SMR: The externally studentized normal midrange distribution
In SMR: Externally Studentized Midrange Distribution
SMR R Documentation
The externally studentized normal midrange distribution
Description
Computes the probability density, the cumulative distribution function and the quantile function and generates random samples for the externally studentized normal midrange distribution with the numbers means equal to size, the degrees of freedom equal to df and the number of
points of the Gauss-Legendre quadrature equal to np.
Usage
dSMR(x, size, df, np=32, log = FALSE)
pSMR(q, size, df, np=32, lower.tail = TRUE, log.p = FALSE)
qSMR(p, size, df, np=32, eps = 1e-13, maxit = 5000, lower.tail = TRUE, log.p = FALSE)
rSMR(n, size, df = Inf)
Arguments
x, q
vector of quantiles x \in R and q \in R.
p
vector of probabilities (0, 1).
size
sample size. Only for size > 1.
n
vector size to be simulated n > 1.
df
degrees of freedom df > 0.
np
number of points of the gaussian quadrature np > 2.
log, log.p
logical argument; if TRUE, the probabilities p are given as log(p).
lower.tail
logical argument; if TRUE, the probabilities are P[X \leq x] otherside, P[X \geq x].
eps
stopping criterion for Newton-Raphson's iteraction method.
maxit
maximum number of interaction in the Newton-Raphson method.
Details
Assumes np = 32 as default value for dSMR, pSMR and qSMR. If df is not specified, it assumes the default value Inf in rSMR. When df=1, the convergence of the routines requires np>250 to obtain the desired result accurately.
The Midrange distribution has density
f(\overline{q};n,\nu) =\int^{\infty}_{0}
\int^{x\overline{q}}_{-\infty}2n(n-1)x\phi(y) \phi(2x\overline{q}-y)[\Phi(2x\overline{q}-y)-\Phi(y)]^{n-2}f(x;\nu)dydx,
where, q is the quantile of externally studentized midrange distribution, n (size) is the sample size and \nu is the degrees of freedon.
The externally studentized midrange distribution function is given by
F(\overline{q};n,\nu)=\int^{\overline{q}}_{-\infty}
\int^{\infty}_{0}\int^{x\overline{q}}_{-\infty}2n(n-1)x\phi(y) \phi(2xz-y)[\Phi(2xz-y)-\Phi(y)]^{n-2}f(x;\nu)dydxdz.
where, q is the quantile of externally studentized midrange distribution, n (size) is the sample size and \nu is the degrees of freedon.
Value
dSMR gives the density, pSMR gives the cumulative distribution function, qSMR gives the quantile function, and rSMR
generates random deviates.
References
BATISTA, B. D. de O.; FERREIRA, D. F. SMR: An R package for computing the externally studentized normal midrange distribution. The R Journal, v. 6, n. 2, p. 123-136, dez. 2014.
Examples
library(SMR)
#example 1:
x <- 2
q <- 1
p <- 0.9
n <- 30
size <- 5
df <- 3
np <- 32
dSMR(x, size, df, np)
pSMR(q, size, df, np)
qSMR(p, size, df, np)
rSMR(n, size, df)
#example 2:
x <- c(-1, 2, 1.1)
q <- c(1, 0, -1.5)
p <- c(0.9, 1, 0.8)
n <- 10
size <- 5
df <- 3
np <- 32
dSMR(x, size, df, np)
pSMR(q, size, df, np)
qSMR(p, size, df, np)
rSMR(n, size, df)
SMR documentation built on Oct. 8, 2023, 1:07 a.m.
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| SMR | R Documentation |
The externally studentized normal midrange distribution
Description
Computes the probability density, the cumulative distribution function and the quantile function and generates random samples for the externally studentized normal midrange distribution with the numbers means equal to size, the degrees of freedom equal to df and the number of
points of the Gauss-Legendre quadrature equal to np.
Usage
dSMR(x, size, df, np=32, log = FALSE)
pSMR(q, size, df, np=32, lower.tail = TRUE, log.p = FALSE)
qSMR(p, size, df, np=32, eps = 1e-13, maxit = 5000, lower.tail = TRUE, log.p = FALSE)
rSMR(n, size, df = Inf)Arguments
x, q |
vector of quantiles |
p |
vector of probabilities |
size |
sample size. Only for |
n |
vector size to be simulated |
df |
degrees of freedom |
np |
number of points of the gaussian quadrature |
log, log.p |
logical argument; if |
lower.tail |
logical argument; if |
eps |
stopping criterion for Newton-Raphson's iteraction method. |
maxit |
maximum number of interaction in the Newton-Raphson method. |
Details
Assumes np = 32 as default value for dSMR, pSMR and qSMR. If df is not specified, it assumes the default value Inf in rSMR. When df=1, the convergence of the routines requires np>250 to obtain the desired result accurately.
The Midrange distribution has density
f(\overline{q};n,\nu) =\int^{\infty}_{0}
\int^{x\overline{q}}_{-\infty}2n(n-1)x\phi(y) \phi(2x\overline{q}-y)[\Phi(2x\overline{q}-y)-\Phi(y)]^{n-2}f(x;\nu)dydx,
where, q is the quantile of externally studentized midrange distribution, n (size) is the sample size and \nu is the degrees of freedon.
The externally studentized midrange distribution function is given by
F(\overline{q};n,\nu)=\int^{\overline{q}}_{-\infty}
\int^{\infty}_{0}\int^{x\overline{q}}_{-\infty}2n(n-1)x\phi(y) \phi(2xz-y)[\Phi(2xz-y)-\Phi(y)]^{n-2}f(x;\nu)dydxdz.
where, q is the quantile of externally studentized midrange distribution, n (size) is the sample size and \nu is the degrees of freedon.
Value
dSMR gives the density, pSMR gives the cumulative distribution function, qSMR gives the quantile function, and rSMR
generates random deviates.
References
BATISTA, B. D. de O.; FERREIRA, D. F. SMR: An R package for computing the externally studentized normal midrange distribution. The R Journal, v. 6, n. 2, p. 123-136, dez. 2014.
Examples
library(SMR)
#example 1:
x <- 2
q <- 1
p <- 0.9
n <- 30
size <- 5
df <- 3
np <- 32
dSMR(x, size, df, np)
pSMR(q, size, df, np)
qSMR(p, size, df, np)
rSMR(n, size, df)
#example 2:
x <- c(-1, 2, 1.1)
q <- c(1, 0, -1.5)
p <- c(0.9, 1, 0.8)
n <- 10
size <- 5
df <- 3
np <- 32
dSMR(x, size, df, np)
pSMR(q, size, df, np)
qSMR(p, size, df, np)
rSMR(n, size, df)
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