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schur
[ordered] Schur decomposition of matrix and pencils
Calling Sequence
[U,T] = schur(A) [U,dim [,T] ]=schur(A,flag) [U,dim [,T] ]=schur(A,extern1) [As,Es [,Q,Z]]=schur(A,E) [As,Es [,Z,dim]] = schur(A,E,flag) [Z,dim] = schur(A,E,flag) [As,Es [,Z,dim]]= schur(A,E,extern2) [Z,dim]= schur(A,E,extern2)
Arguments
- A
real or complex square matrix.
- E
real or complex square matrix with same dimensions as
A
.- flag
character string (
'c'
or'd'
)- extern1
an ``external'', see below
- extern2
an ``external'', see below
- U
orthogonal or unitary square matrix
- Q
orthogonal or unitary square matrix
- Z
orthogonal or unitary square matrix
- T
upper triangular or quasi-triangular square matrix
- As
upper triangular or quasi-triangular square matrix
- Es
upper triangular square matrix
- dim
integer
Description
Schur forms, ordered Schur forms of matrices and pencils
- MATRIX SCHUR FORM
- Usual schur form:
[U,T] = schur(A)
produces a Schur matrixT
and a unitary matrixU
so thatA = U*T*U'
andU'*U = eye(U)
. By itself, schur(A
) returnsT
. IfA
is complex, the Complex Schur Form is returned in matrixT
. The Complex Schur Form is upper triangular with the eigenvalues ofA
on the diagonal. IfA
is real, the Real Schur Form is returned. The Real Schur Form has the real eigenvalues on the diagonal and the complex eigenvalues in 2-by-2 blocks on the diagonal.- Ordered Schur forms
[U,dim]=schur(A,'c')
returns an unitary matrixU
which transformsA
into schur form. In addition, the dim first columns ofU
make a basis of the eigenspace ofA
associated with eigenvalues with negative real parts (stable "continuous time" eigenspace).[U,dim]=schur(A,'d')
returns an unitary matrixU
which transformsA
into schur form. In addition, thedim
first columns ofU
span a basis of the eigenspace ofA
associated with eigenvalues with magnitude lower than 1 (stable "discrete time" eigenspace).[U,dim]=schur(A,extern1)
returns an unitary matrixU
which transformsA
into schur form. In addition, thedim
first columns ofU
span a basis of the eigenspace ofA
associated with the eigenvalues which are selected by the external functionextern1
(see external for details). This external can be described by a Scilab function or by C or Fortran procedure:- a Scilab function
If
extern1
is described by a Scilab function, it should have the following calling sequence:s=extern1(Ev)
, whereEv
is an eigenvalue ands
a boolean.- a C or Fortran procedure
If
extern1
is described by a C or Fortran function it should have the following calling sequence:int extern1(double *EvR, double *EvI)
whereEvR
andEvI
are eigenvalue real and complex parts. a true or non zero returned value stands for selected eigenvalue.
- PENCIL SCHUR FORMS
- Usual Pencil Schur form
[As,Es] = schur(A,E)
produces a quasi triangularAs
matrix and a triangularEs
matrix which are the generalized Schur form of the pairA, E
.[As,Es,Q,Z] = schur(A,E)
returns in addition two unitary matricesQ
andZ
such thatAs=Q'*A*Z
andEs=Q'*E*Z
.- Ordered Schur forms:
[As,Es,Z,dim] = schur(A,E,'c')
returns the real generalized Schur form of the pencils*E-A
. In addition, the dim first columns ofZ
span a basis of the right eigenspace associated with eigenvalues with negative real parts (stable "continuous time" generalized eigenspace).[As,Es,Z,dim] = schur(A,E,'d')
returns the real generalized Schur form of the pencil
s*E-A
. In addition, the dim first columns ofZ
make a basis of the right eigenspace associated with eigenvalues with magnitude lower than 1 (stable "discrete time" generalized eigenspace).[As,Es,Z,dim] = schur(A,E,extern2)
returns the real generalized Schur form of the pencil
s*E-A
. In addition, the dim first columns ofZ
make a basis of the right eigenspace associated with eigenvalues of the pencil which are selected according to a rule which is given by the functionextern2
. (see external for details). This external can be described by a Scilab function or by C or Fortran procedure:- A Scilab function
If
extern2
is described by a Scilab function, it should have the following calling sequence:s=extern2(Alpha,Beta)
, whereAlpha
andBeta
defines a generalized eigenvalue ands
a boolean.- C or Fortran procedure
if external
extern2
is described by a C or a Fortran procedure, it should have the following calling sequence:int extern2(double *AlphaR, double *AlphaI, double *Beta)
if
A
andE
are real andint extern2(double *AlphaR, double *AlphaI, double *BetaR, double *BetaI)
if
A
orE
are complex.Alpha
, andBeta
defines the generalized eigenvalue. a true or non zero returned value stands for selected generalized eigenvalue.
References
Matrix schur form computations are based on the Lapack routines DGEES and ZGEES.
Pencil schur form computations are based on the Lapack routines DGGES and ZGGES.
Examples
//SCHUR FORM OF A MATRIX //---------------------- A=diag([-0.9,-2,2,0.9]);X=rand(A);A=inv(X)*A*X; [U,T]=schur(A);T [U,dim,T]=schur(A,'c'); T(1:dim,1:dim) //stable cont. eigenvalues function t=mytest(Ev),t=abs(Ev)<0.95,endfunction [U,dim,T]=schur(A,mytest); T(1:dim,1:dim) // The same function in C (a Compiler is required) cd TMPDIR; C=['int mytest(double *EvR, double *EvI) {' //the C code 'if (*EvR * *EvR + *EvI * *EvI < 0.9025) return 1;' 'else return 0; }';] mputl(C,TMPDIR+'/mytest.c') //build and link lp=ilib_for_link('mytest','mytest.c',[],'c'); link(lp,'mytest','c'); //run it [U,dim,T]=schur(A,'mytest'); //SCHUR FORM OF A PENCIL //---------------------- F=[-1,%s, 0, 1; 0,-1,5-%s, 0; 0, 0,2+%s, 0; 1, 0, 0, -2+%s]; A=coeff(F,0);E=coeff(F,1); [As,Es,Q,Z]=schur(A,E); Q'*F*Z //It is As+%s*Es [As,Es,Z,dim] = schur(A,E,'c') function t=mytest(Alpha, Beta),t=real(Alpha)<0,endfunction [As,Es,Z,dim] = schur(A,E,mytest) //the same function in Fortran (a Compiler is required) ftn=['integer function mytestf(ar,ai,b)' //the fortran code 'double precision ar,ai,b' 'mytestf=0' 'if(ar.lt.0.0d0) mytestf=1' 'end'] mputl(' '+ftn,TMPDIR+'/mytestf.f') //build and link lp=ilib_for_link('mytestf','mytestf.f',[],'F'); link(lp,'mytestf','f'); //run it [As,Es,Z,dim] = schur(A,E,'mytestf')
See Also
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