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<HEAD><TITLE>TG01JY - SLICOT Library Routine Documentation</TITLE>
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<H2><A Name="TG01JY">TG01JY</A></H2>
<H3>
Irreducible descriptor representation (blocked version)
</H3>
<A HREF ="#Specification"><B>[Specification]</B></A>
<A HREF ="#Arguments"><B>[Arguments]</B></A>
<A HREF ="#Method"><B>[Method]</B></A>
<A HREF ="#References"><B>[References]</B></A>
<A HREF ="#Comments"><B>[Comments]</B></A>
<A HREF ="#Example"><B>[Example]</B></A>
<P>
<B><FONT SIZE="+1">Purpose</FONT></B>
<PRE>
To find a reduced (controllable, observable, or irreducible)
descriptor representation (Ar-lambda*Er,Br,Cr) for an original
descriptor representation (A-lambda*E,B,C).
The pencil Ar-lambda*Er is in an upper block Hessenberg form, with
either Ar or Er upper triangular.
</PRE>
<A name="Specification"><B><FONT SIZE="+1">Specification</FONT></B></A>
<PRE>
SUBROUTINE TG01JY( JOB, SYSTYP, EQUIL, CKSING, RESTOR, N, M, P, A,
$ LDA, E, LDE, B, LDB, C, LDC, NR, INFRED, TOL,
$ IWORK, DWORK, LDWORK, INFO )
C .. Scalar Arguments ..
CHARACTER CKSING, EQUIL, JOB, RESTOR, SYSTYP
INTEGER INFO, LDA, LDB, LDC, LDE, LDWORK, M, N, NR, P
C .. Array Arguments ..
INTEGER INFRED(*), IWORK(*)
DOUBLE PRECISION A(LDA,*), B(LDB,*), C(LDC,*), DWORK(*),
$ E(LDE,*), TOL(*)
</PRE>
<A name="Arguments"><B><FONT SIZE="+1">Arguments</FONT></B></A>
<P>
<B>Mode Parameters</B>
<PRE>
JOB CHARACTER*1
Indicates whether the user wishes to remove the
uncontrollable and/or unobservable parts as follows:
= 'I': Remove both the uncontrollable and unobservable
parts to get an irreducible descriptor
representation;
= 'C': Remove the uncontrollable part only to get a
controllable descriptor representation;
= 'O': Remove the unobservable part only to get an
observable descriptor representation.
SYSTYP CHARACTER*1
Indicates the type of descriptor system algorithm
to be applied according to the assumed
transfer-function matrix as follows:
= 'R': Rational transfer-function matrix;
= 'S': Proper (standard) transfer-function matrix;
= 'P': Polynomial transfer-function matrix.
EQUIL CHARACTER*1
Specifies whether the user wishes to preliminarily scale
the system (A-lambda*E,B,C) as follows:
= 'S': Perform scaling;
= 'N': Do not perform scaling.
CKSING CHARACTER*1
Specifies whether the user wishes to check if the pencil
(A-lambda*E) is singular as follows:
= 'C': Check singularity;
= 'N': Do not check singularity.
If the pencil is singular, the reduced system computed for
CKSING = 'N' can be wrong.
RESTOR CHARACTER*1
Specifies whether the user wishes to save the system
matrices before each phase and restore them if no order
reduction took place as follows:
= 'R': Save and restore;
= 'N': Do not save the matrices.
</PRE>
<B>Input/Output Parameters</B>
<PRE>
N (input) INTEGER
The dimension of the descriptor state vector; also the
order of square matrices A and E, the number of rows of
matrix B, and the number of columns of matrix C. N >= 0.
M (input) INTEGER
The dimension of descriptor system input vector; also the
number of columns of matrix B. M >= 0.
P (input) INTEGER
The dimension of descriptor system output vector; also the
number of rows of matrix C. P >= 0.
