Density function, distribution function, quantiles and random number generation for the skew-\(t\) (ST) distribution.
dst(x, xi=0, omega=1, alpha=0, nu=Inf, dp=NULL, log=FALSE)
pst(x, xi=0, omega=1, alpha=0, nu=Inf, dp=NULL, method=0, lower.tail=TRUE,
log.p=FALSE, ...)
qst(p, xi=0, omega=1, alpha=0, nu=Inf, tol=1e-08, dp=NULL, method=0, ...)
rst(n=1, xi=0, omega=1, alpha=0, nu=Inf, dp=NULL)
Density (dst
), probability (pst
), quantiles (qst
)
and random sample (rst
) from the skew-\(t\) distribution with given
xi
, omega
, alpha
and nu
parameters.
vector of quantiles. Missing values (NA
s) are allowed.
vector of probabililities.
vector of location parameters.
vector of scale parameters; must be positive.
vector of slant parameters. With pst
and qst
,
it must be of length 1.
a single positive value representing the degrees of freedom;
it can be non-integer. Default value is nu=Inf
which corresponds
to the skew-normal distribution.
a vector of length 4, whose elements represent location, scale
(positive), slant and degrees of freedom, respectively. If dp
is
specified, the individual parameters cannot be set.
a positive integer representing the sample size.
logical; if TRUE
, densities are given as log-densities
and probabilities p
are given as log(p)
a scalar value which regulates the accuracy of the result of
qsn
, measured on the probability scale.
an integer value between 0
and 5
which selects
the computing method; see ‘Details’ below for the meaning of these
values. If method=0
(default value), an automatic choice is made
among the four actual computing methods, depending on the other
arguments.
logical; if TRUE
(default), probabilities are \(P\{X\le x\}\),
otherwise \(P\{X\ge x\}\)
additional parameters passed to integrate
or pmst
.
The family of skew-\(t\) distributions is an extension of the Student's
\(t\) family, via the introduction of a alpha
parameter which
regulates skewness; when alpha=0
, the skew-\(t\) distribution
reduces to the usual Student's \(t\) distribution.
When nu=Inf
, it reduces to the skew-normal distribution.
When nu=1
, it reduces to a form of skew-Cauchy distribution.
See Chapter 4 of Azzalini & Capitanio (2014) for additional information.
A multivariate version of the distribution exists; see dmst
.
For evaluation of pst
, and so indirectly of
qst
, four different methods are employed.
In all the cases, the actual computations are performed for the normalized
values z=(x-xi)/omega
).
Method 1 consists in using pmst
with dimension d=1
.
Method 2 applies integrate
to the density function dst
.
Method 3 again uses integrate
too but with a different integrand,
as given in Section 4.2 of Azzalini & Capitanio (2003, full version of
the paper).
Method 4 consists in the recursive procedure of Jamalizadeh, Khosravi and
Balakrishnan (2009), which is recalled in Complement 4.3 on
Azzalini & Capitanio (2014); the recursion over nu
starts from
the explicit expression for nu=1
given by psc
.
Method 5 is targeted to tail probabilities only, and it returns NA
s
for non-extreme x
values (those with abs(z)<=20
);
it is based on expressions given in Complement 4.4 of Azzalini and Capitanio (2014).
Method 1 and 4 are only suitable for integer values of nu
.
Method 4 becomes progressively less efficient as nu
increases,
because the value of nu
determines the number of nested calls,
but the decay of efficiency is slower for larger values of length(x)
.
If the default argument value method=0
is retained, an automatic choice
among the above four methods is made, which depends on the values of
nu, alpha, z
. The numerical accuracy of methods 1, 2 and 3 can
be regulated via the ...
argument, while method 4 is conceptually exact,
up to machine precision.
If qst
is called with nu>1e4
, the computation is transferred to
qsn
.
Azzalini, A. and Capitanio, A. (2003). Distributions generated by perturbation of symmetry with emphasis on a multivariate skew-t distribution. J.Roy. Statist. Soc. B 65, 367--389. Full version of the paper at https://arXiv.org/abs/0911.2342.
Azzalini, A. with the collaboration of Capitanio, A. (2014). The Skew-normal and Related Families. Cambridge University Press, IMS Monographs series.
Jamalizadeh, A., Khosravi, M., and Balakrishnan, N. (2009). Recurrence relations for distributions of a skew-t and a linear combination of order statistics from a bivariate-t. Comp. Statist. Data An. 53, 847--852.
dmst
, dsn
, dsc
pdf <- dst(seq(-4, 4, by=0.1), alpha=3, nu=5)
rnd <- rst(100, 5, 2, -5, 8)
q <- qst(c(0.25, 0.50, 0.75), alpha=3, nu=5)
pst(q, alpha=3, nu=5) # must give back c(0.25, 0.50, 0.75)
#
p1 <- pst(x=seq(-3,3, by=1), dp=c(0,1,pi, 3.5))
p2 <- pst(x=seq(-3,3, by=1), dp=c(0,1,pi, 3.5), method=2, rel.tol=1e-9)
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