International audienceWe consider the solution of sparse linear systems using direct methods via LU factorization. Unless the matrix is positive definite, numerical pivoting is usually needed to ensure stability, which is costly to implement especially in the sparse case. The Random Butterfly Transformations (RBT) technique provides an alternative to pivoting and is easily parallelizable. The RBT transforms the original matrix into another one that can be factorized without pivoting with probability one. This approach has been successful for dense matrices; in this work, we investigate the sparse case. In particular, we address the issue of fill-in in the transformed system
An over view of advanced techniques for solving large sparse linear systems of equations is presente...
This paper focuses on efficiently solving large sparse symmetric indefinite systems of linear equati...
In the interest of reproducible research, this is exactly the version of the code used to generate t...
Also appeared as Lapack Working Note 285We consider the solution of sparse linear systems using dire...
International audienceWe illustrate how linear algebra calculations can be enhanced by statistical t...
© 2015 Society for Industrial and Applied Mathematics.The paper introduces the butterfly factorizati...
Abstract. The paper introduces the butterfly factorization as a data-sparse approximation for the ma...
Out-of-core sparse direct solvers reduce the amount of main memory needed to factorize and solve lar...
International audienceWe propose to use a randomization technique based on Random Butterfly Transfor...
We illustrate how linear algebra calculations can be enhanced by statistical techniques in the case ...
This paper presents an adaptive randomized algorithm for computing the butterfly factorization of an...
In the first part of this dissertation, we explore a novel randomized pivoting strategy to efficient...
The recursive structure of butterfly matrices has been exploited to accelerate common methods in com...
Random butterfly matrices were introduced by Parker in 1995 to remove the need for pivoting when usi...
An oblique projection method is adapted to solve large, sparse, unstructured systems of linear equat...
An over view of advanced techniques for solving large sparse linear systems of equations is presente...
This paper focuses on efficiently solving large sparse symmetric indefinite systems of linear equati...
In the interest of reproducible research, this is exactly the version of the code used to generate t...
Also appeared as Lapack Working Note 285We consider the solution of sparse linear systems using dire...
International audienceWe illustrate how linear algebra calculations can be enhanced by statistical t...
© 2015 Society for Industrial and Applied Mathematics.The paper introduces the butterfly factorizati...
Abstract. The paper introduces the butterfly factorization as a data-sparse approximation for the ma...
Out-of-core sparse direct solvers reduce the amount of main memory needed to factorize and solve lar...
International audienceWe propose to use a randomization technique based on Random Butterfly Transfor...
We illustrate how linear algebra calculations can be enhanced by statistical techniques in the case ...
This paper presents an adaptive randomized algorithm for computing the butterfly factorization of an...
In the first part of this dissertation, we explore a novel randomized pivoting strategy to efficient...
The recursive structure of butterfly matrices has been exploited to accelerate common methods in com...
Random butterfly matrices were introduced by Parker in 1995 to remove the need for pivoting when usi...
An oblique projection method is adapted to solve large, sparse, unstructured systems of linear equat...
An over view of advanced techniques for solving large sparse linear systems of equations is presente...
This paper focuses on efficiently solving large sparse symmetric indefinite systems of linear equati...
In the interest of reproducible research, this is exactly the version of the code used to generate t...