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R/tskrige.R
In rtop: Interpolation of Data with Variable Spatial Support
Defines functions
rtopKrige.STSDF
Documented in
rtopKrige.STSDF
rtopKrige.STSDF = function(object, predictionLocations = NULL, varMatObs, varMatPredObs,
varMat, params = list(), formulaString, sel,
olags = NULL, plags = NULL, lagExact = TRUE, ...) {
if (!requireNamespace("spacetime")) stop("spacetime not available")
params = getRtopParams(params, ...)
cv = params$cv
debug.level = params$debug.level
if (!cv & !all.equal(is.null(olags), is.null(plags)))
stop("Lag times have to be given for both observations and predictionLocations, or for none of them")
if (!missing(varMat) && missing(varMatObs)) {
if (is.atomic(varMat)) {
varMatObs = varMat
if (!cv) stop(paste("Not cross-validation, you must provide either varMatObs",
" and varMatPredObs or varMat with the matrices as elements"))
} else {
varMatObs = varMat$varMatObs
varMatPredObs = varMat$varMatPredObs
}
}
if (cv) {
predictionLocations = object
plags = olags
varMatPredObs = varMatObs
}
ntime = dim(object)[2]
nspace = dim(object)[1]
indx = predictionLocations@index
sinds = sort(unique(indx[,1]))
tinds = sort(unique(indx[,2]))
pspace = dim(predictionLocations)[1]
ptime = dim(predictionLocations)[2]
pfull = if (prod(dim(predictionLocations)) == dim(predictionLocations@data)[1]) TRUE else FALSE
if (is(predictionLocations, "STSDF")) {
predictionLocations@data = cbind(predictionLocations@data,
data.frame(var1.pred = NA, var1.var = NA, var1.yam = NA))
} else if (is(predictionLocations, "STS")) {
predictionLocations = spacetime::STSDF(predictionLocations, data = data.frame(var1.pred = NA, var1.var = NA, var1.yam = NA))
}
if (is.null(olags) & prod(dim(object)) == dim(object@data)[1]) { # if all stations have obs from all time steps
obj1 = object[,1]
if (is(predictionLocations, "STSDF")) {
predLoc = predictionLocations@sp
} else {
predLoc = predictionLocations
}
ret = rtopKrige.default(obj1, predLoc, varMatObs,
varMatPredObs, varMat, params, formulaString, wret = TRUE)#,
#sel, ...)
weight = ret$weight
wvar = ret$predictions$var1.var
obs = as.data.frame(object)
obs = obs[,c("sp.ID", "timeIndex", as.character(formulaString[[2]]))]
# obs$timeIndex = object@index[,2]
obs = reshape(obs, v.names = as.character(formulaString[[2]]),
idvar = "sp.ID", timevar = "timeIndex", direction = "wide")
if (interactive() & debug.level == 1 & length(sinds) > 1) pb = txtProgressBar(1, length(sinds), style = 3)
for (istat in 1:length(sinds)) {
isind = sinds[istat]
ttinds = which(indx[,1] == isind)
lweight = weight[istat,]
preds = lweight %*% as.matrix(obs[,2:dim(obs)[2]])
diffs = sweep(obs[,2:dim(obs)[2]], 2, preds )
var1.yam = t(lweight) %*% (diffs^2)
# var1.var = t(lweights) %*% ((as.matrix(Obs[iobs,depVar]@data)-as.numeric(var1.pred))^2)
if (!pfull) {
ptinds = indx[ttinds,1]
preds = preds[ptinds]
var1.yam = var1.yam[ptinds]
}
predictionLocations@data$var1.pred[ttinds] = preds
predictionLocations@data$var1.var[ttinds] = wvar[istat]
predictionLocations@data$var1.yam[ttinds] = var1.yam
if (interactive() & debug.level == 1 & length(sinds) > 1) setTxtProgressBar(pb, istat)
}
if (interactive() & debug.level == 1 & length(sinds) > 1) close(pb)
} else {
object@sp$sindex = sindex = 1:nspace
object@time$tindex = tindex = 1:ntime
predictionLocations@sp$sindex = 1:pspace
predictionLocations@time$tindex = 1:ptime
obs = as.data.frame(object)
depVar = as.character(formulaString[[2]])
obs = obs[,c("sp.ID", "timeIndex", depVar)]
# obs$timeIndex = object@index[,2]
if (!requireNamespace("reshape2")) stop("reshape2 not available")
obs = reshape2::dcast(obs, sp.ID ~ timeIndex)