A (input/output) DOUBLE PRECISION array, dimension (LDA,N)
On entry, the leading N-by-N part of this array must
contain the original state matrix A.
On exit, the leading NR-by-NR part of this array contains
the reduced order state matrix Ar of an irreducible,
controllable, or observable realization for the original
system, depending on the value of JOB, JOB = 'I',
JOB = 'C', or JOB = 'O', respectively.
The matrix Ar is upper triangular if SYSTYP = 'P'.
If SYSTYP = 'S' and JOB = 'C', the matrix [Br Ar]
is in a controllable staircase form (see SLICOT Library
routine TG01HD).
If SYSTYP = 'S' and JOB = 'I' or 'O', the matrix ( Ar )
( Cr )
is in an observable staircase form (see TG01HD).
The resulting Ar has INFRED(5) nonzero sub-diagonals.
The block structure of staircase forms is contained
in the leading INFRED(7) elements of IWORK.
LDA INTEGER
The leading dimension of array A. LDA >= MAX(1,N).
E (input/output) DOUBLE PRECISION array, dimension (LDE,N)
On entry, the leading N-by-N part of this array must
contain the original descriptor matrix E.
On exit, the leading NR-by-NR part of this array contains
the reduced order descriptor matrix Er of an irreducible,
controllable, or observable realization for the original
system, depending on the value of JOB, JOB = 'I',
JOB = 'C', or JOB = 'O', respectively.
The resulting Er has INFRED(6) nonzero sub-diagonals.
If at least for one k = 1,...,4, INFRED(k) >= 0, then the
resulting Er is structured being either upper triangular
or block Hessenberg, in accordance to the last
performed order reduction phase (see METHOD).
The block structure of staircase forms is contained
in the leading INFRED(7) elements of IWORK.
LDE INTEGER
The leading dimension of array E. LDE >= MAX(1,N).
B (input/output) DOUBLE PRECISION array, dimension (LDB,M),
if JOB = 'C', or (LDB,MAX(M,P)), otherwise.
On entry, the leading N-by-M part of this array must
contain the original input matrix B; if JOB = 'I',
or JOB = 'O', the remainder of the leading N-by-MAX(M,P)
part is used as internal workspace.
On exit, the leading NR-by-M part of this array contains
the reduced input matrix Br of an irreducible,
controllable, or observable realization for the original
system, depending on the value of JOB, JOB = 'I',
JOB = 'C', or JOB = 'O', respectively.
If JOB = 'C', only the first IWORK(1) rows of B are
nonzero.
LDB INTEGER
The leading dimension of array B. LDB >= MAX(1,N).
C (input/output) DOUBLE PRECISION array, dimension (LDC,N)
On entry, the leading P-by-N part of this array must
contain the original output matrix C; if JOB = 'I',
or JOB = 'O', the remainder of the leading MAX(M,P)-by-N
part is used as internal workspace.
On exit, the leading P-by-NR part of this array contains
the transformed state/output matrix Cr of an irreducible,
controllable, or observable realization for the original
system, depending on the value of JOB, JOB = 'I',
JOB = 'C', or JOB = 'O', respectively.
If JOB = 'I', or JOB = 'O', only the last IWORK(1) columns
(in the first NR columns) of C are nonzero.
LDC INTEGER
The leading dimension of array C.
LDC >= MAX(1,M,P) if N > 0.
LDC >= 1 if N = 0.
NR (output) INTEGER
The order of the reduced descriptor representation
(Ar-lambda*Er,Br,Cr) of an irreducible, controllable,
or observable realization for the original system,
depending on JOB = 'I', JOB = 'C', or JOB = 'O',
respectively.
INFRED (output) INTEGER array, dimension 7
This array contains information on performed reduction
and on structure of resulting system matrices as follows:
INFRED(k) >= 0 (k = 1, 2, 3, or 4) if Phase k of reduction
(see METHOD) has been performed. In this
case, INFRED(k) is the achieved order
reduction in Phase k.
