,Dar],
Dar]
}
}
ml = newml
ssq=newssq
} # end no propNugget
# retain only the best box-cox parameter for each pair
# of oneminusar and propNugget
if(length(boxcox)>1 & !fixBoxcox){
profBC = cbind(
boxcox=boxcox,
# xisqTausq = ml[1,profBCind[,1],'xisqTausq',1],
# oneminusar = oneminusar[profBCind[,2]],
logLstuff = -apply(ml[,,Lcol,,drop=FALSE], 1, base::min)/2
)
colnames(profBC) = gsub("logLstuff",
gsub("^m2", "", Lcol),
colnames(profBC))
# only keep best box-cox
profBCind = arrayInd(
apply(ml[,,Lcol,,drop=FALSE], 1, base::which.min),
dim(ml)[c(2,4)])
bestBcList = apply(ml[,,Lcol,,drop=FALSE],
c(2,4),
base::which.min)
theIndex = unlist(bestBcList[1,1])[1]
newml = ml[theIndex,,,,drop=FALSE]
newssq = ssq[
c(theIndex, covDim),
c(theIndex, covDim),,,,drop=FALSE]
if(length(unique(as.vector(bestBcList)))>=1){
# no one box-cox parameter maximizes every likelihood
# retain only the best box-cox for each par of parameters
bestBc = array(as.double(bestBcList), dim(bestBcList))
dimnames(newml)[[1]] = dimnames(newssq)[[1]][1] =
dimnames(newssq)[[2]][1] = 'y'
for(Dar in 1:dim(newml)[4]){
for(Dnugget in 1:dim(newml)[2]){
thisBc = bestBc[Dnugget,Dar]
if(!is.na(thisBc)){
newml[1,Dnugget,,Dar] =
ml[thisBc,Dnugget,,Dar]
newssq[,,Dnugget,,Dar] =
ssq[c(thisBc,covDim),c(thisBc,covDim),Dnugget,,Dar]
}
}
}
ml = newml
ssq=newssq
} # end retain best box cox
} # end have boxcox
theInf = ml[,,'xisqTausq',,drop=FALSE] != Inf
xisqHatRemlArray = theInf*ml[,,'profiledVarianceHatReml',,drop=FALSE]*ml[,,'xisqTausq',,drop=FALSE]
dimnames(xisqHatRemlArray)$output = 'xisqHatReml'
xisqHatRemlArray[,'0','xisqHatReml',] = ml[,'0','profiledVarianceHatReml',,drop=FALSE]
xisqHatMlArray = theInf*ml[,,'profiledVarianceHatMl',,drop=FALSE]*ml[,,'xisqTausq',,drop=FALSE]
dimnames(xisqHatMlArray)$output = 'xisqHatMl'
xisqHatMlArray[,'0','xisqHatMl',] = ml[,'0','profiledVarianceHatMl',,drop=FALSE]
forml = abind::abind(
tausqHatMl=ml[,,'profiledVarianceHatMl',,drop=FALSE]*theInf,
tausqHatReml=ml[,,'profiledVarianceHatReml',,drop=FALSE]*theInf,
xisqHatMlArray,
xisqHatRemlArray,
boxcox = ml[,,'boxcox',,drop=FALSE],
along=3
)
names(dimnames(forml)) = names(dimnames(ml))
dimnames(forml)$output[1:2] = c(
'tausqHatMl','tausqHatReml')
forml[,'0',c('tausqHatMl','tausqHatReml'),] = 0
Ny = dim(ml)[1]
betaHat = ssq[-(1:Ny),1:Ny,,'beta',,drop=FALSE]
names(dimnames(betaHat))[1] = 'covariate'
names(dimnames(betaHat))[2] = 'dataset'
dimnames(betaHat)$covariate = paste(
dimnames(betaHat)[[1]], 'BetaHat',sep=''
)
ssqX = ssq[-(1:Ny),-(1:Ny),,'beta',,drop=FALSE]
seBetaHat = apply(ssqX,c(3,4,5),diag)
# if there's only one covariate
# there won't be a dimension for covariate
if(length(dim(seBetaHat))==3) {
seBetaHat = array(
seBetaHat, c(1,dim(seBetaHat)),
dimnames = c(dimnames(betaHat)['covariate'], dimnames(seBetaHat))
)
}
# add dataset dimension
seBetaHat = array(
seBetaHat,
c(dim(seBetaHat)[1],1,dim(seBetaHat)[-1]),
dimnames = c(
dimnames(betaHat)['covariate'],
list(dataset = 'all'),
dimnames(seBetaHat)[-1])
)
