nag_ztgevc (f08yxc) (PDF version)
f08 Chapter Contents
f08 Chapter Introduction
NAG Library Manual

NAG Library Function Document

nag_ztgevc (f08yxc)

 Contents

    1  Purpose
    7  Accuracy

1  Purpose

nag_ztgevc (f08yxc) computes some or all of the right and/or left generalized eigenvectors of a pair of complex upper triangular matrices A,B.

2  Specification

#include <nag.h>
#include <nagf08.h>
void  nag_ztgevc (Nag_OrderType order, Nag_SideType side, Nag_HowManyType how_many, const Nag_Boolean select[], Integer n, const Complex a[], Integer pda, const Complex b[], Integer pdb, Complex vl[], Integer pdvl, Complex vr[], Integer pdvr, Integer mm, Integer *m, NagError *fail)

3  Description

nag_ztgevc (f08yxc) computes some or all of the right and/or left generalized eigenvectors of the matrix pair A,B which is assumed to be in upper triangular form. If the matrix pair A,B is not upper triangular then the function nag_zhgeqz (f08xsc) should be called before invoking nag_ztgevc (f08yxc).
The right generalized eigenvector x and the left generalized eigenvector y of A,B corresponding to a generalized eigenvalue λ are defined by
A-λBx=0  
and
yH A-λ B=0.  
If a generalized eigenvalue is determined as 0/0, which is due to zero diagonal elements at the same locations in both A and B, a unit vector is returned as the corresponding eigenvector.
Note that the generalized eigenvalues are computed using nag_zhgeqz (f08xsc) but nag_ztgevc (f08yxc) does not explicitly require the generalized eigenvalues to compute eigenvectors. The ordering of the eigenvectors is based on the ordering of the eigenvalues as computed by nag_ztgevc (f08yxc).
If all eigenvectors are requested, the function may either return the matrices X and/or Y of right or left eigenvectors of A,B, or the products ZX and/or QY, where Z and Q are two matrices supplied by you. Usually, Q and Z are chosen as the unitary matrices returned by nag_zhgeqz (f08xsc). Equivalently, Q and Z are the left and right Schur vectors of the matrix pair supplied to nag_zhgeqz (f08xsc). In that case, QY and ZX are the left and right generalized eigenvectors, respectively, of the matrix pair supplied to nag_zhgeqz (f08xsc).

4  References

Anderson E, Bai Z, Bischof C, Blackford S, Demmel J, Dongarra J J, Du Croz J J, Greenbaum A, Hammarling S, McKenney A and Sorensen D (1999) LAPACK Users' Guide (3rd Edition) SIAM, Philadelphia
Golub G H and Van Loan C F (1996) Matrix Computations (3rd Edition) Johns Hopkins University Press, Baltimore
Moler C B and Stewart G W (1973) An algorithm for generalized matrix eigenproblems SIAM J. Numer. Anal. 10 241–256
Stewart G W and Sun J-G (1990) Matrix Perturbation Theory Academic Press, London