INFRED(k) < 0 (k = 1, 2, 3, or 4) if Phase k was not
performed.
INFRED(5) - the number of nonzero sub-diagonals of A.
INFRED(6) - the number of nonzero sub-diagonals of E.
INFRED(7) - the number of blocks in the resulting
staircase form at last performed reduction
phase. The block dimensions are contained
in the first INFRED(7) elements of IWORK.
</PRE>
<B>Tolerances</B>
<PRE>
TOL DOUBLE PRECISION array, dimension 3
TOL(1) is the tolerance to be used in rank determinations
when transforming (A-lambda*E,B,C). If the user sets
TOL(1) > 0, then the given value of TOL(1) is used as a
lower bound for reciprocal condition numbers in rank
determinations; a (sub)matrix whose estimated condition
number is less than 1/TOL(1) is considered to be of full
rank. If the user sets TOL(1) <= 0, then an implicitly
computed, default tolerance, defined by TOLDEF1 = N*N*EPS,
is used instead, where EPS is the machine precision (see
LAPACK Library routine DLAMCH). TOL(1) < 1.
TOL(2) is the tolerance to be used for checking pencil
singularity when CKSING = 'C', or singularity of the
matrices A and E when CKSING = 'N'. If the user sets
TOL(2) > 0, then the given value of TOL(2) is used.
If the user sets TOL(2) <= 0, then an implicitly
computed, default tolerance, defined by TOLDEF2 = 10*EPS,
is used instead. TOL(2) < 1.
TOL(3) is the threshold value for magnitude of the matrix
elements, if EQUIL = 'S': elements with magnitude less
than or equal to TOL(3) are ignored for scaling. If the
user sets TOL(3) >= 0, then the given value of TOL(3) is
used. If the user sets TOL(3) < 0, then an implicitly
computed, default threshold, defined by THRESH = c*EPS,
where c = MAX(norm_1(A,E,B,C)) is used instead.
TOL(3) = 0 is not always a good choice. TOL(3) < 1.
TOL(3) is not used if EQUIL = 'N'.
</PRE>
<B>Workspace</B>
<PRE>
IWORK INTEGER array, dimension (2*N+MAX(M,P))
On exit, if INFO = 0, the leading INFRED(7) elements of
IWORK contain the orders of the diagonal blocks of
Ar-lambda*Er.
DWORK DOUBLE PRECISION array, dimension (LDWORK)
On exit, if INFO = 0, DWORK(1) returns the optimal value
of LDWORK.
LDWORK INTEGER
The length of the array DWORK.
LDWORK >= MAX(1,x,y,8*N), if EQUIL = 'S',
LDWORK >= MAX(1,x,y), if EQUIL = 'N',
where x = MAX(2*(z+MAX(M,P)+N-1),N*N+4*N), if RESTOR = 'R'
x = MAX( 2*(MAX(M,P)+N-1),N*N+4*N), if RESTOR = 'N'
y = 2*N*N+10*N+MAX(N,23), if CKSING = 'C',
y = 0, if CKSING = 'N',
z = 2*N*N+N*M+N*P, if JOB = 'I',
z = 0, if JOB <> 'I'.
For good performance, LDWORK should be generally larger.
If RESTOR = 'R', or
LDWORK >= MAX(1,2*N*N+N*M+N*P+2*(MAX(M,P)+N-1),
more accurate results are to be expected by considering
only those reductions phases (see METHOD), where effective
order reduction occurs. This is achieved by saving the
system matrices before each phase and restoring them if no
order reduction took place. Actually, if JOB = 'I' and
RESTOR = 'N', then the saved matrices are those obtained
after orthogonally triangularizing the matrix A (if
SYSTYP = 'R' or 'P'), or the matrix E (if SYSTYP = 'R'
or 'S').
