Visible to Intel only — GUID: GUID-5FB9B279-A242-428F-AB6A-10880ED63519
Visible to Intel only — GUID: GUID-5FB9B279-A242-428F-AB6A-10880ED63519
?ggsvd3
Computes generalized SVD.
Syntax
lapack_int LAPACKE_sggsvd3 (int matrix_layout, char jobu, char jobv, char jobq, lapack_int m, lapack_int n, lapack_int p, lapack_int * k, lapack_int * l, float * a, lapack_int lda, float * b, lapack_int ldb, float * alpha, float * beta, float * u, lapack_int ldu, float * v, lapack_int ldv, float * q, lapack_int ldq, lapack_int * iwork);
lapack_int LAPACKE_dggsvd3 (int matrix_layout, char jobu, char jobv, char jobq, lapack_int m, lapack_int n, lapack_int p, lapack_int * k, lapack_int * l, double * a, lapack_int lda, double * b, lapack_int ldb, double * alpha, double * beta, double * u, lapack_int ldu, double * v, lapack_int ldv, double * q, lapack_int ldq, lapack_int * iwork);
lapack_int LAPACKE_cggsvd3 (int matrix_layout, char jobu, char jobv, char jobq, lapack_int m, lapack_int n, lapack_int p, lapack_int * k, lapack_int * l, lapack_complex_float * a, lapack_int lda, lapack_complex_float * b, lapack_int ldb, float * alpha, float * beta, lapack_complex_float * u, lapack_int ldu, lapack_complex_float * v, lapack_int ldv, lapack_complex_float * q, lapack_int ldq, lapack_int * iwork);
lapack_int LAPACKE_zggsvd3 (int matrix_layout, char jobu, char jobv, char jobq, lapack_int m, lapack_int n, lapack_int p, lapack_int * k, lapack_int * l, lapack_complex_double * a, lapack_int lda, lapack_complex_double * b, lapack_int ldb, double * alpha, double * beta, lapack_complex_double * u, lapack_int ldu, lapack_complex_double * v, lapack_int ldv, lapack_complex_double * q, lapack_int ldq, lapack_int * iwork);
Include Files
- mkl.h
Description
?ggsvd3 computes the generalized singular value decomposition (GSVD) of an m-by-n real or complex matrix A and p-by-n real or complex matrix B:
UT*A*Q = D1*( 0 R ), VT*B*Q = D2*( 0 R ) for real flavors
or
UH*A*Q = D1*( 0 R ), VH*B*Q = D2*( 0 R ) for complex flavors
where U, V and Q are orthogonal/unitary matrices.
Let k+l = the effective numerical rank of the matrix (ATBT)T for real flavors or the matrix (AH,BH)H for complex flavors, then R is a (k + l)-by-(k + l) nonsingular upper triangular matrix, D1 and D2 are m-by-(k + l) and p-by-(k + l) "diagonal" matrices and of the following structures, respectively:
If m-k-l≥ 0,
where
C = diag( alpha(k+1), ... , alpha(k+l) ),
S = diag( beta(k+1), ... , beta(k+l) ),
C2 + S2 = I.
If m - k - l < 0,
where
C = diag(alpha(k + 1), ... , alpha(m)),
S = diag(beta(k + 1), ... , beta(m)),
C2 + S2 = I.
The routine computes C, S, R, and optionally the orthogonal/unitary transformation matrices U, V and Q.
In particular, if B is an n-by-n nonsingular matrix, then the GSVD of A and B implicitly gives the SVD of A*inv(B):
A*inv(B) = U*(D1*inv(D2))*VT for real flavors
or
A*inv(B) = U*(D1*inv(D2))*VH for complex flavors.
If (AT,BT)T for real flavors or (AH,BH)H for complex flavors has orthonormal columns, then the GSVD of A and B is also equal to the CS decomposition of A and B. Furthermore, the GSVD can be used to derive the solution of the eigenvalue problem:
AT*AX = λ* BT*BX for real flavors
or
AH*AX = λ* BH*BX for complex flavors
In some literature, the GSVD of A and B is presented in the form
UT*A*X = ( 0 D1 ), VT*B*X = ( 0 D2 ) for real (A, B)
or
UH*A*X = ( 0 D1 ), VH*B*X = ( 0 D2 ) for complex (A, B)
where U and V are orthogonal and X is nonsingular, D1 and D2 are "diagonal''. The former GSVD form can be converted to the latter form by taking the nonsingular matrix X as
Input Parameters
- matrix_layout
-
Specifies whether matrix storage layout is row major (LAPACK_ROW_MAJOR) or column major (LAPACK_COL_MAJOR).
