denseBunchKaufman-class: Dense Bunch-Kaufman Factorizations
In Matrix: Sparse and Dense Matrix Classes and Methods
denseBunchKaufman-class R Documentation
Dense Bunch-Kaufman Factorizations
Description
Classes BunchKaufman and pBunchKaufman represent
Bunch-Kaufman factorizations of n \times n real,
symmetric matrices A, having the general form
A = U D_{U} U' = L D_{L} L'
where
D_{U} and D_{L} are symmetric, block diagonal
matrices composed of b_{U} and b_{L}
1 \times 1 or 2 \times 2 diagonal blocks;
U = \prod_{k = 1}^{b_{U}} P_{k} U_{k}
is the product of b_{U} row-permuted unit upper triangular
matrices, each having nonzero entries above the diagonal in 1 or 2 columns;
and
L = \prod_{k = 1}^{b_{L}} P_{k} L_{k}
is the product of b_{L} row-permuted unit lower triangular
matrices, each having nonzero entries below the diagonal in 1 or 2 columns.
These classes store the nonzero entries of the
2 b_{U} + 1 or 2 b_{L} + 1 factors,
which are individually sparse,
in a dense format as a vector of length
nn (BunchKaufman) or
n(n+1)/2 (pBunchKaufman),
the latter giving the “packed” representation.
Slots
Dim, Dimnamesinherited from virtual class
MatrixFactorization.
uploa string, either "U" or "L",
indicating which triangle (upper or lower) of the factorized
symmetric matrix was used to compute the factorization and
in turn how the x slot is partitioned.
xa numeric vector of length n*n
(BunchKaufman) or n*(n+1)/2 (pBunchKaufman),
where n=Dim[1].
The details of the representation are specified by the manual
for LAPACK routines dsytrf and dsptrf.
perman integer vector of length n=Dim[1]
specifying row and column interchanges as described in the manual
for LAPACK routines dsytrf and dsptrf.
Extends
Class BunchKaufmanFactorization, directly.
Class MatrixFactorization, by class
BunchKaufmanFactorization, distance 2.
Instantiation
Objects can be generated directly by calls of the form
new("BunchKaufman", ...) or new("pBunchKaufman", ...),
but they are more typically obtained as the value of
BunchKaufman(x) for x inheriting from
dsyMatrix or dspMatrix.
Methods
coercesignature(from = "BunchKaufman", to = "dtrMatrix"):
returns a dtrMatrix, useful for inspecting
the internal representation of the factorization; see ‘Note’.
coercesignature(from = "pBunchKaufman", to = "dtpMatrix"):
returns a dtpMatrix, useful for inspecting
the internal representation of the factorization; see ‘Note’.
determinantsignature(x = "p?BunchKaufman", logarithm = "logical"):
computes the determinant of the factorized matrix A
or its logarithm.
expand1signature(x = "p?BunchKaufman"):
see expand1-methods.
expand2signature(x = "p?BunchKaufman"):
see expand2-methods.
solvesignature(a = "p?BunchKaufman", b = .):
see solve-methods.
Note
In Matrix < 1.6-0, class BunchKaufman extended
dtrMatrix and class pBunchKaufman extended
dtpMatrix, reflecting the fact that the internal
representation of the factorization is fundamentally triangular:
there are n(n+1)/2 “parameters”, and these
can be arranged systematically to form an n \times n
triangular matrix.
Matrix 1.6-0 removed these extensions so that methods
would no longer be inherited from dtrMatrix and dtpMatrix.
The availability of such methods gave the wrong impression that
BunchKaufman and pBunchKaufman represent a (singular)
matrix, when in fact they represent an ordered set of matrix factors.
The coercions as(., "dtrMatrix") and as(., "dtpMatrix")
are provided for users who understand the caveats.
References
The LAPACK source code, including documentation; see
https://netlib.org/lapack/double/dsytrf.f and
https://netlib.org/lapack/double/dsptrf.f.
