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R/mednnormals.R
In CoreGx: Classes and Functions to Serve as the Basis for Other 'Gx' Packages
Defines functions
.rmednnormals
.dmednnormals
.pmednnormals
.edmednnormals
.rmednnormals = function(N, n, scale) {
x <- matrix(NA, nrow = 1, ncol = N)
for (i in seq_len(N)) {
x[i] <- median(rnorm(n, sd = scale))
}
return(x)
}
#' @importFrom stats rnorm
#' @importFrom stats dnorm
.dmednnormals = function(x, n, scale, divisions = 100) {
n <- rep(n, times = length(x) / length(n))
scale <- rep(scale, times = length(x) / length(scale))
y <- matrix(NA, nrow = 1, ncol = length(x))
for (g in seq_along(x)) {
if (n[g] %% 2 == 0) {
y[g] <- 2 * .multinom(n[g], c(n[g] / 2 - 1, n[g] / 2 - 1)) *
tryCatch(integrate(f = function(j) {
(pnorm(x[g] - j / 2, sd = scale[g])) ^ (n[g] / 2 - 1) *
(1 - pnorm(x[g] + j / 2, sd = scale[g])) ^ (n[g] / 2 - 1) *
dnorm(x[g] - j / 2, sd = scale[g]) *
dnorm(x[g] + j / 2, sd = scale[g])},
lower = 0,
upper = Inf,
subdivisions = divisions)[[1]],
error = function(e) {
if (divisions == 1) {
wseq <- c(1, 4, 1)
} else {
wseq <- c(1, 4, rep(c(2, 4), times = divisions - 1), 1)
}
aseq <- seq(from = 0, to = pi / 2, length.out = 2 * divisions + 1)
tseq <- tan(aseq) / 2
return(sum((pnorm(x[g] + tseq, sd = scale[g])) ^ (n[g] / 2 - 1) *
(pnorm(x[g] - tseq, sd = scale[g])) ^ (n[g] / 2 - 1) *
dnorm(x[g] + tseq, sd = scale[g]) *
dnorm(x[g] - tseq, sd = scale[g]) /
(cos(aseq)) ^ 2 * wseq) *
(aseq[2] - aseq[1]) / 6)
})
} else {
y[g] <- .multinom(n[g], c((n[g] - 1) / 2, (n[g] - 1) / 2)) *
(pnorm(x[g], sd = scale[g])) ^ ((n[g] - 1) / 2) *
(1 - pnorm(x[g], sd = scale[g])) ^ ((n[g] - 1) / 2) *
dnorm(x[g], sd = scale[g])
}
}
return(y)
}
#' @importFrom stats integrate
.pmednnormals = function(x, n, scale, divisions = 100) {
n <- rep(n, times = length(x) / length(n))
scale <- rep(scale, times = length(x) / length(scale))
y <- numeric(length(x))
for (g in seq_along(x)) {
if (n[g] %% 2 == 0) {
y[g] <- tryCatch(integrate(f = function(k) {.dmednnormals(k, n[g], scale[g])},
lower = -Inf,
upper = x[g],
subdivisions = divisions)[[1]],
error = function(e) {
wseq <- c(1, 4, rep(c(2, 4), times = divisions - 1), 1)
aseq <- seq(from = -pi / 2, to = atan(x[g]), length.out = 2 * divisions + 1)
return(sum(.dmednnormals(tan(aseq), n[g], scale[g]) * wseq / (cos(aseq)) ^ 2) * (aseq[3] - aseq[1]) / 6)})
} else {
y[g] <- 0
Fx <- pnorm(x[g], sd = scale[g])
for (i in 0:((n[g] - 1) / 2)) {
y[g] <- y[g] + choose((n[g] - 1) / 2, i) * (-1) ^ i * Fx ^ ((n[g] + 1) / 2 + i) / ((n[g] + 1) / 2 + i)
}
y[g] <- y[g] * .multinom(n[g], c((n[g] - 1) / 2, (n[g] - 1) / 2))
}
}
return(y)
}
#' @importFrom stats integrate
.edmednnormals = function(x, n, scale, divisions = 100) {
n <- rep(n, times = length(x) / length(n))
scale <- rep(scale, times = length(x) / length(scale))
y <- numeric(length(x))
for (g in seq_along(y)) {
if (x[g] > 0) {
upper <- Inf
lower <- x[g]
} else {
upper <- x[g]
lower <- -Inf
}
y[g] <- tryCatch(integrate(f = function(k) {(.dmednnormals(k, n[g], scale[g])) ^ 2},
lower = lower,
upper = upper,
subdivisions = divisions)[[1]],
error = function(e) {
wseq <- c(1, 4, rep(c(2, 4), times = divisions - 1), 1)
aseq <- seq(from = atan(lower), to = atan(upper), length.out = 2 * divisions + 1)
return(sum((.dmednnormals(tan(aseq), n[g], scale[g])) ^ 2 * wseq / (cos(aseq)) ^ 2) * (aseq[3] - aseq[1]) / 6)})
}
return(y)
}
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CoreGx documentation built on Dec. 20, 2019, 1:08 a.m.
