Contents
dtrsen - reorder the real Schur factorization of a real
matrix A = Q*T*Q**T, so that a selected cluster of eigen-
values appears in the leading diagonal blocks of the upper
quasi-triangular matrix T,
SUBROUTINE DTRSEN(JOB, COMPQ, SELECT, N, T, LDT, Q, LDQ, WR, WI, M,
S, SEP, WORK, LWORK, IWORK, LIWORK, INFO)
CHARACTER * 1 JOB, COMPQ
INTEGER N, LDT, LDQ, M, LWORK, LIWORK, INFO
INTEGER IWORK(*)
LOGICAL SELECT(*)
DOUBLE PRECISION S, SEP
DOUBLE PRECISION T(LDT,*), Q(LDQ,*), WR(*), WI(*), WORK(*)
SUBROUTINE DTRSEN_64(JOB, COMPQ, SELECT, N, T, LDT, Q, LDQ, WR, WI,
M, S, SEP, WORK, LWORK, IWORK, LIWORK, INFO)
CHARACTER * 1 JOB, COMPQ
INTEGER*8 N, LDT, LDQ, M, LWORK, LIWORK, INFO
INTEGER*8 IWORK(*)
LOGICAL*8 SELECT(*)
DOUBLE PRECISION S, SEP
DOUBLE PRECISION T(LDT,*), Q(LDQ,*), WR(*), WI(*), WORK(*)
F95 INTERFACE
SUBROUTINE TRSEN(JOB, COMPQ, SELECT, N, T, [LDT], Q, [LDQ], WR, WI,
M, S, SEP, [WORK], [LWORK], [IWORK], [LIWORK], [INFO])
CHARACTER(LEN=1) :: JOB, COMPQ
INTEGER :: N, LDT, LDQ, M, LWORK, LIWORK, INFO
INTEGER, DIMENSION(:) :: IWORK
LOGICAL, DIMENSION(:) :: SELECT
REAL(8) :: S, SEP
REAL(8), DIMENSION(:) :: WR, WI, WORK
REAL(8), DIMENSION(:,:) :: T, Q
SUBROUTINE TRSEN_64(JOB, COMPQ, SELECT, N, T, [LDT], Q, [LDQ], WR,
WI, M, S, SEP, [WORK], [LWORK], [IWORK], [LIWORK], [INFO])
CHARACTER(LEN=1) :: JOB, COMPQ
INTEGER(8) :: N, LDT, LDQ, M, LWORK, LIWORK, INFO
INTEGER(8), DIMENSION(:) :: IWORK
LOGICAL(8), DIMENSION(:) :: SELECT
REAL(8) :: S, SEP
REAL(8), DIMENSION(:) :: WR, WI, WORK
REAL(8), DIMENSION(:,:) :: T, Q
C INTERFACE
#include <sunperf.h>
void dtrsen(char job, char compq, int *select, int n, double
*t, int ldt, double *q, int ldq, double *wr, dou-
ble *wi, int *m, double *s, double *sep, int
*info);
void dtrsen_64(char job, char compq, long *select, long n,
double *t, long ldt, double *q, long ldq, double
*wr, double *wi, long *m, double *s, double *sep,
long *info);
dtrsen reorders the real Schur factorization of a real
matrix A = Q*T*Q**T, so that a selected cluster of eigen-
values appears in the leading diagonal blocks of the upper
quasi-triangular matrix T, and the leading columns of Q form
an orthonormal basis of the corresponding right invariant
subspace.
Optionally the routine computes the reciprocal condition
numbers of the cluster of eigenvalues and/or the invariant
subspace.
T must be in Schur canonical form (as returned by SHSEQR),
that is, block upper triangular with 1-by-1 and 2-by-2 diag-
onal blocks; each 2-by-2 diagonal block has its diagonal
elemnts equal and its off-diagonal elements of opposite
sign.
JOB (input)
Specifies whether condition numbers are required
for the cluster of eigenvalues (S) or the invari-
ant subspace (SEP):
= 'N': none;
= 'E': for eigenvalues only (S);
= 'V': for invariant subspace only (SEP);
= 'B': for both eigenvalues and invariant subspace
(S and SEP).
COMPQ (input)
= 'V': update the matrix Q of Schur vectors;
= 'N': do not update Q.
SELECT (input)
SELECT specifies the eigenvalues in the selected
cluster. To select a real eigenvalue w(j),
SELECT(j) must be set to w(j) and w(j+1),
corresponding to a 2-by-2 diagonal block, either
SELECT(j) or SELECT(j+1) or both must be set to
either both included in the cluster or both
excluded.
N (input) The order of the matrix T. N >= 0.
T (input/output)
On entry, the upper quasi-triangular matrix T, in
Schur canonical form. On exit, T is overwritten
by the reordered matrix T, again in Schur canoni-
cal form, with the selected eigenvalues in the
leading diagonal blocks.
LDT (input)
The leading dimension of the array T. LDT >=
max(1,N).
Q (input) On entry, if COMPQ = 'V', the matrix Q of Schur
vectors. On exit, if COMPQ = 'V', Q has been
postmultiplied by the orthogonal transformation
matrix which reorders T; the leading M columns of
Q form an orthonormal basis for the specified
invariant subspace. If COMPQ = 'N', Q is not
referenced.
