https://github.com/cran/quantreg
Tip revision: c4c8cfa4df5fc01e1b3c73dfa4af2691c627297e authored by Roger Koenker on 06 August 2013, 00:00:00 UTC
version 5.01
version 5.01
Tip revision: c4c8cfa
rq.fit.br.Rd
\name{rq.fit.br}
\alias{rq.fit.br}
\title{
Quantile Regression Fitting by Exterior Point Methods
}
\description{
This function controls the details of QR fitting by the simplex approach
embodied in the algorithm of Koenker and d'Orey based on the median
regression algorithm of Barrodale and Roberts. Typically, options
controlling the construction of the confidence intervals would be passed
via the \code{\dots{}} argument of \code{rq()}.
}
\usage{
rq.fit.br(x, y, tau=0.5, alpha=0.1, ci=FALSE, iid=TRUE, interp=TRUE, tcrit=TRUE)
}
\arguments{
\item{x}{
the design matrix
}
\item{y}{
the response variable
}
\item{tau}{
the quantile desired, if tau lies outside (0,1) the whole process
is estimated.
}
\item{alpha}{
the nominal noncoverage probability for the confidence intervals, i.e. 1-alpha
is the nominal coverage probability of the intervals.
}
\item{ci}{
logical flag if T then compute confidence intervals for the parameters
using the rank inversion method of Koenker (1994). See \code{rq()} for more
details. If F then return only the estimated coefficients. Note that
for large problems the default option ci = TRUE can be rather slow.
Note also that rank inversion only works for p>1, an error message is
printed in the case that ci=T and p=1.
}
\item{iid}{
logical flag if T then the rank inversion is based on an assumption of
iid error model, if F then it is based on an nid error assumption.
See Koenker and Machado (1999) for further details on this distinction.
}
\item{interp}{
As with typical order statistic type confidence intervals the test
statistic is discrete, so it is reasonable to consider intervals that
interpolate between values of the parameter just below the specified
cutoff and values just above the specified cutoff. If \code{interp =
F} then
the 2 ``exact'' values above and below on which the interpolation would
be based are returned.
}
\item{tcrit}{
Logical flag if T - Student t critical values are used, if F then normal
values are used.
}
}
\value{
Returns an object of class \code{"rq"}
for tau in (0,1), or else of class \code{"rq.process"}.
Note that \code{rq.fit.br} when called for a single tau value
will return the vector of optimal dual variables.
See \code{\link{rq.object}} and \code{\link{rq.process.object}}
for further details.
}
\details{
If tau lies in (0,1) then an object of class \code{"rq"} is
returned with various
related inference apparatus. If tau lies outside [0,1] then an object
of class \code{rq.process} is returned. In this case parametric programming
methods are used to find all of the solutions to the QR problem for
tau in (0,1), the p-variate resulting process is then returned as the
array sol containing the primal solution and dsol containing the dual
solution. There are roughly \eqn{O(n \log n))}{O(n log n)} distinct
solutions, so users should
be aware that these arrays may be large and somewhat time consuming to
compute for large problems.
}
\references{
Koenker, R. and J.A.F. Machado, (1999) Goodness of fit and related inference
processes for quantile regression,
\emph{J. of Am Stat. Assoc.}, 94, 1296-1310.
}
\seealso{
\code{\link{rq}}, \code{\link{rq.fit.fnb}}
}
\examples{
data(stackloss)
rq.fit.br(stack.x, stack.loss, tau=.73 ,interp=FALSE)
}
\keyword{regression}