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#'Compute root mean square error
#'
#'Compute the root mean square error for an array of forecasts and an array of
#'observations. The RMSEs are computed along time_dim, the dimension which
#'corresponds to the startdate dimension. If comp_dim is given, the RMSEs are
#'computed only if obs along the comp_dim dimension are complete between
#'limits[1] and limits[2], i.e. there are no NAs between limits[1] and
#'limits[2]. This option can be activated if the user wishes to account only
#'for the forecasts for which the corresponding observations are available at
#'all leadtimes.\cr
#'The confidence interval is computed by the chi2 distribution.\cr
#'
#'@param exp A named numeric array of experimental data, with at least two
#' dimensions 'time_dim' and 'memb_dim'.
#'@param obs A named numeric array of observational data, same dimensions as
#' parameter 'exp' except along memb_dim.
#'@param time_dim A character string indicating the name of dimension along
#' which the correlations are computed. The default value is 'sdate'.
#'@param memb_dim A character string indicating the name of member (nobs/nexp)
#' dimension. The default value is 'member'.
#'@param comp_dim A character string indicating the name of dimension along which
#' obs is taken into account only if it is complete. The default value
#' is NULL.
#'@param limits A vector of two integers indicating the range along comp_dim to
#' be completed. The default value is c(1, length(comp_dim dimension)).
#'@param conf A logical value indicating whether to retrieve the confidence
#' intervals or not. The default value is TRUE.
#'@param conf.lev A numeric indicating the confidence level for the
#' regression computation. The default value is 0.95.
#'@param ncores An integer indicating the number of cores to use for parallel
#' computation. The default value is NULL.
#'
#'@return
#'A list containing the numeric arrays with dimension:\cr
#' c(nexp, nobs, all other dimensions of exp except time_dim).\cr
#'nexp is the number of experiment (i.e., memb_dim in exp), and nobs is the
#'number of observation (i.e., memb_dim in obs).\cr
#'\item{$rms}{
#' The root mean square error.
#'}
#'\item{$conf.lower}{
#' The lower confidence interval. Only present if \code{conf = TRUE}.
#'}
#'\item{$conf.upper}{
#' The upper confidence interval. Only present if \code{conf = TRUE}.
#'}
#'
#'@examples
#'# Load sample data as in Load() example:
#' set.seed(1)
#' exp1 <- array(rnorm(120), dim = c(member = 3, sdate = 5, ftime = 2, lon = 1, lat = 4))
#' set.seed(2)
#' obs1 <- array(rnorm(80), dim = c(member = 2, sdate = 5, ftime = 2, lon = 1, lat = 4))
#' set.seed(2)
#' na <- floor(runif(10, min = 1, max = 80))
#' obs1[na] <- NA
#' res <- RMS(exp1, obs1, comp_dim = 'ftime')
#' # Renew example when Ano and Smoothing are ready
#'
#'@rdname RMS
#'@import multiApply
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#'@export
RMS <- function(exp, obs, time_dim = 'sdate', memb_dim = 'member',
comp_dim = NULL, limits = NULL,
conf = TRUE, conf.lev = 0.95, ncores = NULL) {
# Check inputs
## exp and obs (1)
if (is.null(exp) | is.null(obs)) {
stop("Parameter 'exp' and 'obs' cannot be NULL.")
}
if (!is.numeric(exp) | !is.numeric(obs)) {
stop("Parameter 'exp' and 'obs' must be a numeric array.")
}
if (is.null(dim(exp)) | is.null(dim(obs))) {
stop(paste0("Parameter 'exp' and 'obs' must be at least two dimensions ",
"containing time_dim and memb_dim."))
}
if(any(is.null(names(dim(exp))))| any(nchar(names(dim(exp))) == 0) |
any(is.null(names(dim(obs))))| any(nchar(names(dim(obs))) == 0)) {
stop("Parameter 'exp' and 'obs' must have dimension names.")
}
if(!all(names(dim(exp)) %in% names(dim(obs))) |
!all(names(dim(obs)) %in% names(dim(exp)))) {
stop("Parameter 'exp' and 'obs' must have same dimension name")
}
## time_dim
if (!is.character(time_dim) | length(time_dim) > 1) {
stop("Parameter 'time_dim' must be a character string.")
}
if (!time_dim %in% names(dim(exp)) | !time_dim %in% names(dim(obs))) {
stop("Parameter 'time_dim' is not found in 'exp' or 'obs' dimension.")
}
## memb_dim
if (!is.character(memb_dim) | length(memb_dim) > 1) {
stop("Parameter 'memb_dim' must be a character string.")
}
if (!memb_dim %in% names(dim(exp)) | !memb_dim %in% names(dim(obs))) {
stop("Parameter 'memb_dim' is not found in 'exp' or 'obs' dimension.")
