src/library/base/man/qraux.Rd - R - Git at Google

 % File src/library/base/man/qraux.Rd
 % Part of the R package, https://www.R-project.org
 % Copyright 1995-2015 R Core Team
 % Copyright 2002-2015 The R Foundation
 % Distributed under GPL 2 or later

 \name{QR.Auxiliaries}
 \title{Reconstruct the Q, R, or X Matrices from a QR Object}
 \usage{
 qr.X(qr, complete = FALSE, ncol =)
 qr.Q(qr, complete = FALSE, Dvec =)
 qr.R(qr, complete = FALSE)
 }
 \alias{qr.X}
 \alias{qr.Q}
 \alias{qr.R}
 \arguments{
   \item{qr}{object representing a QR decomposition.  This will
     typically have come from a previous call to \code{\link{qr}} or
     \code{\link{lsfit}}.}
   \item{complete}{logical expression of length 1.  Indicates whether an
     arbitrary  orthogonal completion of the \eqn{\bold{Q}} or
     \eqn{\bold{X}} matrices is to be made, or whether the \eqn{\bold{R}}
     matrix is to be completed  by binding zero-value rows beneath the
     square upper triangle.}
   \item{ncol}{integer in the range \code{1:nrow(qr$qr)}.  The number
     of columns to be in the reconstructed \eqn{\bold{X}}.  The default
     when \code{complete} is \code{FALSE} is the first
     \code{min(ncol(X), nrow(X))} columns of the original \eqn{\bold{X}}
     from which the qr object was constructed.  The default when
     \code{complete} is \code{TRUE} is a square matrix with the original
     \eqn{\bold{X}} in the first \code{ncol(X)} columns and an arbitrary
     orthogonal completion (unitary completion in the complex case) in
     the remaining columns.}
   \item{Dvec}{vector (not matrix) of diagonal values.  Each column of
     the returned \eqn{\bold{Q}} will be multiplied by the corresponding
     diagonal value.  Defaults to all \code{1}s.}
 }
 \description{
   Returns the original matrix from which the object was constructed or
   the components of the decomposition.
 }
 \value{
   \code{qr.X} returns \eqn{\bold{X}}, the original matrix from
   which the qr object was constructed, provided \code{ncol(X) <= nrow(X)}.
   If \code{complete} is \code{TRUE} or the argument \code{ncol} is greater than
   \code{ncol(X)}, additional columns from an arbitrary orthogonal
   (unitary) completion of \code{X} are returned.

   \code{qr.Q} returns part or all of \bold{Q}, the order-nrow(X)
   orthogonal (unitary) transformation represented by \code{qr}.  If
   \code{complete} is \code{TRUE}, \bold{Q} has \code{nrow(X)} columns.
   If \code{complete} is \code{FALSE}, \bold{Q} has \code{ncol(X)}
   columns.  When \code{Dvec} is specified, each column of \bold{Q} is
   multiplied by the corresponding value in \code{Dvec}.

   Note that \code{qr.Q(qr, *)} is a special case of
   \code{\link{qr.qy}(qr, y)} (with a \dQuote{diagonal} \code{y}), and
   \code{qr.X(qr, *)} is basically \code{\link{qr.qy}(qr, R)} (apart from
   pivoting and \code{dimnames} setting).

  \code{qr.R} returns \bold{R}.  This may be pivoted, e.g., if
  \code{a <- qr(x)} then \code{x[, a$pivot]} = \bold{QR}.  The number of
  rows of \bold{R} is either \code{nrow(X)} or \code{ncol(X)} (and may
  depend on whether \code{complete} is \code{TRUE} or \code{FALSE}).
 }
 \seealso{
   \code{\link{qr}},
   \code{\link{qr.qy}}.
 }
 \examples{
 p <- ncol(x <- LifeCycleSavings[, -1]) # not the 'sr'
 qrstr <- qr(x)   # dim(x) == c(n,p)
 qrstr $ rank # = 4 = p
 Q <- qr.Q(qrstr) # dim(Q) == dim(x)
 R <- qr.R(qrstr) # dim(R) == ncol(x)
 X <- qr.X(qrstr) # X == x
 range(X - as.matrix(x))  # ~ < 6e-12
 ## X == Q \%*\% R if there has been no pivoting, as here:
 all.equal(unname(X),
           unname(Q \%*\% R))

 # example of pivoting
 x <- cbind(int = 1,
            b1 = rep(1:0, each = 3), b2 = rep(0:1, each = 3),
            c1 = rep(c(1,0,0), 2), c2 = rep(c(0,1,0), 2), c3 = rep(c(0,0,1),2))
 x # is singular, columns "b2" and "c3" are "extra"
 a <- qr(x)
 zapsmall(qr.R(a)) # columns are int b1 c1 c2 b2 c3
 a$pivot
 pivI <- sort.list(a$pivot) # the inverse permutation
 all.equal (x,            qr.Q(a) \%*\% qr.R(a)) # no, no
 stopifnot(
  all.equal(x[, a$pivot], qr.Q(a) \%*\% qr.R(a)),          # TRUE
  all.equal(x           , qr.Q(a) \%*\% qr.R(a)[, pivI]))  # TRUE too!
 }
 \keyword{algebra}
 \keyword{array}
	% File src/library/base/man/qraux.Rd
	% Part of the R package, https://www.R-project.org
	% Copyright 1995-2015 R Core Team
	% Copyright 2002-2015 The R Foundation
	% Distributed under GPL 2 or later