5  Arguments

1:     order Nag_OrderTypeInput
On entry: the order argument specifies the two-dimensional storage scheme being used, i.e., row-major ordering or column-major ordering. C language defined storage is specified by order=Nag_RowMajor. See Section 3.2.1.3 in the Essential Introduction for a more detailed explanation of the use of this argument.
Constraint: order=Nag_RowMajor or Nag_ColMajor.
2:     side Nag_SideTypeInput
On entry: specifies the required sets of generalized eigenvectors.
side=Nag_RightSide
Only right eigenvectors are computed.
side=Nag_LeftSide
Only left eigenvectors are computed.
side=Nag_BothSides
Both left and right eigenvectors are computed.
Constraint: side=Nag_BothSides, Nag_LeftSide or Nag_RightSide.
3:     how_many Nag_HowManyTypeInput
On entry: specifies further details of the required generalized eigenvectors.
how_many=Nag_ComputeAll
All right and/or left eigenvectors are computed.
how_many=Nag_BackTransform
All right and/or left eigenvectors are computed; they are backtransformed using the input matrices supplied in arrays vr and/or vl.
how_many=Nag_ComputeSelected
Selected right and/or left eigenvectors, defined by the array select, are computed.
Constraint: how_many=Nag_ComputeAll, Nag_BackTransform or Nag_ComputeSelected.
4:     select[dim] const Nag_BooleanInput
Note: the dimension, dim, of the array select must be at least
  • n when how_many=Nag_ComputeSelected;
  • otherwise select may be NULL.
On entry: specifies the eigenvectors to be computed if how_many=Nag_ComputeSelected. To select the generalized eigenvector corresponding to the jth generalized eigenvalue, the jth element of select should be set to Nag_TRUE.
Constraint: if how_many=Nag_ComputeSelected, select[j]=Nag_TRUE or Nag_FALSE, for j=0,1,,n-1.
5:     n IntegerInput
On entry: n, the order of the matrices A and B.
Constraint: n0.
6:     a[dim] const ComplexInput
Note: the dimension, dim, of the array a must be at least pda×n.
The i,jth element of the matrix A is stored in
  • a[j-1×pda+i-1] when order=Nag_ColMajor;
  • a[i-1×pda+j-1] when order=Nag_RowMajor.
On entry: the matrix A must be in upper triangular form. Usually, this is the matrix A returned by nag_zhgeqz (f08xsc).
7:     pda IntegerInput
On entry: the stride separating row or column elements (depending on the value of order) in the array a.
Constraint: pdamax1,n.
8:     b[dim] const ComplexInput
Note: the dimension, dim, of the array b must be at least pdb×n.
The i,jth element of the matrix B is stored in
  • b[j-1×pdb+i-1] when order=Nag_ColMajor;
  • b[i-1×pdb+j-1] when order=Nag_RowMajor.
On entry: the matrix B must be in upper triangular form with non-negative real diagonal elements. Usually, this is the matrix B returned by nag_zhgeqz (f08xsc).
9:     pdb IntegerInput
On entry: the stride separating row or column elements (depending on the value of order) in the array b.
Constraint: pdbmax1,n.
10:   vl[dim] ComplexInput/Output
Note: the dimension, dim, of the array vl must be at least
  • pdvl×mm when side=Nag_LeftSide or Nag_BothSides and order=Nag_ColMajor;
  • n×pdvl when side=Nag_LeftSide or Nag_BothSides and order=Nag_RowMajor;
  • otherwise vl may be NULL.
The ith element of the jth vector is stored in
  • vl[j-1×pdvl+i-1] when order=Nag_ColMajor;
  • vl[i-1×pdvl+j-1] when order=Nag_RowMajor.
On entry: if how_many=Nag_BackTransform and side=Nag_LeftSide or Nag_BothSides, vl must be initialized to an n by n matrix Q. Usually, this is the unitary matrix Q of left Schur vectors returned by nag_zhgeqz (f08xsc).
On exit: if side=Nag_LeftSide or Nag_BothSides, vl contains:
  • if how_many=Nag_ComputeAll, the matrix Y of left eigenvectors of A,B;
  • if how_many=Nag_BackTransform, the matrix QY;
  • if how_many=Nag_ComputeSelected, the left eigenvectors of A,B specified by select, stored consecutively in the rows or columns (depending on the value of order) of the array vl, in the same order as their corresponding eigenvalues.
11:   pdvl IntegerInput
On entry: the stride used in the array vl.
Constraints:
  • if order=Nag_ColMajor,
    • if side=Nag_LeftSide or Nag_BothSides, pdvl n ;
    • if side=Nag_RightSide, vl may be NULL;
  • if order=Nag_RowMajor,
    • if side=Nag_LeftSide or Nag_BothSides, pdvlmm;
    • if side=Nag_RightSide, vl may be NULL.
12:   vr[dim] ComplexInput/Output
Note: the dimension, dim, of the array vr must be at least
  • pdvr×mm when side=Nag_RightSide or Nag_BothSides and order=Nag_ColMajor;
  • n×pdvr when side=Nag_RightSide or Nag_BothSides and order=Nag_RowMajor;
  • otherwise vr may be NULL.
The ith element of the jth vector is stored in
  • vr[j-1×pdvr+i-1] when order=Nag_ColMajor;
  • vr[i-1×pdvr+j-1] when order=Nag_RowMajor.
On entry: if how_many=Nag_BackTransform and side=Nag_RightSide or Nag_BothSides, vr must be initialized to an n by n matrix Z. Usually, this is the unitary matrix Z of right Schur vectors returned by nag_dhgeqz (f08xec).
On exit: if side=Nag_RightSide or Nag_BothSides, vr contains:
  • if how_many=Nag_ComputeAll, the matrix X of right eigenvectors of A,B;
  • if how_many=Nag_BackTransform, the matrix ZX;
  • if how_many=Nag_ComputeSelected, the right eigenvectors of A,B specified by select, stored consecutively in the rows or columns (depending on the value of order) of the array vr, in the same order as their corresponding eigenvalues.
13:   pdvr IntegerInput
On entry: the stride used in the array vr.
Constraints:
  • if order=Nag_ColMajor,
    • if side=Nag_RightSide or Nag_BothSides, pdvr n ;
    • if side=Nag_LeftSide, vr may be NULL;
  • if order=Nag_RowMajor,
    • if side=Nag_RightSide or Nag_BothSides, pdvrmm;
    • if side=Nag_LeftSide, vr may be NULL.
14:   mm IntegerInput
On entry: the number of columns in the arrays vl and/or vr.
Constraints:
  • if how_many=Nag_ComputeAll or Nag_BackTransform, mmn;
  • if how_many=Nag_ComputeSelected, mm must not be less than the number of requested eigenvectors.
15:   m Integer *Output
On exit: the number of columns in the arrays vl and/or vr actually used to store the eigenvectors. If how_many=Nag_ComputeAll or Nag_BackTransform, m is set to n. Each selected eigenvector occupies one column.
16:   fail NagError *Input/Output
The NAG error argument (see Section 3.6 in the Essential Introduction).

