| qr {base} | R Documentation |
The QR Decomposition of a Matrix
Description
qr computes the QR decomposition of a matrix. It provides an
interface to the techniques used in the LINPACK routine DQRDC.
Usage
qr(x, tol=1e-07)
qr.coef(qr, y)
qr.qy(qr, y)
qr.qty(qr, y)
qr.resid(qr, y)
qr.fitted(qr, y, k = qr$rank)
qr.solve(a, b, tol = 1e-7)
is.qr(x)
as.qr(x)
Arguments
x |
a matrix whose QR decomposition is to be computed. |
tol |
the tolerance for detecting linear dependencies in the
columns of |
qr |
a QR decomposition of the type computed by |
y, b |
a vector or matrix of right-hand sides of equations. |
a |
A matrix or QR decomposition. |
Details
The QR decomposition plays an important role in many
statistical techniques. In particular it can be used to solve the
equation \bold{Ax} = \bold{b} for given matrix \bold{A},
and vector \bold{b}. It is useful for computing regression
coefficients and in applying the Newton-Raphson algorithm.
The functions qr.coef, qr.resid, and qr.fitted
return the coefficients, residuals and fitted values obtained when
fitting y to the matrix with QR decomposition qr.
qr.qy and qr.qty return Q %*% y and
t(Q) %*% y, where Q is the \bold{Q} matrix.
qr.solve solves systems of equations via the QR decomposition.
is.qr returns TRUE if x is a list
with components named qr, rank and qraux and
FALSE otherwise.
It is not possible to coerce objects to mode "qr". Objects
either are QR decompositions or they are not.
Value
The QR decomposition of the matrix as computed by LINPACK. The components in the returned value correspond directly to the values returned by DQRDC.
qr |
a matrix with the same dimensions as |
qraux |
a vector of length |
rank |
the rank of |
pivot |
information on the pivoting strategy used during the decomposition. |
Note
To compute the determinant of a matrix (do you really need it?),
the QR decomposition is much more efficient than using Eigen values
(eigen). See det2 in the examples below.
References
Dongarra, J. J., Bunch, J. R., Moler, C. B. and Stewart, G. W. (1978) LINPACK Users Guide. Philadelphia: SIAM Publications.
See Also
qr.Q, qr.R, qr.X for
reconstruction of the matrices.
solve.qr, lsfit,
eigen, svd.
det (using qr) to compute the determinant of a matrix.
Examples
hilbert <- function(n) { i <- 1:n; 1 / outer(i - 1, i, "+") }
h9 <- hilbert(9); h9
qr(h9)$rank #--> only 7
qrh9 <- qr(h9, tol = 1e-10)
qrh9$rank #--> 9
##-- Solve linear equation system H %*% x = y :
y <- 1:9/10
x <- qr.solve(h9, y, tol = 1e-10) # or equivalently :
x <- qr.coef(qrh9, y) #-- is == but much better than
#-- solve(h9) %*% y
h9 %*% x # = y