# reshape(obs, v.names = as.character(formulaString[[2]]),
# idvar = "sp.ID", timevar = "timeIndex", direction = "wide")
obs = obs[order(as.numeric(as.character(obs$sp.ID))), ]
obs = as.matrix(obs[,2:(ntime+1)])
if (!cv | !is.null(olags)) {
ploc = as.data.frame(predictionLocations)
ploc = cbind(ploc, var = 1)
ploc = ploc[,c("sp.ID", "timeIndex", "var")]
ploc$sp.ID = as.numeric(as.character(ploc$sp.ID))
ploc = reshape2::dcast(ploc, sp.ID ~ timeIndex)
ploc = as.matrix(ploc)
# spobs = NULL
}
if (interactive() & debug.level == 1 & ntime > 1) pb = txtProgressBar(1, ntime, style = 3)
spPredLoc = if (!cv) predictionLocations@sp else NULL
if (is.null(olags)) {
oldind = NULL
newkrige = 0
for (itime in 1:ptime) {
newind = which(!is.na(obs[,itime]))
if (length(newind) == 0) next
# print(paste(1, istat, itime, length(newind)))
if (is.null(oldind) || !isTRUE(all.equal(newind, oldind))) {
oldind = newind
newkrige = newkrige + 1
ppq = object[,itime]
vmat = varMatObs[newind, newind]
if (cv) {
vpredobs = NULL
} else {
vpredobs = varMatPredObs[newind,]
}
ret = rtopKrige.default(object = ppq, predictionLocations = spPredLoc, varMatObs = vmat,
varMatPredObs = vpredobs, params = params,
formulaString = formulaString, wret = TRUE, debug.level = 0)#,
weight = ret$weight
wvar = ret$predictions$var1.var
}
ob = obs[,itime]
ob = ob[!is.na(ob)]
preds = weight %*% ob
var1.yam = rep(NA, dim(weight)[1])
for (istat in 1:dim(weight)[1]) {
diffs = ob - preds[istat]
var1.yam[istat] = sum(weight[istat,] * t(diffs^2))
}
itind = tinds[itime]
ttinds = which(indx[,2] == itind)
if (!pfull & FALSE) {
ptinds = indx[ttinds,1]
preds = preds[ptinds]
var1.yam = var1.yam[ptinds]
}
predictionLocations@data$var1.pred[ttinds] = preds
predictionLocations@data$var1.var[ttinds] = wvar
predictionLocations@data$var1.yam[ttinds] = var1.yam
if (interactive() & debug.level == 1 & ntime > 1) setTxtProgressBar(pb, itime)
}
} else {
ntot = dim(predictionLocations@data)[1]
if (interactive() & debug.level == 1 & ntime > 1) pb = txtProgressBar(1, ntot, style = 3)
itot = 0
objsp = object@sp
objsp = SpatialPointsDataFrame(SpatialPoints(objsp), data = objsp@data)
newkrige = 0
obs2 = obs
for (istat in 1:pspace) {
# neigh = which(distm < maxdist)
ispace = predictionLocations@sp@data$sindex[istat]
pxts = as.data.frame(predictionLocations[istat,])
stpred = predictionLocations@sp[istat,]
distm = spDistsN1(coordinates(object@sp),coordinates(stpred))
ppred = SpatialPoints(stpred)
rolags = olags - plags[istat] # longer lags will be positive, i.e., use future observations
nbefore = -floor(min(rolags))
nafter = ceiling(max(c(rolags, 1)))
naadd1 = matrix(NA, nrow = nspace, ncol = nbefore)#, dimnames = list(as.character(1:nbefore), names(obs)))
naadd2 = matrix(NA, nrow = nspace, ncol = nafter)#, dimnames = list(names(obs)as.character(1:nafter)))
obsb = cbind(naadd1, cbind(obs2, naadd2))
obs[,] = NA
if (!lagExact) {
rolags = round(rolags, 0)
for (jstat in 1:nspace) {
obs[jstat, ] = obsb[jstat, (nbefore + 1 + rolags[jstat]) : (nbefore + ntime + rolags[jstat])]
}
} else {
rdiff = rolags - floor(rolags)
for (jstat in 1:nspace) {
nf = (nbefore + 1 + floor(rolags[jstat])) : (nbefore + ntime + floor(rolags[jstat]))
nl = (nbefore + 1 + ceiling(rolags[jstat])) : (nbefore + ntime + ceiling(rolags[jstat]))
obs[jstat, ] = obsb[jstat, nf] * (1-rdiff[jstat]) + obsb[jstat, nl] * rdiff[jstat]
}
}
oldind = NULL
ntl = length(pxts$tindex)
preds = rep(NA, ntl)
var1.yam = rep(NA, ntl)
var1.var = rep(NA, ntl)
tms = as.numeric(as.character(pxts$tindex))
if (cv) vorder = order(varMatObs[istat,]) else vorder = order(varMatPredObs[istat])
for (itime in seq_along(tms)) {
jtime = tms[itime]