Golub, G. H., & Van Loan, C. F. (2013).
Matrix computations (4th ed.).
Johns Hopkins University Press.
\Sexpr[results=rd]{tools:::Rd_expr_doi("10.56021/9781421407944")}
See Also
Class dsyMatrix and its packed counterpart.
Generic functions BunchKaufman,
expand1, and expand2.
Examples
showClass("denseBunchKaufman")
set.seed(1)
n <- 6L
(A <- forceSymmetric(Matrix(rnorm(n * n), n, n)))
## With dimnames, to see that they are propagated :
dimnames(A) <- rep.int(list(paste0("x", seq_len(n))), 2L)
(bk.A <- BunchKaufman(A))
str(e.bk.A <- expand2(bk.A, complete = FALSE), max.level = 2L)
str(E.bk.A <- expand2(bk.A, complete = TRUE), max.level = 2L)
## Underlying LAPACK representation
(m.bk.A <- as(bk.A, "dtrMatrix"))
stopifnot(identical(as(m.bk.A, "matrix"), `dim<-`(bk.A@x, bk.A@Dim)))
## Number of factors is 2*b+1, b <= n, which can be nontrivial ...
(b <- (length(E.bk.A) - 1L) %/% 2L)
ae1 <- function(a, b, ...) all.equal(as(a, "matrix"), as(b, "matrix"), ...)
ae2 <- function(a, b, ...) ae1(unname(a), unname(b), ...)
## A ~ U DU U', U := prod(Pk Uk) in floating point
stopifnot(exprs = {
identical(names(e.bk.A), c("U", "DU", "U."))
identical(e.bk.A[["U" ]], Reduce(`%*%`, E.bk.A[seq_len(b)]))
identical(e.bk.A[["U."]], t(e.bk.A[["U"]]))
ae1(A, with(e.bk.A, U %*% DU %*% U.))
})
## Factorization handled as factorized matrix
b <- rnorm(n)
stopifnot(identical(det(A), det(bk.A)),
identical(solve(A, b), solve(bk.A, b)))
Matrix documentation built on Aug. 13, 2024, 3:01 p.m.
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| denseBunchKaufman-class | R Documentation |
Dense Bunch-Kaufman Factorizations
Description
Classes BunchKaufman and pBunchKaufman represent
Bunch-Kaufman factorizations of n \times n real,
symmetric matrices A, having the general form
A = U D_{U} U' = L D_{L} L'
where
D_{U} and D_{L} are symmetric, block diagonal
matrices composed of b_{U} and b_{L}
1 \times 1 or 2 \times 2 diagonal blocks;
U = \prod_{k = 1}^{b_{U}} P_{k} U_{k}
is the product of b_{U} row-permuted unit upper triangular
matrices, each having nonzero entries above the diagonal in 1 or 2 columns;
and
L = \prod_{k = 1}^{b_{L}} P_{k} L_{k}
is the product of b_{L} row-permuted unit lower triangular
matrices, each having nonzero entries below the diagonal in 1 or 2 columns.
These classes store the nonzero entries of the
2 b_{U} + 1 or 2 b_{L} + 1 factors,
which are individually sparse,
in a dense format as a vector of length
nn (BunchKaufman) or
n(n+1)/2 (pBunchKaufman),
the latter giving the “packed” representation.
Slots
Dim,Dimnamesinherited from virtual class
MatrixFactorization.uploa string, either
"U"or"L", indicating which triangle (upper or lower) of the factorized symmetric matrix was used to compute the factorization and in turn how thexslot is partitioned.xa numeric vector of length
n*n(BunchKaufman) orn*(n+1)/2(pBunchKaufman), wheren=Dim[1]. The details of the representation are specified by the manual for LAPACK routinesdsytrfanddsptrf.perman integer vector of length
n=Dim[1]specifying row and column interchanges as described in the manual for LAPACK routinesdsytrfanddsptrf.
Extends
Class BunchKaufmanFactorization, directly.
