Matrix (version 1.6-5)

solve-methods: Methods in Package Matrix for Function solve

Description

Methods for generic function solve for solving linear systems of equations, i.e., for \(X\) in \(A X = B\), where \(A\) is a square matrix and \(X\) and \(B\) are matrices with dimensions consistent with \(A\).

Usage

solve(a, b, ...)

# S4 method for dgeMatrix,ANY solve(a, b, tol = .Machine$double.eps, ...)

# S4 method for dgCMatrix,missing solve(a, b, sparse = TRUE, ...) # S4 method for dgCMatrix,matrix solve(a, b, sparse = FALSE, ...) # S4 method for dgCMatrix,denseMatrix solve(a, b, sparse = FALSE, ...) # S4 method for dgCMatrix,sparseMatrix solve(a, b, sparse = TRUE, ...)

# S4 method for denseLU,dgeMatrix solve(a, b, ...) # S4 method for BunchKaufman,dgeMatrix solve(a, b, ...) # S4 method for Cholesky,dgeMatrix solve(a, b, ...) # S4 method for sparseLU,dgCMatrix solve(a, b, tol = .Machine$double.eps, ...) # S4 method for sparseQR,dgCMatrix solve(a, b, ...) # S4 method for CHMfactor,dgCMatrix solve(a, b, system = c("A", "LDLt", "LD", "DLt", "L", "Lt", "D", "P", "Pt"), ...)

Arguments

a

a finite square matrix or Matrix containing the coefficients of the linear system, or otherwise a MatrixFactorization, in which case methods behave (by default) as if the factorized matrix were specified.

b

a vector, sparseVector, matrix, or Matrix satisfying NROW(b) == nrow(a), giving the right-hand side(s) of the linear system. Vectors b are treated as length(b)-by-1 matrices. If b is missing, then methods take b to be an identity matrix.

tol

a non-negative number. For a inheriting from denseMatrix, an error is signaled if the reciprocal one-norm condition number (see rcond) of a is less than tol, indicating that a is near-singular. For a of class sparseLU, an error is signaled if the ratio min(d)/max(d) is less than tol, where d = abs(diag(a@U)). (Interpret with care, as this ratio is a cheap heuristic and not in general equal to or even proportional to the reciprocal one-norm condition number.) Setting tol = 0 disables the test.

sparse

a logical indicating if the result should be formally sparse, i.e., if the result should inherit from virtual class sparseMatrix. Only methods for sparse a and missing or matrix b have this argument. Methods for missing or sparse b use sparse = TRUE by default. Methods for dense b use sparse = FALSE by default.

system

a string specifying a linear system to be solved. Only methods for a inheriting from CHMfactor have this argument. See ‘Details’.

...

further arguments passed to or from methods.

Details

Methods for general and symmetric matrices a compute a triangular factorization (LU, Bunch-Kaufman, or Cholesky) and call the method for the corresponding factorization class. The factorization is sparse if a is. Methods for sparse, symmetric matrices a attempt a Cholesky factorization and perform an LU factorization only if that fails (typically because a is not positive definite).

Triangular, diagonal, and permutation matrices do not require factorization (they are already “factors”), hence methods for those are implemented directly. For triangular a, solutions are obtained by forward or backward substitution; for diagonal a, they are obtained by scaling the rows of b; and for permutations a, they are obtained by permuting the rows of b.

Methods for dense a are built on 14 LAPACK routines: class d..Matrix, where ..=(ge|tr|tp|sy|sp|po|pp), uses routines d..tri and d..trs for missing and non-missing b, respectively. A corollary is that these methods always give a dense result.

Methods for sparse a are built on CSparse routines cs_lsolve, cs_usolve, and cs_spsolve and CHOLMOD routines cholmod_solve and cholmod_spsolve. By default, these methods give a vector result if b is a vector, a sparse matrix result if b is missing or a sparse matrix, and a dense matrix result if b is a dense matrix. One can override this behaviour by setting the sparse argument, where available, but that should be done with care. Note that a sparse result may be sparse only in the formal sense and not at all in the mathematical sense, depending on the nonzero patterns of a and b. Furthermore, whereas dense results are fully preallocated, sparse results must be “grown” in a loop over the columns of b.

Methods for a of class sparseQR are simple wrappers around qr.coef, giving the least squares solution in overdetermined cases.

Methods for a inheriting from CHMfactor can solve systems other than the default one \(A X = B\). The correspondence between its system argument the system actually solved is outlined in the table below. See CHMfactor-class for a definition of notation.

systemisLDL(a)=TRUEisLDL(a)=FALSE
"A"\(A X = B\)\(A X = B\)
"LDLt"\(L_{1} D L_{1}' X = B\)\(L L' X = B\)
"LD"\(L_{1} D X = B\)\(L X = B\)
"DLt"\(D L_{1}' X = B\)\(L' X = B\)
"L"\(L_{1} X = B\)\(L X = B\)
"Lt"\(L_{1}' X = B\)\(L' X = B\)
"D"\(D X = B\)\(X = B\)
"P"\(X = P_{1} B\)\(X = P_{1} B\)
"Pt"\(X = P_{1}' B\)\(X = P_{1}' B\)

See Also

Virtual class MatrixFactorization and its subclasses.

Generic functions Cholesky, BunchKaufman, Schur, lu, and qr for computing factorizations.

Generic function solve from base.

Function qr.coef from base for computing least squares solutions of overdetermined linear systems.

Examples

Run this code
## A close to symmetric example with "quite sparse" inverse:
n1 <- 7; n2 <- 3
dd <- data.frame(a = gl(n1,n2), b = gl(n2,1,n1*n2))# balanced 2-way
X <- sparse.model.matrix(~ -1+ a + b, dd)# no intercept --> even sparser
XXt <- tcrossprod(X)
diag(XXt) <- rep(c(0,0,1,0), length.out = nrow(XXt))

n <- nrow(ZZ <- kronecker(XXt, Diagonal(x=c(4,1))))
image(a <- 2*Diagonal(n) + ZZ %*% Diagonal(x=c(10, rep(1, n-1))))
isSymmetric(a) # FALSE
image(drop0(skewpart(a)))
image(ia0 <- solve(a, tol = 0)) # checker board, dense [but really, a is singular!]
try(solve(a, sparse=TRUE))##-> error [ TODO: assertError ]
ia. <- solve(a, sparse=TRUE, tol = 1e-19)##-> *no* error
if(R.version$arch == "x86_64")
  ## Fails on 32-bit [Fedora 19, R 3.0.2] from Matrix 1.1-0 on [FIXME ??] only
  stopifnot(all.equal(as.matrix(ia.), as.matrix(ia0)))
a <- a + Diagonal(n)
iad <- solve(a)
ias <- solve(a, sparse=FALSE)
stopifnot(all.equal(as(iad,"denseMatrix"), ias, tolerance=1e-14))
I. <- iad %*% a          ; image(I.)
I0 <- drop0(zapsmall(I.)); image(I0)
.I <- a %*% iad
.I0 <- drop0(zapsmall(.I))
stopifnot( all.equal(as(I0, "diagonalMatrix"), Diagonal(n)),
           all.equal(as(.I0,"diagonalMatrix"), Diagonal(n)) )

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