	\name{QR.Auxiliaries}
	\title{Reconstruct the Q, R, or X Matrices from a QR Object}
	\usage{
	qr.X(qr, complete = FALSE, ncol =)
	qr.Q(qr, complete = FALSE, Dvec =)
	qr.R(qr, complete = FALSE)
	}
	\alias{qr.X}
	\alias{qr.Q}
	\alias{qr.R}
	\arguments{
	\item{qr}{object representing a QR decomposition. This will
	typically have come from a previous call to \code{\link{qr}} or
	\code{\link{lsfit}}.}
	\item{complete}{logical expression of length 1. Indicates whether an
	arbitrary orthogonal completion of the \eqn{\bold{Q}} or
	\eqn{\bold{X}} matrices is to be made, or whether the \eqn{\bold{R}}
	matrix is to be completed by binding zero-value rows beneath the
	square upper triangle.}
	\item{ncol}{integer in the range \code{1:nrow(qr$qr)}. The number
	of columns to be in the reconstructed \eqn{\bold{X}}. The default
	when \code{complete} is \code{FALSE} is the first
	\code{min(ncol(X), nrow(X))} columns of the original \eqn{\bold{X}}
	from which the qr object was constructed. The default when
	\code{complete} is \code{TRUE} is a square matrix with the original
	\eqn{\bold{X}} in the first \code{ncol(X)} columns and an arbitrary
	orthogonal completion (unitary completion in the complex case) in
	the remaining columns.}
	\item{Dvec}{vector (not matrix) of diagonal values. Each column of
	the returned \eqn{\bold{Q}} will be multiplied by the corresponding
	diagonal value. Defaults to all \code{1}s.}
	}
	\description{
	Returns the original matrix from which the object was constructed or
	the components of the decomposition.
	}
	\value{
	\code{qr.X} returns \eqn{\bold{X}}, the original matrix from
	which the qr object was constructed, provided \code{ncol(X) <= nrow(X)}.
	If \code{complete} is \code{TRUE} or the argument \code{ncol} is greater than
	\code{ncol(X)}, additional columns from an arbitrary orthogonal
	(unitary) completion of \code{X} are returned.

	\code{qr.Q} returns part or all of \bold{Q}, the order-nrow(X)
	orthogonal (unitary) transformation represented by \code{qr}. If
	\code{complete} is \code{TRUE}, \bold{Q} has \code{nrow(X)} columns.
	If \code{complete} is \code{FALSE}, \bold{Q} has \code{ncol(X)}
	columns. When \code{Dvec} is specified, each column of \bold{Q} is
	multiplied by the corresponding value in \code{Dvec}.

	Note that \code{qr.Q(qr, *)} is a special case of
	\code{\link{qr.qy}(qr, y)} (with a \dQuote{diagonal} \code{y}), and
	\code{qr.X(qr, *)} is basically \code{\link{qr.qy}(qr, R)} (apart from
	pivoting and \code{dimnames} setting).

	\code{qr.R} returns \bold{R}. This may be pivoted, e.g., if
	\code{a <- qr(x)} then \code{x[, a$pivot]} = \bold{QR}. The number of
	rows of \bold{R} is either \code{nrow(X)} or \code{ncol(X)} (and may
	depend on whether \code{complete} is \code{TRUE} or \code{FALSE}).
	}
	\seealso{
	\code{\link{qr}},
	\code{\link{qr.qy}}.
	}
	\examples{
	p <- ncol(x <- LifeCycleSavings[, -1]) # not the 'sr'
	qrstr <- qr(x) # dim(x) == c(n,p)
	qrstr $ rank # = 4 = p
	Q <- qr.Q(qrstr) # dim(Q) == dim(x)
	R <- qr.R(qrstr) # dim(R) == ncol(x)
	X <- qr.X(qrstr) # X == x
	range(X - as.matrix(x)) # ~ < 6e-12
	## X == Q \%*\% R if there has been no pivoting, as here:
	all.equal(unname(X),
	unname(Q \%*\% R))

	# example of pivoting
	x <- cbind(int = 1,
	b1 = rep(1:0, each = 3), b2 = rep(0:1, each = 3),
	c1 = rep(c(1,0,0), 2), c2 = rep(c(0,1,0), 2), c3 = rep(c(0,0,1),2))
	x # is singular, columns "b2" and "c3" are "extra"
	a <- qr(x)
	zapsmall(qr.R(a)) # columns are int b1 c1 c2 b2 c3
	a$pivot
	pivI <- sort.list(a$pivot) # the inverse permutation
	all.equal (x, qr.Q(a) \%*\% qr.R(a)) # no, no
	stopifnot(
	all.equal(x[, a$pivot], qr.Q(a) \%*\% qr.R(a)), # TRUE
	all.equal(x , qr.Q(a) \%*\% qr.R(a)[, pivI])) # TRUE too!
	}
	\keyword{algebra}
	\keyword{array}