tp = ploc[istat, jtime]
if (is.na(tp)) next
newind = vorder[vorder %in% which(!is.na(obs[,jtime]))]
if (cv) newind = newind[-which(newind == istat)]
if (is.numeric(params$nmax) && length(newind) > params$nmax) newind = newind[1:params$nmax]
if (length(newind) == 0) next
newind = newind[newind %in% vorder]
# print(paste(1, istat, itime, length(newind)))
if (is.null(oldind) || !isTRUE(all.equal(newind, oldind))) {
oldind = newind
newkrige = newkrige + 1
# print(paste(2, istat, itime, length(newind), newkrige))
ppq = objsp[newind, ]
ppq$intvar = obs[newind, jtime]
vmat = varMatObs[newind, newind]
vpredobs = varMatPredObs[newind, istat, drop = FALSE]
# fmstring = as.formula(paste(names(ppq)[1], "~1"))
ret = rtopKrige.default(object = ppq, ppred, varMatObs = vmat,
varMatPredObs = vpredobs, params = params,
formulaString = intvar~1, wret = TRUE,
debug.level = 0, cv = FALSE)#,
weight = ret$weight
wvar = ret$predictions$var1.var
}
preds[itime] = sum(weight * obs[newind,jtime])
diffs = obs[newind,jtime] - preds[itime]
var1.yam[itime] = sum(weight * (diffs^2))
var1.var[itime] = wvar
itot = itot + 1
if (interactive() & debug.level == 1 & ntime > 1) setTxtProgressBar(pb, itot)
}
# print(paste(1, istat, itime, length(newind), newkrige))
itind = tinds[itime]
ttinds = which(indx[,1] == ispace)
predictionLocations@data$var1.pred[ttinds] = preds
predictionLocations@data$var1.var[ttinds] = var1.var
predictionLocations@data$var1.yam[ttinds] = var1.yam
}
}
if (interactive() & debug.level == 1 & ntime > 1) close(pb)
}
list(predictions = predictionLocations)
}
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rtop documentation built on May 2, 2019, 6:48 p.m.
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Defines functions rtopKrige.STSDF
Documented in rtopKrige.STSDF
rtopKrige.STSDF = function(object, predictionLocations = NULL, varMatObs, varMatPredObs,
varMat, params = list(), formulaString, sel,
olags = NULL, plags = NULL, lagExact = TRUE, ...) {
if (!requireNamespace("spacetime")) stop("spacetime not available")
params = getRtopParams(params, ...)
cv = params$cv
debug.level = params$debug.level
if (!cv & !all.equal(is.null(olags), is.null(plags)))
stop("Lag times have to be given for both observations and predictionLocations, or for none of them")
if (!missing(varMat) && missing(varMatObs)) {
if (is.atomic(varMat)) {
varMatObs = varMat
if (!cv) stop(paste("Not cross-validation, you must provide either varMatObs",
" and varMatPredObs or varMat with the matrices as elements"))
} else {
varMatObs = varMat$varMatObs
varMatPredObs = varMat$varMatPredObs
}
}
if (cv) {
predictionLocations = object
plags = olags
varMatPredObs = varMatObs
}
ntime = dim(object)[2]
nspace = dim(object)[1]
indx = predictionLocations@index
sinds = sort(unique(indx[,1]))
tinds = sort(unique(indx[,2]))
pspace = dim(predictionLocations)[1]
ptime = dim(predictionLocations)[2]
pfull = if (prod(dim(predictionLocations)) == dim(predictionLocations@data)[1]) TRUE else FALSE
if (is(predictionLocations, "STSDF")) {
predictionLocations@data = cbind(predictionLocations@data,
data.frame(var1.pred = NA, var1.var = NA, var1.yam = NA))
} else if (is(predictionLocations, "STS")) {
predictionLocations = spacetime::STSDF(predictionLocations, data = data.frame(var1.pred = NA, var1.var = NA, var1.yam = NA))
}
if (is.null(olags) & prod(dim(object)) == dim(object@data)[1]) { # if all stations have obs from all time steps
obj1 = object[,1]
if (is(predictionLocations, "STSDF")) {
predLoc = predictionLocations@sp
} else {
predLoc = predictionLocations
}
ret = rtopKrige.default(obj1, predLoc, varMatObs,
varMatPredObs, varMat, params, formulaString, wret = TRUE)#,
#sel, ...)