}
## comp_dim
if (!is.null(comp_dim)) {
if (!is.character(comp_dim) | length(comp_dim) > 1) {
stop("Parameter 'comp_dim' must be a character string.")
}
if (!comp_dim %in% names(dim(exp)) | !comp_dim %in% names(dim(obs))) {
stop("Parameter 'comp_dim' is not found in 'exp' or 'obs' dimension.")
}
}
## limits
if (!is.null(limits)) {
if (is.null(comp_dim)) {
stop("Paramter 'comp_dim' cannot be NULL if 'limits' is assigned.")
}
if (!is.numeric(limits) | any(limits %% 1 != 0) | any(limits < 0) |
length(limits) != 2 | any(limits > dim(exp)[comp_dim])) {
stop(paste0("Parameter 'limits' must be a vector of two positive ",
"integers smaller than the length of paramter 'comp_dim'."))
}
}
## conf
if (!is.logical(conf) | length(conf) > 1) {
stop("Parameter 'conf' must be one logical value.")
}
## conf.lev
if (!is.numeric(conf.lev) | conf.lev < 0 | conf.lev > 1 | length(conf.lev) > 1) {
stop("Parameter 'conf.lev' must be a numeric number between 0 and 1.")
}
## ncores
if (!is.null(ncores)) {
if (!is.numeric(ncores) | ncores %% 1 != 0 | ncores < 0 |
length(ncores) > 1) {
stop("Parameter 'ncores' must be a positive integer.")
}
}
## exp and obs (2)
name_exp <- sort(names(dim(exp)))
name_obs <- sort(names(dim(obs)))
name_exp <- name_exp[-which(name_exp == memb_dim)]
name_obs <- name_obs[-which(name_obs == memb_dim)]
if(!all(dim(exp)[name_exp] == dim(obs)[name_obs])) {
stop(paste0("Parameter 'exp' and 'obs' must have same length of ",
"all dimension expect 'memb_dim'."))
}
if (dim(exp)[time_dim] < 2) {
stop("The length of time_dim must be at least 2 to compute RMS.")
}
###############################
# Sort dimension
name_exp <- names(dim(exp))
name_obs <- names(dim(obs))
order_obs <- match(name_exp, name_obs)
###############################
# Remove data along comp_dim dim if there is at least one NA between limits
if (!is.null(comp_dim)) {
if (is.null(limits)) {
limits <- c(1, dim(obs)[comp_dim])
}
pos <- which(names(dim(obs)) == comp_dim)
obs_sub <- Subset(obs, pos, list(limits[1]:limits[2]))
outrows <- is.na(MeanDims(obs_sub, pos, na.rm = FALSE))
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outrows <- InsertDim(outrows, pos, dim(obs)[comp_dim])
obs[which(outrows)] <- NA
}
res <- Apply(list(exp, obs),
target_dims = list(c(time_dim, memb_dim),
c(time_dim, memb_dim)),
fun = .RMS,
time_dim = time_dim, memb_dim = memb_dim,
conf = conf, conf.lev = conf.lev, ncores = ncores)
return(res)
}
.RMS <- function(exp, obs, time_dim = 'sdate', memb_dim = 'member',
conf = TRUE, conf.lev = 0.95) {
# exp: [sdate, member_exp]
# obs: [sdate, member_obs]
n_exp <- as.numeric(dim(exp)[2])
n_obs <- as.numeric(dim(obs)[2])
n_sdate <- as.numeric(dim(exp)[1])
dif <- array(dim = c(sdate = n_sdate, n_exp = n_exp, n_obs = n_obs))
chi <- array(dim = c(nexp = n_exp, nobs = n_obs))
if (conf) {
conflow <- (1 - conf.lev) / 2
confhigh <- 1 - conflow
conf.lower <- array(dim = c(nexp = n_exp, nobs = n_obs))
conf.upper <- array(dim = c(nexp = n_exp, nobs = n_obs))
}
# dif
for (i in 1:n_obs) {
dif[, , i] <- sapply(1:n_exp, function(x) {exp[, x] - obs[, i]})
}
rms <- apply(dif^2, c(2, 3), mean, na.rm = TRUE)^0.5 #array(dim = c(n_exp, n_obs))
if (conf) {
#eno <- Eno(dif, 1) #count effective sample along sdate. dim = c(n_exp, n_obs)
eno <- Eno(dif, time_dim) #change to this line when Eno() is done
# conf.lower
chi <- sapply(1:n_obs, function(i) {
qchisq(confhigh, eno[, i] - 1)
})
conf.lower <- (eno * rms ** 2 / chi) ** 0.5
# conf.upper
chi <- sapply(1:n_obs, function(i) {
qchisq(conflow, eno[, i] - 1)
})
conf.upper <- (eno * rms ** 2 / chi) ** 0.5
}
if (conf) {
res <- list(rms = rms, conf.lower = conf.lower, conf.upper = conf.upper)
} else {
res <- list(rms = rms)
}
return(res)
}