If LDWORK = -1, then a workspace query is assumed;
the routine only calculates the optimal size of the
DWORK array, returns this value as the first entry of
the DWORK array, and no error message related to LDWORK
is issued by XERBLA. The optimal workspace includes the
extra space for improving the accuracy.
</PRE>
<B>Error Indicator</B>
<PRE>
INFO INTEGER
= 0: successful exit;
< 0: if INFO = -i, the i-th argument had an illegal
value;
= 1: the given pencil A - lambda*E is numerically
singular and the reduced system is not computed.
This error can be returned only if CKSING = 'C'.
</PRE>
<A name="Method"><B><FONT SIZE="+1">Method</FONT></B></A>
<PRE>
The subroutine is based on the reduction algorithms of [1], but
with a different ordering of the phases.
The order reduction is performed in 4 phases:
Phase 1: Eliminate all infinite and finite nonzero uncontrollable
eigenvalues. The resulting matrix ( Br Er ) is in a
controllable staircase form (see TG01HD), and Ar is
upper triangular.
This phase is performed if JOB = 'I' or 'C' and
SYSTYP = 'R' or 'P'.
Phase 2: Eliminate all infinite and finite nonzero unobservable
eigenvalues. The resulting matrix ( Er ) is in an
( Cr )
observable staircase form (see SLICOT Library routine
TG01ID), and Ar is upper triangular.
This phase is performed if JOB = 'I' or 'O' and
SYSTYP = 'R' or 'P'.
Phase 3: Eliminate all finite uncontrollable eigenvalues.
The resulting matrix ( Br Ar ) is in a controllable
staircase form (see TG01HD), and Er is upper triangular.
This phase is performed if JOB = 'I' or 'C' and
SYSTYP = 'R' or 'S'.
Phase 4: Eliminate all finite unobservable eigenvalues.
The resulting matrix ( Ar ) is in an observable
( Cr )
staircase form (see TG01ID), and Er is upper triangular.
This phase is performed if JOB = 'I' or 'O' and
SYSTYP = 'R' or 'S'.
The routine checks the singularity of the matrices A and/or E
(depending on JOB and SYSTYP) and skips the unnecessary phases.
See FURTHER COMMENTS.
</PRE>
<A name="References"><B><FONT SIZE="+1">References</FONT></B></A>
<PRE>
[1] A. Varga
Computation of Irreducible Generalized State-Space
Realizations.
Kybernetika, vol. 26, pp. 89-106, 1990.
</PRE>
<A name="Numerical Aspects"><B><FONT SIZE="+1">Numerical Aspects</FONT></B></A>
<PRE>
The algorithm is numerically backward stable and requires
0( N**3 ) floating point operations.
</PRE>
<A name="Comments"><B><FONT SIZE="+1">Further Comments</FONT></B></A>
<PRE>
If the pencil A-lambda*E has no zero eigenvalues, then an
irreducible realization is computed skipping Phases 3 and 4
(equivalent to setting: JOB = 'I' and SYSTYP = 'P').
</PRE>
<A name="Example"><B><FONT SIZE="+1">Example</FONT></B></A>
<P>
<B>Program Text</B>
<PRE>
* TG01JY EXAMPLE PROGRAM TEXT
*
* .. Parameters ..
INTEGER NIN, NOUT
PARAMETER ( NIN = 5, NOUT = 6 )
INTEGER NMAX, MMAX, PMAX
PARAMETER ( NMAX = 20, MMAX = 20, PMAX = 20 )
INTEGER LDA, LDB, LDC, LDE
PARAMETER ( LDA = NMAX, LDB = NMAX, LDC = PMAX,
$ LDE = NMAX )
INTEGER LDWORK, LIWORK
PARAMETER ( LDWORK = 2*NMAX*NMAX +
$ MAX( 2*( NMAX*( NMAX + MMAX + PMAX ) +
$ MAX( MMAX, PMAX ) + NMAX - 1 ),
$ 10*NMAX + MAX( NMAX, 23 ) ),
$ LIWORK = 2*NMAX + MAX( MMAX, PMAX ) )
* .. Local Scalars ..
