Add to ORKGWe show how the Arnoldi algorithm for approximating a function of a matrix times a vector can be restarted in a manner analogous to restarted Krylov subspace methods for solving linear systems of equations. The resulting restarted algorithm reduces to other known algorithms for the reciprocal and the exponential functions. We further show that the restarted algorithm inherits the superlinear convergence property of its unrestarted counterpart for entire functions and present the results of numerical experiments
The convergence of Krylov subspace eigenvalue algorithms can be robustly measured by the angle the a...
Many problems in scientific computing involving a large sparse matrix A are solved by Krylov subspac...
A well-known problem in computing some matrix functions iteratively is the lack of a clear, commonly...
AbstractA new implementation of restarted Krylov subspace methods for evaluating f(A)b for a functio...
AbstractA new implementation of restarted Krylov subspace methods for evaluating f(A)b for a functio...
A common way to approximate $F(A)b$ -- the action of a matrix function on a vector -- is to use the ...
AbstractA deflated restarting Krylov subspace method for approximating a function of a matrix times ...
Abstract. We investigate an acceleration technique for restarted Krylov subspace methods for computi...
A variety of block Krylov subspace methods have been successfully developed for linear systems and m...
A variety of block Krylov subspace methods have been successfully developed for linear systems and m...
When using the Arnoldi method for approximating f(A)b, the action of a matrix function on a vector, ...
When using the Arnoldi method for approximating f(A)b, the action of a matrix function on a vector, ...
Abstract. When using the Arnoldi method for approximating f(A)b, the action of a matrix function on ...
When using the Arnoldi method for approximating f(A)b, the action of a matrix function on a vector, ...
A well-known problem in computing some matrix functions iteratively is a lack of a clear, commonly a...
The convergence of Krylov subspace eigenvalue algorithms can be robustly measured by the angle the a...
Many problems in scientific computing involving a large sparse matrix A are solved by Krylov subspac...
A well-known problem in computing some matrix functions iteratively is the lack of a clear, commonly...
AbstractA new implementation of restarted Krylov subspace methods for evaluating f(A)b for a functio...
AbstractA new implementation of restarted Krylov subspace methods for evaluating f(A)b for a functio...
A common way to approximate $F(A)b$ -- the action of a matrix function on a vector -- is to use the ...
AbstractA deflated restarting Krylov subspace method for approximating a function of a matrix times ...
Abstract. We investigate an acceleration technique for restarted Krylov subspace methods for computi...
A variety of block Krylov subspace methods have been successfully developed for linear systems and m...
A variety of block Krylov subspace methods have been successfully developed for linear systems and m...
When using the Arnoldi method for approximating f(A)b, the action of a matrix function on a vector, ...
When using the Arnoldi method for approximating f(A)b, the action of a matrix function on a vector, ...
Abstract. When using the Arnoldi method for approximating f(A)b, the action of a matrix function on ...
When using the Arnoldi method for approximating f(A)b, the action of a matrix function on a vector, ...
A well-known problem in computing some matrix functions iteratively is a lack of a clear, commonly a...
The convergence of Krylov subspace eigenvalue algorithms can be robustly measured by the angle the a...
Many problems in scientific computing involving a large sparse matrix A are solved by Krylov subspac...
A well-known problem in computing some matrix functions iteratively is the lack of a clear, commonly...