weight = ret$weight
wvar = ret$predictions$var1.var
obs = as.data.frame(object)
obs = obs[,c("sp.ID", "timeIndex", as.character(formulaString[[2]]))]
# obs$timeIndex = object@index[,2]
obs = reshape(obs, v.names = as.character(formulaString[[2]]),
idvar = "sp.ID", timevar = "timeIndex", direction = "wide")
if (interactive() & debug.level == 1 & length(sinds) > 1) pb = txtProgressBar(1, length(sinds), style = 3)
for (istat in 1:length(sinds)) {
isind = sinds[istat]
ttinds = which(indx[,1] == isind)
lweight = weight[istat,]
preds = lweight %*% as.matrix(obs[,2:dim(obs)[2]])
diffs = sweep(obs[,2:dim(obs)[2]], 2, preds )
var1.yam = t(lweight) %*% (diffs^2)
# var1.var = t(lweights) %*% ((as.matrix(Obs[iobs,depVar]@data)-as.numeric(var1.pred))^2)
if (!pfull) {
ptinds = indx[ttinds,1]
preds = preds[ptinds]
var1.yam = var1.yam[ptinds]
}
predictionLocations@data$var1.pred[ttinds] = preds
predictionLocations@data$var1.var[ttinds] = wvar[istat]
predictionLocations@data$var1.yam[ttinds] = var1.yam
if (interactive() & debug.level == 1 & length(sinds) > 1) setTxtProgressBar(pb, istat)
}
if (interactive() & debug.level == 1 & length(sinds) > 1) close(pb)
} else {
object@sp$sindex = sindex = 1:nspace
object@time$tindex = tindex = 1:ntime
predictionLocations@sp$sindex = 1:pspace
predictionLocations@time$tindex = 1:ptime
obs = as.data.frame(object)
depVar = as.character(formulaString[[2]])
obs = obs[,c("sp.ID", "timeIndex", depVar)]
# obs$timeIndex = object@index[,2]
if (!requireNamespace("reshape2")) stop("reshape2 not available")
obs = reshape2::dcast(obs, sp.ID ~ timeIndex)
# reshape(obs, v.names = as.character(formulaString[[2]]),
# idvar = "sp.ID", timevar = "timeIndex", direction = "wide")
obs = obs[order(as.numeric(as.character(obs$sp.ID))), ]
obs = as.matrix(obs[,2:(ntime+1)])
if (!cv | !is.null(olags)) {
ploc = as.data.frame(predictionLocations)
ploc = cbind(ploc, var = 1)
ploc = ploc[,c("sp.ID", "timeIndex", "var")]
ploc$sp.ID = as.numeric(as.character(ploc$sp.ID))
ploc = reshape2::dcast(ploc, sp.ID ~ timeIndex)
ploc = as.matrix(ploc)
# spobs = NULL
}
if (interactive() & debug.level == 1 & ntime > 1) pb = txtProgressBar(1, ntime, style = 3)
spPredLoc = if (!cv) predictionLocations@sp else NULL
if (is.null(olags)) {
oldind = NULL
newkrige = 0
for (itime in 1:ptime) {
newind = which(!is.na(obs[,itime]))
if (length(newind) == 0) next
# print(paste(1, istat, itime, length(newind)))
if (is.null(oldind) || !isTRUE(all.equal(newind, oldind))) {
oldind = newind
newkrige = newkrige + 1
ppq = object[,itime]
vmat = varMatObs[newind, newind]
if (cv) {
vpredobs = NULL
} else {
vpredobs = varMatPredObs[newind,]
}
ret = rtopKrige.default(object = ppq, predictionLocations = spPredLoc, varMatObs = vmat,
varMatPredObs = vpredobs, params = params,
formulaString = formulaString, wret = TRUE, debug.level = 0)#,
weight = ret$weight
wvar = ret$predictions$var1.var
}
ob = obs[,itime]
ob = ob[!is.na(ob)]
preds = weight %*% ob
var1.yam = rep(NA, dim(weight)[1])
for (istat in 1:dim(weight)[1]) {
diffs = ob - preds[istat]
var1.yam[istat] = sum(weight[istat,] * t(diffs^2))
}
itind = tinds[itime]
ttinds = which(indx[,2] == itind)
if (!pfull & FALSE) {
ptinds = indx[ttinds,1]
preds = preds[ptinds]
var1.yam = var1.yam[ptinds]
}
predictionLocations@data$var1.pred[ttinds] = preds
predictionLocations@data$var1.var[ttinds] = wvar
predictionLocations@data$var1.yam[ttinds] = var1.yam
