in packed storage. Eigenvalues and eigenvectors can be selected by specifying either a range of values or a range of indices for the desired eigenvalues.

Syntax

[ap, m, w, z, jfail, info] = f08gp(jobz, range, uplo, n, ap, vl, vu, il, iu, abstol)

[ap, m, w, z, jfail, info] = nag_lapack_zhpevx(jobz, range, uplo, n, ap, vl, vu, il, iu, abstol)

Description

The Hermitian matrix

A

is first reduced to real tridiagonal form, using unitary similarity transformations. The required eigenvalues and eigenvectors are then computed from the tridiagonal matrix; the method used depends upon whether all, or selected, eigenvalues and eigenvectors are required.

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 http://www.netlib.org/lapack/lug

Demmel J W and Kahan W (1990) Accurate singular values of bidiagonal matrices SIAM J. Sci. Statist. Comput. 11 873–912

Golub G H and Van Loan C F (1996) Matrix Computations (3rd Edition) Johns Hopkins University Press, Baltimore

Parameters

Compulsory Input Parameters

1: $jobz$ – string (length ≥ 1)

Indicates whether eigenvectors are computed.

$jobz ='N'$: Only eigenvalues are computed.
$jobz ='V'$: Eigenvalues and eigenvectors are computed.

Constraint:

jobz ='N'

'V'

2: $range$ – string (length ≥ 1)

range ='A'

, all eigenvalues will be found.

range ='V'

, all eigenvalues in the half-open interval

(vl, vu]

will be found.

range ='I'

, the ilth to iuth eigenvalues will be found.

Constraint:

range ='A'

'V'

'I'

3: $uplo$ – string (length ≥ 1)

uplo ='U'

, the upper triangular part of

A

is stored.

uplo ='L'

, the lower triangular part of

A

is stored.

Constraint:

uplo ='U'

'L'

4: $n$ – int64int32nag_int scalar

n

, the order of the matrix

A

Constraint:

n \geq 0

5: $ap (:)$ – complex array

The dimension of the array ap must be at least

\max (1, n \times (n + 1) / 2)

The upper or lower triangle of the

n

n

Hermitian matrix

A

, packed by columns.

More precisely,

if $uplo ='U'$ , the upper triangle of $A$ must be stored with element $A_{i j}$ in $ap (i + j (j - 1) / 2)$ for $i \leq j$ ;
if $uplo ='L'$ , the lower triangle of $A$ must be stored with element $A_{i j}$ in $ap (i + (2 n - j) (j - 1) / 2)$ for $i \geq j$ .

6: $vl$ – double scalar

7: $vu$ – double scalar

range ='V'

, the lower and upper bounds of the interval to be searched for eigenvalues.

range ='A'

'I'

, vl and vu are not referenced.

Constraint: if

range ='V'

vl < vu

8: $il$ – int64int32nag_int scalar

9: $iu$ – int64int32nag_int scalar

range ='I'

, the indices (in ascending order) of the smallest and largest eigenvalues to be returned.

range ='A'

'V'

, il and iu are not referenced.

Constraints:

if $range ='I'$ and $n = 0$ , $il = 1$ and $iu = 0$ ;
if $range ='I'$ and $n > 0$ , $1 \leq il \leq iu \leq n$ .

10: $abstol$ – double scalar

The absolute error tolerance for the eigenvalues. An approximate eigenvalue is accepted as converged when it is determined to lie in an interval

[a, b]

of width less than or equal to

abstol + ε \max (|a|, |b|),

where

ε

is the machine precision. If abstol is less than or equal to zero, then

ε {‖T‖}_{1}

will be used in its place, where

T

is the tridiagonal matrix obtained by reducing

A

to tridiagonal form. Eigenvalues will be computed most accurately when abstol is set to twice the underflow threshold

2 \times x02am ()

, not zero. If this function returns with

info > 0

, indicating that some eigenvectors did not converge, try setting abstol to

2 \times x02am ()

. See Demmel and Kahan (1990).

Optional Input Parameters

None.

Output Parameters

1: $ap (:)$ – complex array

The dimension of the array ap will be

\max (1, n \times (n + 1) / 2)

ap stores the values generated during the reduction to tridiagonal form. The elements of the diagonal and the off-diagonal of the tridiagonal matrix overwrite the corresponding elements of

A

2: $m$ – int64int32nag_int scalar

The total number of eigenvalues found.

0 \leq m \leq n

range ='A'

m = n

range ='I'

m = iu - il + 1

3: $w (n)$ – double array

The selected eigenvalues in ascending order.

