table of contents
| lagts(3) | Library Functions Manual | lagts(3) |
NAME¶
lagts - lagts: LU solve of (T - λI) x = y
SYNOPSIS¶
Functions¶
subroutine DLAGTS (job, n, a, b, c, d, in, y, tol, info)
DLAGTS solves the system of equations (T-λI)x = y or
(T-λI)^Tx = y, where T is a general tridiagonal matrix and λ a
scalar, using the LU factorization computed by slagtf. subroutine
SLAGTS (job, n, a, b, c, d, in, y, tol, info)
SLAGTS solves the system of equations (T-λI)x = y or
(T-λI)^Tx = y, where T is a general tridiagonal matrix and λ a
scalar, using the LU factorization computed by slagtf.
Detailed Description¶
Function Documentation¶
subroutine DLAGTS (integer job, integer n, double precision, dimension( * ) a, double precision, dimension( * ) b, double precision, dimension( * ) c, double precision, dimension( * ) d, integer, dimension( * ) in, double precision, dimension( * ) y, double precision tol, integer info)¶
DLAGTS solves the system of equations (T-λI)x = y or (T-λI)^Tx = y, where T is a general tridiagonal matrix and λ a scalar, using the LU factorization computed by slagtf.
Purpose:
!> !> DLAGTS may be used to solve one of the systems of equations !> !> (T - lambda*I)*x = y or (T - lambda*I)**T*x = y, !> !> where T is an n by n tridiagonal matrix, for x, following the !> factorization of (T - lambda*I) as !> !> (T - lambda*I) = P*L*U , !> !> by routine DLAGTF. The choice of equation to be solved is !> controlled by the argument JOB, and in each case there is an option !> to perturb zero or very small diagonal elements of U, this option !> being intended for use in applications such as inverse iteration. !>
Parameters
JOB
!> JOB is INTEGER !> Specifies the job to be performed by DLAGTS as follows: !> = 1: The equations (T - lambda*I)x = y are to be solved, !> but diagonal elements of U are not to be perturbed. !> = -1: The equations (T - lambda*I)x = y are to be solved !> and, if overflow would otherwise occur, the diagonal !> elements of U are to be perturbed. See argument TOL !> below. !> = 2: The equations (T - lambda*I)**Tx = y are to be solved, !> but diagonal elements of U are not to be perturbed. !> = -2: The equations (T - lambda*I)**Tx = y are to be solved !> and, if overflow would otherwise occur, the diagonal !> elements of U are to be perturbed. See argument TOL !> below. !>
N
!> N is INTEGER !> The order of the matrix T. !>
A
!> A is DOUBLE PRECISION array, dimension (N) !> On entry, A must contain the diagonal elements of U as !> returned from DLAGTF. !>
B
!> B is DOUBLE PRECISION array, dimension (N-1) !> On entry, B must contain the first super-diagonal elements of !> U as returned from DLAGTF. !>
C
!> C is DOUBLE PRECISION array, dimension (N-1) !> On entry, C must contain the sub-diagonal elements of L as !> returned from DLAGTF. !>
D
!> D is DOUBLE PRECISION array, dimension (N-2) !> On entry, D must contain the second super-diagonal elements !> of U as returned from DLAGTF. !>
IN
!> IN is INTEGER array, dimension (N) !> On entry, IN must contain details of the matrix P as returned !> from DLAGTF. !>
Y
!> Y is DOUBLE PRECISION array, dimension (N) !> On entry, the right hand side vector y. !> On exit, Y is overwritten by the solution vector x. !>
TOL
!> TOL is DOUBLE PRECISION !> On entry, with JOB < 0, TOL should be the minimum !> perturbation to be made to very small diagonal elements of U. !> TOL should normally be chosen as about eps*norm(U), where eps !> is the relative machine precision, but if TOL is supplied as !> non-positive, then it is reset to eps*max( abs( u(i,j) ) ). !> If JOB > 0 then TOL is not referenced. !> !> On exit, TOL is changed as described above, only if TOL is !> non-positive on entry. Otherwise TOL is unchanged. !>
INFO
!> INFO is INTEGER !> = 0: successful exit !> < 0: if INFO = -i, the i-th argument had an illegal value !> > 0: overflow would occur when computing the INFO(th) !> element of the solution vector x. This can only occur !> when JOB is supplied as positive and either means !> that a diagonal element of U is very small, or that !> the elements of the right-hand side vector y are very !> large. !>
Author
Univ. of Tennessee
Univ. of California Berkeley
Univ. of Colorado Denver
NAG Ltd.