# make seBetaHat the same as betaHat
seBetaHat = seBetaHat[,rep(1, length(dimnames(betaHat)$dataset)),,,,drop=FALSE]
dimnames(seBetaHat)$dataset = dimnames(betaHat)$dataset
betaHat = aperm(betaHat, c(2,3,1,5, 4))
seBetaHat = aperm(seBetaHat, c(2,3,1,5, 4))
# drop last dimension that's 'beta'
betaHat = array(
betaHat, dim(betaHat)[1:4],
dimnames = dimnames(betaHat)[1:4]
)
seBetaHat = array(
seBetaHat, dim(seBetaHat)[1:4],
dimnames = dimnames(seBetaHat)[1:4]
)
seBetaHatMl = seBetaHat * ml[,,rep('profiledVarianceHatMl',dim(seBetaHat)[3]),,drop=FALSE]
seBetaHatReml = seBetaHat *
ml[,,rep('profiledVarianceHatReml',dim(seBetaHat)[3]),,drop=FALSE]
dimnames(seBetaHatMl)$covariate = paste(dimnames(seBetaHatMl)$covariate,'SeMl',sep='')
dimnames(seBetaHatReml)$covariate = paste(dimnames(seBetaHatReml)$covariate,'SeReml',sep='')
logLml = -ml[,,c('m2logLreml','m2logLml'),,drop=FALSE]/2
dimnames(logLml)[[3]] = gsub("^m2","", dimnames(logLml)[[3]])
parMat = lapply(parInfo, function(qq){
c(
qq$theo[c('range','shape')],
sigmasqXisq = as.numeric(qq$theo['variance']),
optimalShape=as.numeric(qq$optimalShape['shape']),
optimalVarianceAndShape=qq$optimal[c('shape','variance')]
)
})
parMat = simplify2array(parMat)
parArray = aperm(
array(parMat,c(dim(parMat),dim(ml)[1:2])),
c(length(dim(parMat))+c(1,2), 1:length(dim(parMat))))
dimnames(parArray)[[3]] = rownames(parMat)
sigmasqHat = forml[,,c('xisqHatMl', 'xisqHatReml'),,drop=FALSE] *
parArray[,,rep('sigmasqXisq',2),,drop=FALSE]
dimnames(sigmasqHat)[[3]] = gsub("^xi", "sigma",
dimnames(sigmasqHat)[[3]])
sigmasqHat[,'0',,] = ml[,'0',c('profiledVarianceHatMl','profiledVarianceHatReml'),]
# deviance
theMin = apply(
ml[,,c('m2logLml','m2logLreml'),,drop=FALSE],
c(1,3), min)
theMin = array(
theMin,
c(dim(ml)[1],1,2,1)
)
deviance =
ml[,,c('m2logLml','m2logLreml'),,drop=FALSE] -
theMin[
,
rep(1, dim(ml)[2]),
,
rep(1, dim(ml)[4]), drop=FALSE
]
dimnames(deviance)[[3]] = paste(
gsub(
'm2logL', '', dimnames(deviance)[[3]]
),
'Deviance', sep='')
res = abind::abind(logLml, deviance,
forml, sigmasqHat,
betaHat, seBetaHatMl, seBetaHatReml, parArray,
along=3)
names(dimnames(res)) = names(dimnames(ml))
theMle = apply(
res[,,gsub("^m2","",Lcol),,drop=FALSE],
1, which.max)
mleIndex = arrayInd(theMle, dim(res)[-c(1,3)])
mle = NULL
for(D in 1:nrow(mleIndex))
mle = cbind(mle,
c(res[D,mleIndex[D,1],,mleIndex[D,2]],
oneminusar = as.numeric(dimnames(res)$oneminusar[mleIndex[D,2]]),
propNugget = as.numeric(dimnames(res)$propNugget[mleIndex[D,1]])))
colsToKeep = grep(paste(c('Reml','Ml')[1+reml],'$',sep=''),
rownames(mle), invert=TRUE)
mle = mle[colsToKeep,,drop=FALSE]
mle = mle[grep("^logL", rownames(mle), invert=TRUE),,drop=FALSE]
rownames(mle) = gsub("(Beta)?(Hat)?(Reml|Ml)?$", "", rownames(mle))
res = list(
mle=mle,
mlArray = res,
extras = list(ml=ml, ssq=ssq)
)
} else { # if (!length)
#oneminusar is NULL
########################
# optimizing
######################################################
resEnv = new.env()
assign('allPar', list(), envir=resEnv)