if (interactive() & debug.level == 1 & ntime > 1) setTxtProgressBar(pb, itime)
}
} else {
ntot = dim(predictionLocations@data)[1]
if (interactive() & debug.level == 1 & ntime > 1) pb = txtProgressBar(1, ntot, style = 3)
itot = 0
objsp = object@sp
objsp = SpatialPointsDataFrame(SpatialPoints(objsp), data = objsp@data)
newkrige = 0
obs2 = obs
for (istat in 1:pspace) {
# neigh = which(distm < maxdist)
ispace = predictionLocations@sp@data$sindex[istat]
pxts = as.data.frame(predictionLocations[istat,])
stpred = predictionLocations@sp[istat,]
distm = spDistsN1(coordinates(object@sp),coordinates(stpred))
ppred = SpatialPoints(stpred)
rolags = olags - plags[istat] # longer lags will be positive, i.e., use future observations
nbefore = -floor(min(rolags))
nafter = ceiling(max(c(rolags, 1)))
naadd1 = matrix(NA, nrow = nspace, ncol = nbefore)#, dimnames = list(as.character(1:nbefore), names(obs)))
naadd2 = matrix(NA, nrow = nspace, ncol = nafter)#, dimnames = list(names(obs)as.character(1:nafter)))
obsb = cbind(naadd1, cbind(obs2, naadd2))
obs[,] = NA
if (!lagExact) {
rolags = round(rolags, 0)
for (jstat in 1:nspace) {
obs[jstat, ] = obsb[jstat, (nbefore + 1 + rolags[jstat]) : (nbefore + ntime + rolags[jstat])]
}
} else {
rdiff = rolags - floor(rolags)
for (jstat in 1:nspace) {
nf = (nbefore + 1 + floor(rolags[jstat])) : (nbefore + ntime + floor(rolags[jstat]))
nl = (nbefore + 1 + ceiling(rolags[jstat])) : (nbefore + ntime + ceiling(rolags[jstat]))
obs[jstat, ] = obsb[jstat, nf] * (1-rdiff[jstat]) + obsb[jstat, nl] * rdiff[jstat]
}
}
oldind = NULL
ntl = length(pxts$tindex)
preds = rep(NA, ntl)
var1.yam = rep(NA, ntl)
var1.var = rep(NA, ntl)
tms = as.numeric(as.character(pxts$tindex))
if (cv) vorder = order(varMatObs[istat,]) else vorder = order(varMatPredObs[istat])
for (itime in seq_along(tms)) {
jtime = tms[itime]
tp = ploc[istat, jtime]
if (is.na(tp)) next
newind = vorder[vorder %in% which(!is.na(obs[,jtime]))]
if (cv) newind = newind[-which(newind == istat)]
if (is.numeric(params$nmax) && length(newind) > params$nmax) newind = newind[1:params$nmax]
if (length(newind) == 0) next
newind = newind[newind %in% vorder]
# print(paste(1, istat, itime, length(newind)))
if (is.null(oldind) || !isTRUE(all.equal(newind, oldind))) {
oldind = newind
newkrige = newkrige + 1
# print(paste(2, istat, itime, length(newind), newkrige))
ppq = objsp[newind, ]
ppq$intvar = obs[newind, jtime]
vmat = varMatObs[newind, newind]
vpredobs = varMatPredObs[newind, istat, drop = FALSE]
# fmstring = as.formula(paste(names(ppq)[1], "~1"))
ret = rtopKrige.default(object = ppq, ppred, varMatObs = vmat,
varMatPredObs = vpredobs, params = params,
formulaString = intvar~1, wret = TRUE,
debug.level = 0, cv = FALSE)#,
weight = ret$weight
wvar = ret$predictions$var1.var
}
preds[itime] = sum(weight * obs[newind,jtime])
diffs = obs[newind,jtime] - preds[itime]
var1.yam[itime] = sum(weight * (diffs^2))
var1.var[itime] = wvar
itot = itot + 1
if (interactive() & debug.level == 1 & ntime > 1) setTxtProgressBar(pb, itot)
}
# print(paste(1, istat, itime, length(newind), newkrige))
itind = tinds[itime]
ttinds = which(indx[,1] == ispace)
predictionLocations@data$var1.pred[ttinds] = preds
predictionLocations@data$var1.var[ttinds] = var1.var
predictionLocations@data$var1.yam[ttinds] = var1.yam
}
}
if (interactive() & debug.level == 1 & ntime > 1) close(pb)
}
list(predictions = predictionLocations)
}
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