We introduce a novel approach to exploit mixed precision arithmetic for low-rank approximations. Our approach is based on the observation that singular vectors associated with small singular values can be stored in lower precisions while preserving high accuracy overall. We provide an explicit criterion to determine which level of precision is needed for each singular vector. We apply this approach to block low-rank (BLR) matrices, most of whose off-diagonal blocks have low rank. We propose a new BLR LU factorization algorithm that exploits the mixed precision representation of the blocks. We carry out the rounding error analysis of this algorithm and prove that the use of mixed precision arithmetic does not compromise the numerical stabili...
In this paper we present an algorithm for computing a low rank approximation of a sparse matrix base...
International audienceThe standard LU factorization-based solution process for linear systems can be...
The calculation of a low-rank approximation to a matrix is fundamental to many algorithms in compute...
International audienceWe introduce a novel approach to exploit mixed precision arithmetic for low-ra...
We consider the LU factorization of an $n\times n$ matrix $A$ represented as a block low-rank (BLR) ...
We consider the LU factorization of an $n\times n$ matrix $A$ represented as a block low-rank (BLR) ...
International audiencen this paper we present an algorithm for computing a low rank approximation of...
Today's floating-point arithmetic landscape is broader than ever. While scientific computing has tra...
The available error bounds for randomized algorithms for computing a low rank approximation to a ma...
Motivated by the demand in machine learning, modern computer hardware is increas- ingly supporting r...
The development of randomized algorithms for numerical linear algebra, e.g. for computing approximat...
We present a new mixed precision algorithm to compute low-rank matrix and tensor approximations, a f...
We consider ill-conditioned linear systems $Ax =$ b that are to be solved iteratively, and assume t...
In this paper we present an algorithm for computing a low rank approximation of a sparse matrix base...
International audienceThe standard LU factorization-based solution process for linear systems can be...
The calculation of a low-rank approximation to a matrix is fundamental to many algorithms in compute...
International audienceWe introduce a novel approach to exploit mixed precision arithmetic for low-ra...
We consider the LU factorization of an $n\times n$ matrix $A$ represented as a block low-rank (BLR) ...
We consider the LU factorization of an $n\times n$ matrix $A$ represented as a block low-rank (BLR) ...
International audiencen this paper we present an algorithm for computing a low rank approximation of...
Today's floating-point arithmetic landscape is broader than ever. While scientific computing has tra...
The available error bounds for randomized algorithms for computing a low rank approximation to a ma...
Motivated by the demand in machine learning, modern computer hardware is increas- ingly supporting r...
The development of randomized algorithms for numerical linear algebra, e.g. for computing approximat...
We present a new mixed precision algorithm to compute low-rank matrix and tensor approximations, a f...
We consider ill-conditioned linear systems $Ax =$ b that are to be solved iteratively, and assume t...
In this paper we present an algorithm for computing a low rank approximation of a sparse matrix base...
International audienceThe standard LU factorization-based solution process for linear systems can be...
The calculation of a low-rank approximation to a matrix is fundamental to many algorithms in compute...