assign('allFromC', NULL, envir=resEnv)
assign('oneminusar', NULL, envir=resEnv)
oneL = function(x){
Q = geostatsp::maternGmrfPrec(NN,
param=c(
shape=as.vector(shape),
oneminusar=as.vector(x),
conditionalVariance=1),
adjustEdges=adjustEdges)
fromC = .Call(
C_gmrfLik,
Q,
obsCov,
as.double(xisqTausq),
reml,
as.double(jacobian),
as.double(
control$logXisqTausq[
c('lower','upper','tol')]
)
)
assign('allFromC',
cbind(get('allFromC', resEnv), fromC),
resEnv)
assign('oneminusar',
c(get('oneminusar', resEnv), x),
resEnv)
assign('allPar',
c(get('allPar', resEnv),
list(attributes(Q)$info)),
resEnv
)
NxysqTausq = length(fromC)/Ncols
logLstart = NxysqTausq*(
Nxysq+Ny*(2 + reml)
)
# get the likelihood column
ml = fromC[seq(
logLstart, by=1, len=NxysqTausq
)]
#
ml = min(ml, na.rm=TRUE)
ml
}
optimize(oneL,
lower=control$oneminusar['lower'],
upper=control$oneminusar['upper'],
tol=control$oneminusar['tol']
)
oneminusarRes = get('oneminusar', resEnv)
fromC = as.matrix(get('allFromC', resEnv))
NxysqTausq = nrow(fromC)/(8*Ny+ncol(obsCov)^2)
logLstart = NxysqTausq*Nxysq
Lseq = 1:logLstart
ssq = fromC[Lseq,]
ssq=array(ssq,
dim=c(ncol(obsCov),ncol(obsCov),NxysqTausq, ncol(fromC)),
dimnames=list(colnames(obsCov), colnames(obsCov), NULL, oneminusarRes))
ml = fromC[-Lseq,,drop=FALSE]
ml = array(
as.vector(ml),
dim=c(Ny, NxysqTausq, length(mlColNames), ncol(fromC)),
dimnames=list(
colnames(Yvec),
NULL, mlColNames, oneminusarRes
)
)
minMl = min(ml[,,Lcol,],na.rm=TRUE)
mleIndex = arrayInd(
which((ml[,,Lcol,,drop=FALSE]-minMl) < 10),
dim(ml)[-3])
mlMat = NULL
for(D in 1:nrow(mleIndex)){
mlMat = rbind(mlMat,
ml[mleIndex[1],mleIndex[2],,mleIndex[3]])
}
mlMat = cbind(
mlMat,
boxcox=boxcox[mleIndex[1]],
oneminusar = oneminusarRes[mleIndex[,3]],
propNugget = 1/mlMat[,'xisqTausq']
)
mle = mlMat[which.min(mlMat[,Lcol]),]
Qinfo = get('allPar', resEnv)
thepar = Qinfo[[
which.min(abs(oneminusarRes-mle['oneminusar']))
]]
parMat = lapply(Qinfo, function(qq){
c(
qq$theo[c('range','shape')],
sigmasqXisq = as.numeric(qq$theo['variance']),
optimalShape=as.numeric(qq$optimalShape['shape']),
optimalVarianceAndShape=qq$optimal[c('shape','variance')]
)
})
parMat =
c(
thepar$theo[c('range','shape')],
sigmasqXisq = as.numeric(thepar$theo['variance']),
optimalShape=as.numeric(thepar$optimalShape['shape']),
optimalVarianceAndShape=thepar$optimal[c('shape','variance')]
)
varMat = parMat[grep('variance', names(parMat))]
varMle = varMat * mle[c('varMl','varReml')[1+reml]]
nuggetMle = c(nugget=as.numeric(
mle['propNugget'] * mle[c('varMl','varReml')[1+reml]]
))
mle = c(mle,
varMle, nuggetMle,
parMat[grep('variance', names(parMat), invert=TRUE)])
mleIndex = drop(arrayInd(
which.min(ml[,,Lcol,,drop=FALSE]-minMl),
dim(ml)[-3]))
toKeep = c(mleIndex[1], seq(Ny+1, ncol(obsCov)))
mleSsq = ssq[toKeep[-1],toKeep,
mleIndex[2],
mleIndex[3]
]
colnames(mleSsq)[1] = 'mle'
betaHat = mleSsq[,'mle']
seBetaHat = diag(mleSsq[,-1])
seBetaHat = seBetaHat * mle[c('varMl','varReml')[1+reml]]
names(seBetaHat) = paste('stdErr',names(seBetaHat), sep='.')