6  Error Indicators and Warnings

NE_ALLOC_FAIL
Dynamic memory allocation failed.
See Section 3.2.1.2 in the Essential Introduction for further information.
NE_BAD_PARAM
On entry, argument value had an illegal value.
NE_CONSTRAINT
On entry, how_many=value and select[j]=value.
Constraint: if how_many=Nag_ComputeSelected, select[j]=Nag_TRUE or Nag_FALSE, for j=0,1,,n-1.
NE_ENUM_INT_2
On entry, how_many=value, n=value and mm=value.
Constraint: if how_many=Nag_ComputeAll or Nag_BackTransform, mmn;
if how_many=Nag_ComputeSelected, mm must not be less than the number of requested eigenvectors.
On entry, side=value, pdvl=value, mm=value.
Constraint: if side=Nag_LeftSide or Nag_BothSides, pdvlmm.
On entry, side=value, pdvl=value and n=value.
Constraint: if side=Nag_LeftSide or Nag_BothSides, pdvl n .
On entry, side=value, pdvr=value, mm=value.
Constraint: if side=Nag_RightSide or Nag_BothSides, pdvrmm.
On entry, side=value, pdvr=value and n=value.
Constraint: if side=Nag_RightSide or Nag_BothSides, pdvr n .
NE_INT
On entry, n=value.
Constraint: n0.
On entry, pda=value.
Constraint: pda>0.
On entry, pdb=value.
Constraint: pdb>0.
On entry, pdvl=value.
Constraint: pdvl>0.
On entry, pdvr=value.
Constraint: pdvr>0.
NE_INT_2
On entry, pda=value and n=value.
Constraint: pdamax1,n.
On entry, pdb=value and n=value.
Constraint: pdbmax1,n.
NE_INTERNAL_ERROR
An internal error has occurred in this function. Check the function call and any array sizes. If the call is correct then please contact NAG for assistance.
An unexpected error has been triggered by this function. Please contact NAG.
See Section 3.6.6 in the Essential Introduction for further information.
NE_NO_LICENCE
Your licence key may have expired or may not have been installed correctly.
See Section 3.6.5 in the Essential Introduction for further information.

7  Accuracy

It is beyond the scope of this manual to summarise the accuracy of the solution of the generalized eigenvalue problem. Interested readers should consult Section 4.11 of the LAPACK Users' Guide (see Anderson et al. (1999)) and Chapter 6 of Stewart and Sun (1990).

8  Parallelism and Performance

nag_ztgevc (f08yxc) is not threaded by NAG in any implementation.
nag_ztgevc (f08yxc) makes calls to BLAS and/or LAPACK routines, which may be threaded within the vendor library used by this implementation. Consult the documentation for the vendor library for further information.
Please consult the X06 Chapter Introduction for information on how to control and interrogate the OpenMP environment used within this function. Please also consult the Users' Note for your implementation for any additional implementation-specific information.

9  Further Comments

nag_ztgevc (f08yxc) is the sixth step in the solution of the complex generalized eigenvalue problem and is usually called after nag_zhgeqz (f08xsc).
The real analogue of this function is nag_dtgevc (f08ykc).

10  Example

This example computes the α and β arguments, which defines the generalized eigenvalues and the corresponding left and right eigenvectors, of the matrix pair A,B given by
A = 1.0+3.0i 1.0+4.0i 1.0+5.0i 1.0+6.0i 2.0+2.0i 4.0+3.0i 8.0+4.0i 16.0+5.0i 3.0+1.0i 9.0+2.0i 27.0+3.0i 81.0+4.0i 4.0+0.0i 16.0+1.0i 64.0+2.0i 256.0+3.0i  
and
B = 1.0+0.0i 2.0+1.0i 3.0+2.0i 4.0+3.0i 1.0+1.0i 4.0+2.0i 9.0+3.0i 16.0+4.0i 1.0+2.0i 8.0+3.0i 27.0+4.0i 64.0+5.0i 1.0+3.0i 16.0+4.0i 81.0+5.0i 256.0+6.0i .  
To compute generalized eigenvalues, it is required to call five functions: nag_zggbal (f08wvc) to balance the matrix, nag_zgeqrf (f08asc) to perform the QR factorization of B, nag_zunmqr (f08auc) to apply Q to A, nag_zgghrd (f08wsc) to reduce the matrix pair to the generalized Hessenberg form and nag_zhgeqz (f08xsc) to compute the eigenvalues via the QZ algorithm.
The computation of generalized eigenvectors is done by calling nag_ztgevc (f08yxc) to compute the eigenvectors of the balanced matrix pair. The function nag_zggbak (f08wwc) is called to backward transform the eigenvectors to the user-supplied matrix pair. If both left and right eigenvectors are required then nag_zggbak (f08wwc) must be called twice.

10.1  Program Text

Program Text (f08yxce.c)

10.2  Program Data

Program Data (f08yxce.d)

10.3  Program Results

Program Results (f08yxce.r)


nag_ztgevc (f08yxc) (PDF version)
f08 Chapter Contents
f08 Chapter Introduction
NAG Library Manual

© The Numerical Algorithms Group Ltd, Oxford, UK. 2015