Reducing synchronization on the parallel Davidson method for the large, sparse, eigenvalue problem

Author

Stathopoulos, Andreas ; Fischer, Charlotte F.

Author_Institution

Dept. of Comput. Sci., Vanderbilt Univ., Nashville, TN, USA

fYear

1993

fDate

15-19 Nov. 1993

Firstpage

172

Lastpage

180

Abstract

The Davidson method is extensively used in quantum chemistry and atomic physics for finding a few extreme eigenpairs of a large, sparse, symmetric matrix. It can be viewed as a preconditioned version of the Lanczos method which reduces the number of iterations at the expense of a more complicated step. Frequently, the problem sizes involved demand the use of large multicomputers with hundreds or thousands of processors. The difficulties occurring in parallelizing the Davidson step are dealt with and results on a smaller scale machine are reported. The new version improves the parallel characteristics of the Davidson algorithm and holds promise for a large number of processors. Its stability and reliability is similar to that of the original method.

Keywords

chemistry computing; eigenvalues and eigenfunctions; parallel algorithms; physics computing; synchronisation; Davidson algorithm; Davidson step; Lanczos method; atomic physics; eigenvalue problem; extreme eigenpairs; iterations; large sparse symmetric matrix; multicomputers; parallel Davidson method; parallel characteristics; quantum chemistry; reliability; stability; synchronisation reduction; Chemistry; Computer science; Eigenvalues and eigenfunctions; High performance computing; Iris; Parallel processing; Physics; Quantum computing; Sparse matrices; Symmetric matrices;

fLanguage

English

Publisher

ieee

Conference_Titel

Supercomputing '93. Proceedings

ISSN

1063-9535

Print_ISBN

0-8186-4340-4

Type

conf

DOI

10.1109/SUPERC.1993.1263443

Filename

1263443