Class MatrixFactorization, by class
BunchKaufmanFactorization, distance 2.
Instantiation
Objects can be generated directly by calls of the form
new("BunchKaufman", ...) or new("pBunchKaufman", ...),
but they are more typically obtained as the value of
BunchKaufman(x) for x inheriting from
dsyMatrix or dspMatrix.
Methods
coercesignature(from = "BunchKaufman", to = "dtrMatrix"): returns adtrMatrix, useful for inspecting the internal representation of the factorization; see ‘Note’.coercesignature(from = "pBunchKaufman", to = "dtpMatrix"): returns adtpMatrix, useful for inspecting the internal representation of the factorization; see ‘Note’.determinantsignature(x = "p?BunchKaufman", logarithm = "logical"): computes the determinant of the factorized matrixAor its logarithm.expand1signature(x = "p?BunchKaufman"): seeexpand1-methods.expand2signature(x = "p?BunchKaufman"): seeexpand2-methods.solvesignature(a = "p?BunchKaufman", b = .): seesolve-methods.
Note
In Matrix < 1.6-0, class BunchKaufman extended
dtrMatrix and class pBunchKaufman extended
dtpMatrix, reflecting the fact that the internal
representation of the factorization is fundamentally triangular:
there are n(n+1)/2 “parameters”, and these
can be arranged systematically to form an n \times n
triangular matrix.
Matrix 1.6-0 removed these extensions so that methods
would no longer be inherited from dtrMatrix and dtpMatrix.
The availability of such methods gave the wrong impression that
BunchKaufman and pBunchKaufman represent a (singular)
matrix, when in fact they represent an ordered set of matrix factors.
The coercions as(., "dtrMatrix") and as(., "dtpMatrix")
are provided for users who understand the caveats.
References
The LAPACK source code, including documentation; see https://netlib.org/lapack/double/dsytrf.f and https://netlib.org/lapack/double/dsptrf.f.
Golub, G. H., & Van Loan, C. F. (2013). Matrix computations (4th ed.). Johns Hopkins University Press. \Sexpr[results=rd]{tools:::Rd_expr_doi("10.56021/9781421407944")}
See Also
Class dsyMatrix and its packed counterpart.
Generic functions BunchKaufman,
expand1, and expand2.
Examples
showClass("denseBunchKaufman")
set.seed(1)
n <- 6L
(A <- forceSymmetric(Matrix(rnorm(n * n), n, n)))
## With dimnames, to see that they are propagated :
dimnames(A) <- rep.int(list(paste0("x", seq_len(n))), 2L)
(bk.A <- BunchKaufman(A))
str(e.bk.A <- expand2(bk.A, complete = FALSE), max.level = 2L)
str(E.bk.A <- expand2(bk.A, complete = TRUE), max.level = 2L)
## Underlying LAPACK representation
(m.bk.A <- as(bk.A, "dtrMatrix"))
stopifnot(identical(as(m.bk.A, "matrix"), `dim<-`(bk.A@x, bk.A@Dim)))
## Number of factors is 2*b+1, b <= n, which can be nontrivial ...
(b <- (length(E.bk.A) - 1L) %/% 2L)
ae1 <- function(a, b, ...) all.equal(as(a, "matrix"), as(b, "matrix"), ...)
ae2 <- function(a, b, ...) ae1(unname(a), unname(b), ...)
## A ~ U DU U', U := prod(Pk Uk) in floating point
stopifnot(exprs = {
identical(names(e.bk.A), c("U", "DU", "U."))
identical(e.bk.A[["U" ]], Reduce(`%*%`, E.bk.A[seq_len(b)]))
identical(e.bk.A[["U."]], t(e.bk.A[["U"]]))
ae1(A, with(e.bk.A, U %*% DU %*% U.))
})
## Factorization handled as factorized matrix
b <- rnorm(n)
stopifnot(identical(det(A), det(bk.A)),
identical(solve(A, b), solve(bk.A, b)))
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