- jobu
-
= 'U': Orthogonal/unitary matrix U is computed;
= 'N': U is not computed.
- jobv
-
= 'V': Orthogonal/unitary matrix V is computed;
= 'N': V is not computed.
- jobq
-
= 'Q': Orthogonal/unitary matrix Q is computed;
= 'N': Q is not computed.
- m
-
The number of rows of the matrix A.
m≥ 0.
- n
-
The number of columns of the matrices A and B.
n≥ 0.
- p
-
The number of rows of the matrix B.
p≥ 0.
- a
-
Array, size (lda*n).
On entry, the m-by-n matrix A.
- lda
-
The leading dimension of the array a.
lda≥ max(1,m).
- b
-
Array, size (ldb*n).
On entry, the p-by-n matrix B.
- ldb
-
The leading dimension of the array b.
ldb≥ max(1,p).
- ldu
-
The leading dimension of the array u.
ldu≥ max(1,m) if jobu = 'U'; ldu≥ 1 otherwise.
- ldv
-
The leading dimension of the array v.
ldv≥ max(1,p) if jobv = 'V'; ldv≥ 1 otherwise.
- ldq
-
The leading dimension of the array q.
ldq≥ max(1,n) if jobq = 'Q'; ldq≥ 1 otherwise.
- iwork
-
Array, size (n).
Output Parameters
k, l |
On exit, k and l specify the dimension of the subblocks described in the Description section. k + l = effective numerical rank of (AT,BT)T for real flavors or (AH,BH)H for complex flavors. |
a |
On exit, a contains the triangular matrix R, or part of R. If m-k-l≥ 0, R is stored in the elements of array a corresponding to A1: k + l,n - k - l + 1:n. If m - k - l < 0, is stored in the elements of array a corresponding to A(1:m, n - k - l + 1:n, and R33 is stored in bthe elements of array a corresponding to Am - k + 1:l,n + m - k - l + 1:n on exit. |
b |
On exit, b contains part of the triangular matrix R if m - k - l < 0. See Description for details. |
alpha |
Array, size (n) |
beta |
Array, size (n) On exit, alpha and beta contain the generalized singular value pairs of a and b; alpha[0: k - 1] = 1, beta[0: k - 1] = 0, and if m - k - l≥ 0, alpha[k:k + l - 1] = C, beta[k:k + l - 1] = S, or if m - k - l < 0, alpha[k:m - 1] = C, alpha[m: k + l - 1] = 0 beta[k: m - 1] =S, beta[m: k + l - 1] = 1 and alpha[k + l: n - 1] = 0 beta[k + l : n - 1] = 0 |
u |
Array, size (ldu*m). If jobu = 'U', u contains the m-by-m orthogonal/unitary matrix U. If jobu = 'N', u is not referenced. |
v |
Array, size (ldv*p). If jobv = 'V', v contains the p-by-p orthogonal/unitary matrix V. If jobv = 'N', v is not referenced. |
q |
Array, size (ldq*n). If jobq = 'Q', q contains the n-by-n orthogonal/unitary matrix Q. If jobq = 'N', q is not referenced. |
iwork |
On exit, iwork stores the sorting information. More precisely, the following loop uses iwork to sort alpha: for (i = k; i<min(m,k + l); i++) { swap (alpha[i], alpha[iwork[i] - 1]); } such that alpha[0] ≥alpha[1] ≥ ... ≥alpha[n - 1]. |
Return Values
This function returns a value info.
= 0: successful exit.
< 0: if info = -i, the i-th argument had an illegal value.
> 0: if info = 1, the Jacobi-type procedure failed to converge.
For further details, see subroutine ?tgsja.
Application Notes
?ggsvd3 replaces the deprecated subroutine ?ggsvd.