Definition at line 162 of file dlagts.f.
subroutine SLAGTS (integer job, integer n, real, dimension( * ) a, real, dimension( * ) b, real, dimension( * ) c, real, dimension( * ) d, integer, dimension( * ) in, real, dimension( * ) y, real tol, integer info)¶
SLAGTS solves the system of equations (T-λI)x = y or (T-λI)^Tx = y, where T is a general tridiagonal matrix and λ a scalar, using the LU factorization computed by slagtf.
Purpose:
!> !> SLAGTS may be used to solve one of the systems of equations !> !> (T - lambda*I)*x = y or (T - lambda*I)**T*x = y, !> !> where T is an n by n tridiagonal matrix, for x, following the !> factorization of (T - lambda*I) as !> !> (T - lambda*I) = P*L*U , !> !> by routine SLAGTF. The choice of equation to be solved is !> controlled by the argument JOB, and in each case there is an option !> to perturb zero or very small diagonal elements of U, this option !> being intended for use in applications such as inverse iteration. !>
Parameters
JOB
!> JOB is INTEGER !> Specifies the job to be performed by SLAGTS as follows: !> = 1: The equations (T - lambda*I)x = y are to be solved, !> but diagonal elements of U are not to be perturbed. !> = -1: The equations (T - lambda*I)x = y are to be solved !> and, if overflow would otherwise occur, the diagonal !> elements of U are to be perturbed. See argument TOL !> below. !> = 2: The equations (T - lambda*I)**Tx = y are to be solved, !> but diagonal elements of U are not to be perturbed. !> = -2: The equations (T - lambda*I)**Tx = y are to be solved !> and, if overflow would otherwise occur, the diagonal !> elements of U are to be perturbed. See argument TOL !> below. !>
N
!> N is INTEGER !> The order of the matrix T. !>
A
!> A is REAL array, dimension (N) !> On entry, A must contain the diagonal elements of U as !> returned from SLAGTF. !>
B
!> B is REAL array, dimension (N-1) !> On entry, B must contain the first super-diagonal elements of !> U as returned from SLAGTF. !>
C
!> C is REAL array, dimension (N-1) !> On entry, C must contain the sub-diagonal elements of L as !> returned from SLAGTF. !>
D
!> D is REAL array, dimension (N-2) !> On entry, D must contain the second super-diagonal elements !> of U as returned from SLAGTF. !>
IN
!> IN is INTEGER array, dimension (N) !> On entry, IN must contain details of the matrix P as returned !> from SLAGTF. !>
Y
!> Y is REAL array, dimension (N) !> On entry, the right hand side vector y. !> On exit, Y is overwritten by the solution vector x. !>
TOL
!> TOL is REAL !> On entry, with JOB < 0, TOL should be the minimum !> perturbation to be made to very small diagonal elements of U. !> TOL should normally be chosen as about eps*norm(U), where eps !> is the relative machine precision, but if TOL is supplied as !> non-positive, then it is reset to eps*max( abs( u(i,j) ) ). !> If JOB > 0 then TOL is not referenced. !> !> On exit, TOL is changed as described above, only if TOL is !> non-positive on entry. Otherwise TOL is unchanged. !>
INFO
!> INFO is INTEGER !> = 0: successful exit !> < 0: if INFO = -i, the i-th argument had an illegal value !> > 0: overflow would occur when computing the INFO(th) !> element of the solution vector x. This can only occur !> when JOB is supplied as positive and either means !> that a diagonal element of U is very small, or that !> the elements of the right-hand side vector y are very !> large. !>
Author
Univ. of Tennessee
Univ. of California Berkeley
Univ. of Colorado Denver
NAG Ltd.
Definition at line 162 of file slagts.f.
Author¶
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