c----------------------------------------------------------------------- c\BeginDoc c c\Name: dseigt c c\Description: c Compute the eigenvalues of the current symmetric tridiagonal matrix c and the corresponding error bounds given the current residual norm. c c\Usage: c call dseigt c ( RNORM, N, H, LDH, EIG, BOUNDS, WORKL, IERR ) c c\Arguments c RNORM Double precision scalar. (INPUT) c RNORM contains the residual norm corresponding to the current c symmetric tridiagonal matrix H. c c N Integer. (INPUT) c Size of the symmetric tridiagonal matrix H. c c H Double precision N by 2 array. (INPUT) c H contains the symmetric tridiagonal matrix with the c subdiagonal in the first column starting at H(2,1) and the c main diagonal in arsecond column. c c LDH Integer. (INPUT) c Leading dimension of H exactly as declared in the calling c program. c c EIG Double precision array of length N. (OUTPUT) c On output, EIG contains the N eigenvalues of H possibly c unsorted. The BOUNDS arrays are returned in the c same sorted order as EIG. c c BOUNDS Double precision array of length N. (OUTPUT) c On output, BOUNDS contains the error estimates corresponding c to the eigenvalues EIG. This is equal to RNORM times the c last components of the eigenvectors corresponding to the c eigenvalues in EIG. c c WORKL Double precision work array of length 3*N. (WORKSPACE) c Private (replicated) array on each PE or array allocated on c the front end. c c IERR Integer. (OUTPUT) c Error exit flag from dstqrb. c c\EndDoc c c----------------------------------------------------------------------- c c\BeginLib c c\Local variables: c xxxxxx real c c\Routines called: c dstqrb ARPACK routine that computes the eigenvalues and the c last components of the eigenvectors of a symmetric c and tridiagonal matrix. c arsecond ARPACK utility routine for timing. c dvout ARPACK utility routine that prints vectors. c dcopy Level 1 BLAS that copies one vector to another. c c\Author c Danny Sorensen Phuong Vu c Richard Lehoucq CRPC / Rice University c Dept. of Computational & Houston, Texas c Applied Mathematics c Rice University c Houston, Texas c c\Revision history: c xx/xx/92: Version ' 2.4' c c\SCCS Information: @(#) c FILE: seigt.F SID: 2.4 DATE OF SID: 8/27/96 RELEASE: 2 c c\Remarks c None c c\EndLib c c----------------------------------------------------------------------- c subroutine dseigt & ( rnorm, n, h, ldh, eig, bounds, workl, ierr ) c c %----------------------------------------------------% c | Include files for debugging and timing information | c %----------------------------------------------------% c include 'debug.h' include 'stat.h' c c %------------------% c | Scalar Arguments | c %------------------% c integer ierr, ldh, n Double precision & rnorm c c %-----------------% c | Array Arguments | c %-----------------% c Double precision & eig(n), bounds(n), h(ldh,2), workl(3*n) c c %------------% c | Parameters | c %------------% c Double precision & zero parameter (zero = 0.0D+0) c c %---------------% c | Local Scalars | c %---------------% c integer i, k, msglvl c c %----------------------% c | External Subroutines | c %----------------------% c external dcopy, dstqrb, dvout c c %-----------------------% c | Executable Statements | c %-----------------------% c c %-------------------------------% c | Initialize timing statistics | c | & message level for debugging | c %-------------------------------% c call arsecond (t0) msglvl = mseigt c if (msglvl .gt. 0) then call dvout (logfil, n, h(1,2), ndigit, & '_seigt: main diagonal of matrix H') if (n .gt. 1) then call dvout (logfil, n-1, h(2,1), ndigit, & '_seigt: sub diagonal of matrix H') end if end if c call dcopy (n, h(1,2), 1, eig, 1) call dcopy (n-1, h(2,1), 1, workl, 1) call dstqrb (n, eig, workl, bounds, workl(n+1), ierr) if (ierr .ne. 0) go to 9000 if (msglvl .gt. 1) then call dvout (logfil, n, bounds, ndigit, & '_seigt: last row of the eigenvector matrix for H') end if c c %-----------------------------------------------% c | Finally determine the error bounds associated | c | with the n Ritz values of H. | c %-----------------------------------------------% c do 30 k = 1, n bounds(k) = rnorm*abs(bounds(k)) 30 continue c call arsecond (t1) tseigt = tseigt + (t1 - t0) c 9000 continue return c c %---------------% c | End of dseigt | c %---------------% c end