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Defines functions .rmednnormals .dmednnormals .pmednnormals .edmednnormals
.rmednnormals = function(N, n, scale) {
x <- matrix(NA, nrow = 1, ncol = N)
for (i in seq_len(N)) {
x[i] <- median(rnorm(n, sd = scale))
}
return(x)
}
#' @importFrom stats rnorm
#' @importFrom stats dnorm
.dmednnormals = function(x, n, scale, divisions = 100) {
n <- rep(n, times = length(x) / length(n))
scale <- rep(scale, times = length(x) / length(scale))
y <- matrix(NA, nrow = 1, ncol = length(x))
for (g in seq_along(x)) {
if (n[g] %% 2 == 0) {
y[g] <- 2 * .multinom(n[g], c(n[g] / 2 - 1, n[g] / 2 - 1)) *
tryCatch(integrate(f = function(j) {
(pnorm(x[g] - j / 2, sd = scale[g])) ^ (n[g] / 2 - 1) *
(1 - pnorm(x[g] + j / 2, sd = scale[g])) ^ (n[g] / 2 - 1) *
dnorm(x[g] - j / 2, sd = scale[g]) *
dnorm(x[g] + j / 2, sd = scale[g])},
lower = 0,
upper = Inf,
subdivisions = divisions)[[1]],
error = function(e) {
if (divisions == 1) {
wseq <- c(1, 4, 1)
} else {
wseq <- c(1, 4, rep(c(2, 4), times = divisions - 1), 1)
}
aseq <- seq(from = 0, to = pi / 2, length.out = 2 * divisions + 1)
tseq <- tan(aseq) / 2
return(sum((pnorm(x[g] + tseq, sd = scale[g])) ^ (n[g] / 2 - 1) *
(pnorm(x[g] - tseq, sd = scale[g])) ^ (n[g] / 2 - 1) *
dnorm(x[g] + tseq, sd = scale[g]) *
dnorm(x[g] - tseq, sd = scale[g]) /
(cos(aseq)) ^ 2 * wseq) *
(aseq[2] - aseq[1]) / 6)
})
} else {
y[g] <- .multinom(n[g], c((n[g] - 1) / 2, (n[g] - 1) / 2)) *
(pnorm(x[g], sd = scale[g])) ^ ((n[g] - 1) / 2) *
(1 - pnorm(x[g], sd = scale[g])) ^ ((n[g] - 1) / 2) *
dnorm(x[g], sd = scale[g])
}
}
return(y)
}
#' @importFrom stats integrate
.pmednnormals = function(x, n, scale, divisions = 100) {
n <- rep(n, times = length(x) / length(n))
scale <- rep(scale, times = length(x) / length(scale))
y <- numeric(length(x))
for (g in seq_along(x)) {
if (n[g] %% 2 == 0) {
y[g] <- tryCatch(integrate(f = function(k) {.dmednnormals(k, n[g], scale[g])},
lower = -Inf,
upper = x[g],
subdivisions = divisions)[[1]],
error = function(e) {
wseq <- c(1, 4, rep(c(2, 4), times = divisions - 1), 1)
aseq <- seq(from = -pi / 2, to = atan(x[g]), length.out = 2 * divisions + 1)
return(sum(.dmednnormals(tan(aseq), n[g], scale[g]) * wseq / (cos(aseq)) ^ 2) * (aseq[3] - aseq[1]) / 6)})
} else {
y[g] <- 0
Fx <- pnorm(x[g], sd = scale[g])
for (i in 0:((n[g] - 1) / 2)) {
y[g] <- y[g] + choose((n[g] - 1) / 2, i) * (-1) ^ i * Fx ^ ((n[g] + 1) / 2 + i) / ((n[g] + 1) / 2 + i)
}
y[g] <- y[g] * .multinom(n[g], c((n[g] - 1) / 2, (n[g] - 1) / 2))
}
}
return(y)
}
#' @importFrom stats integrate
.edmednnormals = function(x, n, scale, divisions = 100) {
n <- rep(n, times = length(x) / length(n))
scale <- rep(scale, times = length(x) / length(scale))
y <- numeric(length(x))
for (g in seq_along(y)) {
if (x[g] > 0) {
upper <- Inf
lower <- x[g]
} else {
upper <- x[g]
lower <- -Inf
}
y[g] <- tryCatch(integrate(f = function(k) {(.dmednnormals(k, n[g], scale[g])) ^ 2},
lower = lower,
upper = upper,
subdivisions = divisions)[[1]],
error = function(e) {
wseq <- c(1, 4, rep(c(2, 4), times = divisions - 1), 1)
aseq <- seq(from = atan(lower), to = atan(upper), length.out = 2 * divisions + 1)
return(sum((.dmednnormals(tan(aseq), n[g], scale[g])) ^ 2 * wseq / (cos(aseq)) ^ 2) * (aseq[3] - aseq[1]) / 6)})
}
return(y)
}
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