#' Incremental Processing Shift-Detection based on EWMA (SD-EWMA).
#'
#' @description \code{IpSdEwma} allows the calculation of anomalies
#' using SD-EWMA in an incremental processing mode. See also
#' \code{\link{OipSdEwma}}, the optimized and faster function of this function
#' SD-EWMA algorithm is a novel method for covariate shift-detection tests
#' based on a two-stage structure for univariate time-series. It works in an
#' online mode and it uses an exponentially weighted moving average (EWMA)
#' model based control chart to detect the covariate shift-point in
#' non-stationary time-series.
#'
#' @param data Numerical vector with training and test dataset.
#' @param n.train Number of points of the dataset that correspond to the
#' training set.
#' @param threshold Error smoothing constant.
#' @param l Control limit multiplier.
#' @param last.res Last result returned by the algorithm.
#'
#' @details \code{data} must be a numerical vector without NA values.
#' \code{threshold} must be a numeric value between 0 and 1. It is recommended
#' to use low values such as 0.01 or 0.05. By default, 0.01 is used. \code{l} is
#' the parameter that determines the control limits. By default, 3 is used.
#' Finally \code{last.res} is the last result returned by some previous
#' execution of this algorithm. The first time the algorithm is executed its
#' value is NULL. However, to run a new batch
#' of data without having to include it in the old dataset and restart the
#' process, the two parameters returned by the last run are only needed.
#'
#' This algorithm can be used for both classical and incremental processing. It
#' should be noted that in case of having a finite dataset the
#' \code{\link{CpSdEwma}} or \code{\link{OcpSdEwma}} algorithms are faster.
#' Incremental processing can be used in two ways. 1) Processing all available
#' data and saving \code{last.res} for future runs in which there is new data.
#' 2) Using the \href{https://CRAN.R-project.org/package=stream}{stream} library
#' for when there is too much data and it does not fit into memory. An example
#' has been made for this use case.
#'
#' @return A list of the following items.
#'
#' \item{result}{dataset conformed by the following columns.}
#' \itemize{
#' \item \code{is.anomaly} 1 if the value is anomalous 0 otherwise.
#' \item \code{ucl} Upper control limit.
#' \item \code{lcl} Lower control limit.
#' }
#' \item{last.res}{Last result returned by the algorithm. Is a dataset
#' containing the parameters calculated in the last iteration and necessary
#' for the next one.}
#'
#' @references Raza, H., Prasad, G., & Li, Y. (03 de 2015). EWMA model based
#' shift-detection methods for detecting covariate shifts in non-stationary
#' environments. Pattern Recognition, 48(3), 659-669.
#'
#' @example tests/examples/ip_sd_ewma_example.R
#'
#' @export
IpSdEwma <- function(data, n.train, threshold = 0.01, l = 3, last.res = NULL) {
# validate parameters
if (!is.numeric(data) | (sum(is.na(data)) > 0)) {
stop("data argument must be a numeric vector and without NA values.")
}
if (!is.numeric(n.train) | n.train <= 0) {
stop("n.train argument must be a positive numeric value.")
}
if (!is.numeric(threshold) | threshold <= 0 | threshold > 1) {
stop("threshold argument must be a numeric value in (0,1] range.")
}
if (!is.numeric(l)) {
stop("l argument must be a numeric value.")
}
if (!is.null(last.res) & !is.data.frame(last.res)) {
stop("last.res argument must be NULL or a data.frame with las execution result.")
}
# Auxiliar function SdEwma train phase
SdEwmaTrain <- function(row, x) {
row$x <- x
row$i <- row$i + 1
row$z.ant <- row$z
row$std.ant <- row$std
row$z <- row$lambda * row$x + (1 - row$lambda) * row$z.ant
row$error <- row$x - row$z.ant
row$error.sum <- row$error.sum + row$error^2
row$std <- row$error.sum / row$i
row
}
# Auxiliar function SdEwma test phase
SdEwmaTest <- function(row, x) {
row$i <- row$i + 1
row$x <- x
row$z.ant <- row$z
row$std.ant <- row$std
row$z <- row$lambda * row$x + (1 - row$lambda) * row$z.ant
row$error <- row$x - row$z.ant
row$std <- threshold * row$error ^ 2 + (1 - threshold) * row$std.ant
row$ucl <- row$z.ant + l[1] * sqrt(row$std.ant)
row$lcl <- row$z.ant - l[1] * sqrt(row$std.ant)
row$is.anomaly <- row$x < row$lcl | row$x > row$ucl
row
}
# Initialize the parameters
lambdas <- seq(0.1, 1, 0.1)
if (is.null(last.res)) {
last.res <- data.frame(lambda = lambdas,
i = 0,
x = data[1],
z.ant = 0,
std.ant = 0,
z = data[1],
error = 0,
std = 0,
error.sum = 0)
}
res <- NULL
# prepare train and test
n <- length(data)
aux <- n.train - unique(last.res$i)
if (n <= aux) {
train.data <- data
test.data <- NULL
} else if (aux <= 0) {
train.data <- NULL
test.data <- data
} else {
train.data <- data[1:aux]
test.data <- data[(aux + 1):n]
}
# Training phase
if (!is.null(train.data)) {
for (i in 1:length(train.data)) {
last.res <- SdEwmaTrain(last.res, train.data[i])
}
}
if (unique(last.res$i) == n.train) {
last.res <- last.res[last.res$error.sum == min(last.res$error.sum),]
last.res <- last.res[1,]
}
# Testing phase
if (!is.null(test.data)) {
for (i in 1:length(test.data)) {
last.res <- SdEwmaTest(last.res, test.data[i])
res <- rbind(res, last.res[,c("is.anomaly", "lcl", "ucl")])
}
}
if (!is.null(train.data)) {
v <- rep(0, length(train.data))
tra <- data.frame(is.anomaly = v, lcl = train.data, ucl = train.data, stringsAsFactors = FALSE)
res <- rbind(tra, res)
}
return(list(result = res, last.res = last.res))
}
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