4: $z (ldz :)$ – complex array

The first dimension,

ldz

, of the array z will be

if $jobz ='V'$ , $ldz = \max (1, n)$ ;
otherwise $ldz = 1$ .

The second dimension of the array z will be

\max (1, m)

jobz ='V'

and

1

otherwise.

jobz ='V'

, then

if $info = 0$ , the first m columns of $Z$ contain the orthonormal eigenvectors of the matrix $A$ corresponding to the selected eigenvalues, with the $i$ th column of $Z$ holding the eigenvector associated with $w (i)$ ;
if an eigenvector fails to converge ( $info > 0$ ), then that column of $Z$ contains the latest approximation to the eigenvector, and the index of the eigenvector is returned in jfail.

jobz ='N'

, z is not referenced.

5: $jfail (:)$ – int64int32nag_int array

The dimension of the array jfail will be

\max (1, n)

jobz ='V'

, then

if $info = 0$ , the first m elements of jfail are zero;
if $info > 0$ , jfail contains the indices of the eigenvectors that failed to converge.

jobz ='N'

, jfail is not referenced.

6: $info$ – int64int32nag_int scalar

info = 0

unless the function detects an error (see Error Indicators and Warnings).

Error Indicators and Warnings

$info < 0$: If $info = - i$ , argument $i$ had an illegal value. An explanatory message is output, and execution of the program is terminated.

$info > 0$: The algorithm failed to converge; $_$ eigenvectors did not converge. Their indices are stored in array jfail.

Accuracy

The computed eigenvalues and eigenvectors are exact for a nearby matrix

(A + E)

, where

{‖E‖}_{2} = O (ε) {‖A‖}_{2},

and

ε

is the machine precision. See Section 4.7 of Anderson et al. (1999) for further details.

Further Comments

The total number of floating-point operations is proportional to

n^{3}

The real analogue of this function is nag_lapack_dspevx (f08gb).

Example

This example finds the eigenvalues in the half-open interval

(- 2, 2]

, and the corresponding eigenvectors, of the Hermitian matrix

A = (\begin{array}{l} 1 & 2 - i & 3 - i & 4 - i \\ 2 + i & 2 & 3 - 2 i & 4 - 2 i \\ 3 + i & 3 + 2 i & 3 & 4 - 3 i \\ 4 + i & 4 + 2 i & 4 + 3 i & 4 \end{array}) .

Open in the MATLAB editor: f08gp_example

function f08gp_example


fprintf('f08gp example results\n\n');

% Hermitian A stored in packed format.
uplo = 'U';
n = int64(4);
ap = [1;
      2 - 1i;      2 + 0i;
      3 - 1i;      3 - 2i;      3 + 0i;
      4 - 1i;      4 - 2i;      4 - 3i;      4 + 0i];

% Eigenvalues in range [-2,2] of Hermitian A stored in packed format.
jobz  = 'Vectors';
range = 'Values in range';
vl = -2;
vu =  2;
il = int64(0);
iu = int64(0);
abstol = 0;
[~, m, w, z, jfail, info] = ...
f08gp( ...
       jobz, range, uplo, n, ap, vl, vu, il, iu, abstol);

% Normalize: largest elements are real
for i = 1:m
  [~,k] = max(abs(real(z(:,i)))+abs(imag(z(:,i))));
  z(:,i) = z(:,i)*conj(z(k,i))/abs(z(k,i));
end

fprintf('Number of eigenvalues in [-2,2] is %2d\n',m);
fprintf('\n Eigenvalues are:\n');
disp(w(1:m));

ncols  = int64(80);
indent = int64(0);
[ifail] = x04db( ...
                 'General', ' ', z, 'Bracketed', 'F7.4', ...
                 'Corresponding eigenvectors', 'Integer', 'Integer', ...
                 ncols, indent);

f08gp example results

Number of eigenvalues in [-2,2] is  2

 Eigenvalues are:
   -0.6886
    1.1412

 Corresponding eigenvectors
                    1                 2
 1  ( 0.6470, 0.0000) ( 0.0179,-0.4453)
 2  (-0.4984,-0.1130) ( 0.5706, 0.0000)
 3  ( 0.2949, 0.3165) (-0.1530, 0.5273)
 4  (-0.2241,-0.2878) (-0.2118,-0.3598)

PDF version (NAG web site, 64-bit version, 64-bit version)

Chapter Contents

Chapter Introduction

NAG Toolbox