res = list(
mle=c(mle[names(mle)!='junk'],
betaHat,
seBetaHat),
mlMat = mlMat,
Qinfo = thepar)
} # end optimizing
res$profileBoxCox = profBC
res
}
summaryGmrfFit= function(x) {
UseMethod("summaryGmrfFit")
}
summaryGmrfFit.array = function(x) {
x2 = aperm(x,seq(length(dim(x)),1))
x3 = array(x2, c(prod(dim(x2)[1:2]),dim(x2)[-(1:2)]),
dimnames=c(
list(as.vector(outer(dimnames(x2)[[1]], dimnames(x2)[[2]], paste))),
dimnames(x2)[-(1:2)]))
if(length(dim(x3))==2){
res = summaryGmrfFit.matrix(x3)
} else if(length(dim(x3))==3){
res=NULL
for(D in seq(dim(x3)[2],1)){
res = abind::abind(summaryGmrfFit.matrix(x3[,D,]),
res, along=4)
}
dimnames(res)[[4]]=dimnames(x3)[[2]]
}
return(res)
}
summaryGmrfFit.matrix = function(x) {
if(any(rownames(x)=='logL.ml')){
x = t(x)
}
result = list()
someL = c('ml','reml')
for(D1 in someL) {
D=paste('logL.',D1,sep='')
MLErow = x[which.max(x[ ,D]),]
withinCI = which(-2*(x[,D] - MLErow[D]) < qchisq(0.95, 2))
xsub = x[,grep("^se\\.",colnames(x),invert=TRUE),drop=FALSE]
parCI= t(apply(
xsub[withinCI, ,drop=FALSE],
2,range))
colnames(parCI) = c('q0.025', 'q0.975')
parMat = cbind(mle=MLErow[colnames(xsub)],parCI,se=NA)
notD = someL[someL != D1]
notD = grep(
paste("\\.",notD, "$",sep=''),
rownames(parMat),
invert=TRUE,value=TRUE)
parMat = parMat[notD,]
rownames(parMat) = gsub(paste("\\.", D1, "$",sep=""),
"",rownames(parMat))
se = grep("\\.se$", rownames(parMat), value=TRUE)
betahats = gsub("se$", "betaHat", se)
parMat[betahats,"se"] = parMat[se,"mle"]
parMat[betahats,"q0.025"] = as.numeric(parMat[betahats,"mle"]-2*parMat[betahats,"se"])
parMat[betahats,"q0.975"] = as.numeric(parMat[betahats,"mle"]+2*parMat[betahats,"se"])
parKeep = parMat[!rownames(parMat) %in% se,]
dele = grep("^shape|^sigmasq|^xisq|^tausq",rownames(parKeep))
parKeep[dele,grep("^q0\\.", colnames(parKeep))] = NA
result[[D1]] = parKeep
}
result = abind::abind(result[[1]], result[[2]], along=3)
dimnames(result)[[3]] = someL
return(result)
}
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