CHARACTER CKSING, EQUIL, JOB, RESTOR, SYSTYP
INTEGER I, INFO, J, M, N, NR, P
* .. Local Arrays ..
INTEGER INFRED(7), IWORK(LIWORK)
DOUBLE PRECISION A(LDA,NMAX), B(LDB,MMAX), C(LDC,NMAX),
$ DWORK(LDWORK), E(LDE,NMAX), TOL(3)
* .. External Subroutines ..
EXTERNAL TG01JY
* .. Intrinsic Functions ..
INTRINSIC MAX
* .. Executable Statements ..
*
WRITE ( NOUT, FMT = 99999 )
* Skip the heading in the data file and read the data.
READ ( NIN, FMT = '()' )
READ ( NIN, FMT = * ) N, M, P, TOL(1), TOL(2), TOL(3), JOB,
$ SYSTYP, EQUIL, CKSING, RESTOR
IF ( N.LT.0 .OR. N.GT.NMAX ) THEN
WRITE ( NOUT, FMT = 99988 ) N
ELSE
READ ( NIN, FMT = * ) ( ( A(I,J), J = 1,N ), I = 1,N )
READ ( NIN, FMT = * ) ( ( E(I,J), J = 1,N ), I = 1,N )
IF ( M.LT.0 .OR. M.GT.MMAX ) THEN
WRITE ( NOUT, FMT = 99987 ) M
ELSE
READ ( NIN, FMT = * ) ( ( B(I,J), J = 1,M ), I = 1,N )
IF ( P.LT.0 .OR. P.GT.PMAX ) THEN
WRITE ( NOUT, FMT = 99986 ) P
ELSE
READ ( NIN, FMT = * ) ( ( C(I,J), J = 1,N ), I = 1,P )
* Find the irreducible descriptor system (Ar-lambda Er,Br,Cr).
CALL TG01JY( JOB, SYSTYP, EQUIL, CKSING, RESTOR, N, M, P,
$ A, LDA, E, LDE, B, LDB, C, LDC, NR, INFRED,
$ TOL, IWORK, DWORK, LDWORK, INFO )
*
IF ( INFO.NE.0 ) THEN
WRITE ( NOUT, FMT = 99998 ) INFO
ELSE
WRITE ( NOUT, FMT = 99994 ) NR
WRITE ( NOUT, FMT = 99991 )
DO 10 I = 1, 4
IF( INFRED(I).GE.0 )
$ WRITE ( NOUT, FMT = 99990 ) I, INFRED(I)
10 CONTINUE
WRITE ( NOUT, FMT = 99997 )
DO 20 I = 1, NR
WRITE ( NOUT, FMT = 99995 ) ( A(I,J), J = 1,NR )
20 CONTINUE
WRITE ( NOUT, FMT = 99996 )
DO 30 I = 1, NR
WRITE ( NOUT, FMT = 99995 ) ( E(I,J), J = 1,NR )
30 CONTINUE
WRITE ( NOUT, FMT = 99993 )
DO 40 I = 1, NR
WRITE ( NOUT, FMT = 99995 ) ( B(I,J), J = 1,M )
40 CONTINUE
WRITE ( NOUT, FMT = 99992 )
DO 50 I = 1, P
WRITE ( NOUT, FMT = 99995 ) ( C(I,J), J = 1,NR )
50 CONTINUE
END IF
END IF
END IF
END IF
STOP
*
99999 FORMAT (' TG01JY EXAMPLE PROGRAM RESULTS',/1X)
99998 FORMAT (' INFO on exit from TG01JY = ',I2)
99997 FORMAT (/' The reduced state dynamics matrix Ar is ')
99996 FORMAT (/' The reduced descriptor matrix Er is ')
99995 FORMAT (20(1X,F8.4))
99994 FORMAT (' Order of reduced system =', I5 )
99993 FORMAT (/' The reduced input/state matrix Br is ')
