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CVE/CVarE/R/predict_dim.R

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predict_dim_cv <- function(object) {
# Get centered training data and dimensions
X <- scale(object$X, center = TRUE, scale = FALSE)
n <- nrow(object$X) # umber of training data samples
Sigma <- (1 / n) * crossprod(X, X)
eig <- eigen(Sigma)
Sigma_root <- eig$vectors %*% tcrossprod(diag(sqrt(eig$values)), eig$vectors)
X <- X %*% solve(Sigma_root)
pred <- array(0, c(n, ncol(object$Fy), length(object$res)),
dimnames = list(NULL, NULL, names(object$res)))
for (dr.k in object$res) {
# get "name" of current dimension
k <- as.character(dr.k$k)
# Project dataset with current SDR basis
X.proj <- X %*% dr.k$B
for (i in 1:n) {
model <- mda::mars(X.proj[-i, ], object$Fy[-i, ])
pred[i, , k] <- predict(model, X.proj[i, , drop = FALSE])
}
}
MSE <- apply((pred - as.numeric(object$Fy))^2, 3, mean)
return(list(
MSE = MSE,
k = as.integer(names(which.min(MSE)))
))
}
predict_dim_elbow <- function(object) {
if (ncol(object$Fy) > 1) # TODO: Implement or find better way
stop("For multivariate or central models not supported yet.")
# extract original data from object (cve result)
X <- object$X
Y <- object$Y
# Get dimensions
n <- nrow(X)
p <- ncol(X)
losses <- vector("double", length(object$res))
names(losses) <- names(object$res)
# Compute per sample losses with alternative bandwidth for each dimension.
for (dr.k in object$res) {
# extract dimension specific estimates and dimensions.
k <- dr.k$k
V <- dr.k$V
# estimate bandwidth according alternative formula.
h <- estimate.bandwidth(X, k, sqrt(n), version = 2L)
# Projected `X`
XQ <- X %*% (diag(1, p) - tcrossprod(V)) # X (I - V V')
# Compute distances
d2 <- tcrossprod(XQ) # XQ XQ'
d1 <- matrix(diag(d2), n, n)
D <- d1 - 2 * d2 + t(d1)
# Apply kernel
# Note: CVE uses for d = ||Q(X_i - X_j)|| the kernel exp(-d^4 / (2 h^2))
K <- exp((-0.5 / h^2) * D^2)
# sum columns
colSumsK <- colSums(K)
# compute weighted and square meighted reponses
y1 <- (K %*% Y) / colSumsK
y2 <- (K %*% Y^2) / colSumsK
# total loss
losses[[as.character(k)]] <- mean(y2 - y1^2)
}
return(list(
losses = losses,
k = as.integer(names(which.min(losses)))
))
}
predict_dim_wilcoxon <- function(object, p.value = 0.05) {
if (ncol(object$Fy) > 1) # TODO: Implement or find better way
stop("For multivariate or central models not supported yet.")
# extract original data from object (cve result)
X <- object$X
Y <- object$Y
# Get dimensions
n <- nrow(X)
p <- ncol(X)
L <- matrix(NA, n, length(object$res))
colnames(L) <- names(object$res)
# Compute per sample losses with alternative bandwidth for each dimension.
for (dr.k in object$res) {
# extract dimension specific estimates and dimensions.
k <- dr.k$k
V <- dr.k$V
# estimate bandwidth according alternative formula.
h <- estimate.bandwidth(X, k, sqrt(n), version = 2L)
# Projected `X`
XQ <- X %*% (diag(1, p) - tcrossprod(V)) # X (I - V V')
# Compute distances
d2 <- tcrossprod(XQ) # XQ XQ'
d1 <- matrix(diag(d2), n, n)
D <- d1 - 2 * d2 + t(d1)
# Apply kernel
# Note: CVE uses for d = ||Q(X_i - X_j)|| the kernel exp(-d^4 / (2 h^2))
K <- exp((-0.5 / h^2) * D^2)
# sum columns
colSumsK <- colSums(K)
# compute weighted and square meighted reponses
y1 <- (K %*% Y) / colSumsK
y2 <- (K %*% Y^2) / colSumsK
# element-wise L for dim. k
L[, as.character(k)] <- y2 - y1^2
}
for (ind in seq_len(length(object$res) - 1L)) {
p.test <- wilcox.test(L[, ind], L[, ind + 1L],
alternative = "less")$p.value
if (p.test < p.value) {
return(list(
p.value = p.test,
k = object$res[[ind]]$k
))
}
}
return(list(
p.value = NA,
k = object$res[[length(object$res)]]$k
))
}
#' Estimate Dimension of the Sufficient Reduction.
#'
#' This function estimates the dimension, i.e. the rank of \eqn{B}. The default
#' method \code{'CV'} performs leave-one-out (LOO) cross-validation using
#' \code{mars} as follows for \code{k = min.dim, ..., max.dim} a
#' cross-validation via \code{mars} is
#' performed on the dataset \eqn{(Y_i, B_k' X_i)_{i = 1, ..., n}} where
#' \eqn{B_k} is the \eqn{p \times k}{p x k} dimensional CVE estimate. The
#' estimated SDR dimension is the \eqn{k} where the
#' cross-validation mean squared error is minimal. The method \code{'elbow'}
#' estimates the dimension via \eqn{k = argmin_k L_n(V_{p - k})} where
#' \eqn{V_{p - k}} is the space that is orthogonal to the column space of the
#' CVE estimate of \eqn{B_k}. Method \code{'wilcoxon'} finds the minimum using
#' the Wilcoxon test.
#'
#' @param object an object of class \code{"cve"}, usually, a result of a call to
#' \code{\link{cve}} or \code{\link{cve.call}}.
#' @param method This parameter specifies which method is used in dimension
#' estimation. It provides three options: \code{'CV'} (default),
#' \code{'elbow'} and \code{'wilcoxon'}.
#' @param ... ignored.
#'
#' @return A \code{list} with
#' \describe{
#' \item{}{criterion for method and \code{k = min.dim, ..., max.dim}.}
#' \item{k}{estimated dimension is the minimizer of the criterion.}
#' }
#'
#' @examples
#' # create B for simulation
#' B <- rep(1, 5) / sqrt(5)
#'
#' set.seed(21)
#' # creat predictor data x ~ N(0, I_p)
#' x <- matrix(rnorm(500), 100)
#'
#' # simulate response variable
#' # y = f(B'x) + err
#' # with f(x1) = x1 and err ~ N(0, 0.25^2)
#' y <- x %*% B + 0.25 * rnorm(100)
#'
#' # Calculate cve for unknown k between min.dim and max.dim.
#' cve.obj.simple <- cve(y ~ x)
#'
#' predict_dim(cve.obj.simple)
#'
#' @export
predict_dim <- function(object, ..., method = "CV") {
# Check if there are dimensions to select.
if (length(object$res) == 1L) {
return(list(
message = "Only one dim. estimated.",
k = as.integer(names(object$res))
))
}
# Determine method "fuzzy".
methods <- c("cv", "elbow", "wilcoxon")
names(methods) <- methods
method <- methods[[tolower(method), exact = FALSE]]
if (is.null(method)) {
stop('Unable to determine method.')
}
if (method == "cv") {
return(predict_dim_cv(object))
} else if (method == "elbow") {
return(predict_dim_elbow(object))
} else if (method == "wilcoxon") {
return(predict_dim_wilcoxon(object))
} else {
stop("Unable to determine method.")
}
}
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