Algorithm 710: FORTRAN subroutines for computing the eigenvalues and eigenvectors of a general matrix by reduction to general tridiagonal form

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Algorithm 710: FORTRAN subroutines for computing the eigenvalues and eigenvectors of a general matrix by reduction to general tridiagonal form

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ACM Transactions on Mathematical Software (TOMS) archive
Volume 18 , Issue 4 (December 1992) table of contents

Pages: 392 - 400

Year of Publication: 1992

ISSN:0098-3500

Authors

J. J. Dongarra
G. A. Geist
C. H. Romine

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 13, Downloads (12 Months): 156, Citation Count: 2

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appendices and supplements abstract references cited by index terms collaborative colleagues peer to peer

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eigenvalues and eigenvectors of a general matrix
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ABSTRACT

This paper describes programs to reduce a nonsymmetric matrix to tridiagonal form, to compute the eigenvalues of the tridiagonal matrix, to improve the accuracy of an eigenvalue, and to compute the corresponding eigenvector. The intended purpose of the software is to find a few eigenpairs of a dense nonsymmetric matrix faster and more accurately than previous methods. The performance and accuracy of the new routines are compared to two EISPACK paths: RG and HQR-INVIT. The results show that the new routines are more accurate and also faster if less than 20 percent of the eigenpairs are needed.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	DONGARRA, J. J. Improving the accuracy of computed matrix eigenvalues. Tech. Rep. ANL-80-84, Argonne National Laboratory, Chicago, Ill., Aug. 1980.
	2	DONGARRA, J. J., MOLER, C. B., AND WILKINSON, J.H. Improving the accuracy of computed elgenvalues and eigenvectors. SIAM J Numer. Anal. 20, i (Feb. 1983), 23-45.
	3	FRANCIS, J. G.F. The QR transformation Part 2. Comput. J. 4, 4 (Oct. 1961), 332-345.
	4	GEIST, G.A. Reduction of a general matrix to tndiagonal form. Tech. Rep. ORNL/TM-10991, Oak Ridge National Laboratory, Oak Ridge, Tenn., Feb. 1989
	5	George A. Geist, Reduction of a general matrix to tridiagonal form, SIAM Journal on Matrix Analysis and Applications, v.12 n.2, p.362-373, April 1991 [doi>10.1137/0612026]
	6	GELS?, G A., Lu, A, AND W^CHSPRES$, E, L. Stabilized Gaussian reduction of an arbitrary matrix to tridiagonal form. Tech. Rep. ORNL/TM-11089, Oak Ridge National Laboratory, Oak Ridge, Tenn., Feb. 1989.
	7	GOLUB, G. H., AND VAN LOAN, C.F. Matrtx Cornputatzons. Johns Hopkins University Press, Baltimore, Md., 1983.
	8	R^LL, L. B. Comptltational Solution of Nonlinear Operator Equations. Wiley, New York, 1969.
	9	RUTISHAUSER, H. Solution of e~genvalue problems with the LR transformation. Nat. Bur. Standards Appl. Math. Ser. 49 (1958), 47-81.
	10	SMrrH, B. T., BOYLE, J. M., DONGARRA, J. J., GARABOW, B. S., IKEBE, Y., KLEMA, V. C., AND MOLER, C. B. Matrix Elgensystern Routtnes--EISPACK Guzde. Springer-Verlag, Heidelberg, 1974
	11	J. H. Wilkinson, The algebraic eigenvalue problem, Oxford University Press, Inc., New York, NY, 1988

CITED BY 2

	Julie Langou , Julien Langou , Piotr Luszczek , Jakub Kurzak , Alfredo Buttari , Jack Dongarra, Tools and techniques for performance---Exploiting the performance of 32 bit floating point arithmetic in obtaining 64 bit accuracy (revisiting iterative refinement for linear systems), Proceedings of the 2006 ACM/IEEE conference on Supercomputing, November 11-17, 2006, Tampa, Florida
	Gary W. Howell , Nadia Diaa, Algorithm 841: BHESS: Gaussian reduction to a similar banded Hessenberg form, ACM Transactions on Mathematical Software (TOMS), v.31 n.1, p.166-185, March 2005