99992 FORMAT (/' The reduced state/output matrix Cr is ')
99991 FORMAT (/' Achieved order reductions in different phases')
99990 FORMAT (' Phase',I2,':', I3, ' elliminated eigenvalue(s)' )
99988 FORMAT (/' N is out of range.',/' N = ',I5)
99987 FORMAT (/' M is out of range.',/' M = ',I5)
99986 FORMAT (/' P is out of range.',/' P = ',I5)
END
</PRE>
<B>Program Data</B>
<PRE>
TG01JY EXAMPLE PROGRAM DATA
9 2 2 0.0 0.0 0.0 I R N N N
-2 -3 0 0 0 0 0 0 0
1 0 0 0 0 0 0 0 0
0 0 -2 -3 0 0 0 0 0
0 0 1 0 0 0 0 0 0
0 0 0 0 1 0 0 0 0
0 0 0 0 0 1 0 0 0
0 0 0 0 0 0 1 0 0
0 0 0 0 0 0 0 1 0
0 0 0 0 0 0 0 0 1
1 0 0 0 0 0 0 0 0
0 1 0 0 0 0 0 0 0
0 0 1 0 0 0 0 0 0
0 0 0 1 0 0 0 0 0
0 0 0 0 0 0 0 0 0
0 0 0 0 1 0 0 0 0
0 0 0 0 0 0 0 0 0
0 0 0 0 0 0 1 0 0
0 0 0 0 0 0 0 1 0
1 0
0 0
0 1
0 0
-1 0
0 0
0 -1
0 0
0 0
1 0 1 -3 0 1 0 2 0
0 1 1 3 0 1 0 0 1
</PRE>
<B>Program Results</B>
<PRE>
TG01JY EXAMPLE PROGRAM RESULTS
Order of reduced system = 7
Achieved order reductions in different phases
Phase 1: 0 elliminated eigenvalue(s)
Phase 2: 2 elliminated eigenvalue(s)
The reduced state dynamics matrix Ar is
1.0000 -0.0393 -0.0980 0.1066 -0.0781 0.2330 -0.0777
0.0000 1.0312 0.2717 -0.2609 0.1533 -0.6758 0.3553
0.0000 0.0000 1.3887 -0.6699 0.4281 -1.6389 0.7615
0.0000 0.0000 0.0000 1.2147 -0.2423 0.9792 -0.4788
0.0000 0.0000 0.0000 0.0000 1.0545 -0.5035 0.2788
0.0000 0.0000 0.0000 0.0000 0.0000 1.6355 -0.4323
0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 1.0000
The reduced descriptor matrix Er is
0.4100 0.2590 0.5080 0.3109 -0.0705 -0.1429 0.1477
-0.7629 -0.3464 0.0992 0.3007 -0.0619 -0.2483 0.0152
0.1120 -0.2124 -0.4184 0.1288 -0.0569 0.4213 0.6182
0.0000 0.1122 -0.0039 -0.2771 0.0758 -0.0975 -0.3923
0.0000 0.0000 0.3708 0.4290 -0.1006 -0.1402 0.2699
0.0000 0.0000 0.0000 0.0000 0.9458 -0.2211 0.2378
0.0000 0.0000 0.0000 0.5711 0.2648 0.5948 -0.5000
The reduced input/state matrix Br is
0.5597 -0.2363
0.4843 0.0498
0.4727 0.1491
-0.1802 -1.1574
-0.5995 -0.1556
-0.1729 -0.3999
0.0000 0.2500
The reduced state/output matrix Cr is
0.0000 0.0000 0.0000 0.0000 0.0000 0.0000 4.0000
0.0000 0.0000 0.0000 0.0000 0.0000 3.1524 -1.7500
</PRE>
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