LDQ (input)
The leading dimension of the array Q. LDQ >= 1;
and if COMPQ = 'V', LDQ >= N.
WR (output)
The real and imaginary parts, respectively, of the
reordered eigenvalues of T. The eigenvalues are
stored in the same order as on the diagonal of T,
with WR(i) = T(i,i) and, if T(i:i+1,i:i+1) is a
2-by-2 diagonal block, WI(i) > 0 and WI(i+1) =
-WI(i). Note that if a complex eigenvalue is suf-
ficiently ill-conditioned, then its value may
differ significantly from its value before reord-
ering.
WI (output)
See the description of WR.
M (output)
The dimension of the specified invariant subspace.
0 < = M <= N.
S (output)
If JOB = 'E' or 'B', S is a lower bound on the
reciprocal condition number for the selected clus-
ter of eigenvalues. S cannot underestimate the
true reciprocal condition number by more than a
factor of sqrt(N). If M = 0 or N, S = 1. If JOB =
'N' or 'V', S is not referenced.
SEP (output)
If JOB = 'V' or 'B', SEP is the estimated recipro-
cal condition number of the specified invariant
subspace. If M = 0 or N, SEP = norm(T). If JOB =
'N' or 'E', SEP is not referenced.
WORK (workspace)
On exit, if INFO = 0, WORK(1) returns the optimal
LWORK.
LWORK (input)
The dimension of the array WORK. If JOB = 'N',
LWORK >= max(1,N); if JOB = 'E', LWORK >= M*(N-M);
if JOB = 'V' or 'B', LWORK >= 2*M*(N-M).
If LWORK = -1, then a workspace query is assumed;
the routine only calculates the optimal size of
the WORK array, returns this value as the first
entry of the WORK array, and no error message
related to LWORK is issued by XERBLA.
IWORK (workspace/output)
If JOB = 'N' or 'E', IWORK is not referenced.
LIWORK (input)
The dimension of the array IWORK. If JOB = 'N' or
'E', LIWORK >= 1; if JOB = 'V' or 'B', LIWORK >=
M*(N-M).
If LIWORK = -1, then a workspace query is assumed;
the routine only calculates the optimal size of
the IWORK array, returns this value as the first
entry of the IWORK array, and no error message
related to LIWORK is issued by XERBLA.
INFO (output)
= 0: successful exit
< 0: if INFO = -i, the i-th argument had an ille-
gal value
= 1: reordering of T failed because some eigen-
values are too close to separate (the problem is
very ill-conditioned); T may have been partially
reordered, and WR and WI contain the eigenvalues
in the same order as in T; S and SEP (if
requested) are set to zero.
DTRSEN first collects the selected eigenvalues by computing
an orthogonal transformation Z to move them to the top left
corner of T. In other words, the selected eigenvalues are
the eigenvalues of T11 in:
Z'*T*Z = ( T11 T12 ) n1
( 0 T22 ) n2
n1 n2
where N = n1+n2 and Z' means the transpose of Z. The first
n1 columns of Z span the specified invariant subspace of T.
If T has been obtained from the real Schur factorization of
a matrix A = Q*T*Q', then the reordered real Schur factori-
zation of A is given by A = (Q*Z)*(Z'*T*Z)*(Q*Z)', and the
first n1 columns of Q*Z span the corresponding invariant
subspace of A.
The reciprocal condition number of the average of the eigen-
values of T11 may be returned in S. S lies between 0 (very
badly conditioned) and 1 (very well conditioned). It is com-
puted as follows. First we compute R so that
P = ( I R ) n1
( 0 0 ) n2
n1 n2
is the projector on the invariant subspace associated with
T11. R is the solution of the Sylvester equation:
T11*R - R*T22 = T12.
Let F-norm(M) denote the Frobenius-norm of M and 2-norm(M)
denote the two-norm of M. Then S is computed as the lower
bound
(1 + F-norm(R)**2)**(-1/2)
on the reciprocal of 2-norm(P), the true reciprocal condi-
tion number. S cannot underestimate 1 / 2-norm(P) by more
than a factor of sqrt(N).
An approximate error bound for the computed average of the
eigenvalues of T11 is
EPS * norm(T) / S
where EPS is the machine precision.
The reciprocal condition number of the right invariant sub-
space spanned by the first n1 columns of Z (or of Q*Z) is
returned in SEP. SEP is defined as the separation of T11
and T22:
sep( T11, T22 ) = sigma-min( C )
where sigma-min(C) is the smallest singular value of the
n1*n2-by-n1*n2 matrix
C = kprod( I(n2), T11 ) - kprod( transpose(T22), I(n1) )
I(m) is an m by m identity matrix, and kprod denotes the
Kronecker product. We estimate sigma-min(C) by the recipro-
cal of an estimate of the 1-norm of inverse(C). The true
reciprocal 1-norm of inverse(C) cannot differ from sigma-
min(C) by more than a factor of sqrt(n1*n2).
When SEP is small, small changes in T can cause large
changes in the invariant subspace. An approximate bound on
the maximum angular error in the computed right invariant
subspace is
EPS * norm(T) / SEP