Nothing
srre<-function (formula, r, R, dpn, delt, k, data = NULL, na.action,
...)
{
k <- as.matrix(k)
k1 <- k[1L]
srres <- function(formula, r, R, dpn, delt, k1, data = NULL,
na.action, ...) {
cal <- match.call(expand.dots = FALSE)
mat <- match(c("formula", "data", "na.action"), names(cal))
cal <- cal[c(1L, mat)]
cal[[1L]] <- as.name("model.frame")
cal <- eval(cal)
y <- model.response(cal)
md <- attr(cal, "terms")
x <- model.matrix(md, cal, contrasts)
s <- t(x) %*% x
xin <- solve(s)
r <- as.matrix(r)
RC <- matrix(R, NCOL(x))
RR <- t(RC)
if (is.matrix(R))
RR <- R
else RR <- RR
if (length(dpn) == 1L)
shi <- dpn
else if (is.matrix(dpn))
shi <- dpn
else shi <- diag(dpn)
de1 <- as.matrix(delt)
I <- diag(NCOL(x))
bb <- xin %*% t(x) %*% y
ev <- (t(y) %*% y - t(bb) %*% t(x) %*% y)/(NROW(x) -
NCOL(x))
ev <- diag(ev)
w1 <- solve(s/ev + t(RR) %*% solve(shi) %*% RR)
w2 <- (t(x) %*% y)/ev + t(RR) %*% solve(shi) %*% r
bm <- w1 %*% w2
tk <- solve(s + k1 * I) %*% s
bsrr <- tk %*% bm
colnames(bsrr) <- c("Estimate")
dbd <- ev * tk %*% solve(s + t(RR) %*% solve(shi/ev) %*%
RR) %*% tk
Standard_error <- sqrt(diag(abs(dbd)))
rdel <- matrix(delt, NROW(RR))
lenr <- length(RR)
dlpt <- diag(RR %*% xin %*% t(RR))
if (lenr == ncol(RR))
ilpt <- sqrt(solve(abs(dlpt)))
else ilpt <- sqrt(solve(diag(abs(dlpt))))
upt <- RR %*% bsrr
tb <- t(upt)
t_statistic <- ((tb - t(rdel)) %*% ilpt)/sqrt(ev)
tst <- t(2L * pt(-abs(t_statistic), df <- (NROW(x) -
NCOL(x))))
pvalue <- c(tst, rep(NA, (NCOL(x) - NROW(RR))))
dbd <- ev * tk %*% solve(s + t(RR) %*% solve(shi/ev) %*%
RR) %*% tk
bibet <- k1 * solve(s + k1 * I) %*% bb
bibets <- bibet %*% t(bibet)
mse <- dbd + bibets
mse1 <- sum(diag(mse))
mse1 <- round(mse1, digits <- 4L)
names(mse1) <- c("MSE")
t_statistic <- c(t_statistic, rep(NA, (NCOL(x) - NROW(RR))))
ans1 <- cbind(bsrr, Standard_error, t_statistic, pvalue)
ans <- round(ans1, digits <- 4L)
anw <- list(`*****Stochastic Restricted Ridge Estimator*****` = ans,
`*****Mean square error value*****` = mse1)
return(anw)
}
npt <- srres(formula, r, R, dpn, delt, k1, data, na.action)
plotsrr <- function(formula, r, R, dpn, delt, k, data = NULL,
na.action, ...) {
j <- 0
arr <- 0
for (j in 1:nrow(k)) {
srrem <- function(formula, r, R, dpn, delt, k, data,
na.action, ...) {
cal <- match.call(expand.dots = FALSE)
mat <- match(c("formula", "data", "na.action"),
names(cal))
cal <- cal[c(1L, mat)]
cal[[1L]] <- as.name("model.frame")
cal <- eval(cal)
y <- model.response(cal)
md <- attr(cal, "terms")
x <- model.matrix(md, cal, contrasts)
s <- t(x) %*% x
xin <- solve(s)
r <- as.matrix(r)
RC <- matrix(R, NCOL(x))
RR <- t(RC)
if (is.matrix(R))
RR <- R
else RR <- RR
if (length(dpn) == 1L)
shi <- dpn
else if (is.matrix(dpn))
shi <- dpn
else shi <- diag(dpn)
de1 <- as.matrix(delt)
I <- diag(NCOL(x))
bb <- xin %*% t(x) %*% y
ev <- (t(y) %*% y - t(bb) %*% t(x) %*% y)/(NROW(x) -
NCOL(x))
ev <- diag(ev)
tk <- solve(s + k * I) %*% s
dbd <- ev * tk %*% solve(s + t(RR) %*% solve(shi/ev) %*%
RR) %*% tk
bibet <- k * solve(s + k * I) %*% bb
bibets <- bibet %*% t(bibet)
mse <- dbd + bibets
mse1 <- sum(diag(mse))
return(mse1)
}
arr[j] <- srrem(formula, r, R, dpn, delt, k[j], data,
na.action)
}
MSE <- arr
Parameter <- k
pvl <- cbind(Parameter, MSE)
colnames(pvl) <- c("Parameter", "MSE")
sval <- pvl
return(sval)
}
psrre <- plotsrr(formula, r, R, dpn, delt, k, data, na.action)
if (nrow(k) > 1L)
val <- psrre
else val <- npt
val
}
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