Low-rank matrices arise in many scientific and engineering computations. Both computational and storage costs of manipulating such matrices may be reduced by taking advantages of their low-rank properties. To compute a low-rank approximation of a dense matrix, in this paper, we study the performance of QR factorization with column pivoting or with restricted pivoting on multicore CPUs with a GPU. We first propose several techniques to reduce the postprocessing time, which is required for restricted pivoting, on a modern CPU. We then examine the potential of using a GPU to accelerate the factorization process with both column and restricted pivoting. Our performance results on two eight-core Intel Sandy Bridge CPUs with one NVIDIA Kepler GPU...
to appearInternational audienceA wide class of numerical methods needs to solve a linear system, whe...
AbstractLinear least squares problems are commonly solved by QR factorization. When multiple solutio...
Abstract: Few realize that, for large matrices, many dense matrix computations achieve nearly the sa...
AbstractOne-sided dense matrix factorizations are important computational kernels in many scientific...
International audienceThis paper studies the performance of different algorithms for solving a dense...
QR decomposition is a computationally intensive linear al-gebra operation that factors a matrix A in...
For many finite element problems, when represented as sparse matrices, iterative solvers are found t...
Parallelizing the LU factorization of sparse Jacobian matrices reduces the execution time of the pow...
AbstractWe study several solvers for the solution of general linear systems where the main objective...
Linear least squares problems are commonly solved by QR factorization. When multiple solutions have ...
We study several solvers for the solution of general linear systems where the main objective is to r...
The solution of dense systems of linear equations is at the heart of numerical computations. Such sy...
International audienceWe present a new sparse linear solver for GPUs. It is designed to work with st...
The least squares problem is an extremely useful device to represent an approximate solution to over...
Sparse solver has become the bottleneck of SPICE simulators. There has been few work on GPU-based sp...
to appearInternational audienceA wide class of numerical methods needs to solve a linear system, whe...
AbstractLinear least squares problems are commonly solved by QR factorization. When multiple solutio...
Abstract: Few realize that, for large matrices, many dense matrix computations achieve nearly the sa...
AbstractOne-sided dense matrix factorizations are important computational kernels in many scientific...
International audienceThis paper studies the performance of different algorithms for solving a dense...
QR decomposition is a computationally intensive linear al-gebra operation that factors a matrix A in...
For many finite element problems, when represented as sparse matrices, iterative solvers are found t...
Parallelizing the LU factorization of sparse Jacobian matrices reduces the execution time of the pow...
AbstractWe study several solvers for the solution of general linear systems where the main objective...
Linear least squares problems are commonly solved by QR factorization. When multiple solutions have ...
We study several solvers for the solution of general linear systems where the main objective is to r...
The solution of dense systems of linear equations is at the heart of numerical computations. Such sy...
International audienceWe present a new sparse linear solver for GPUs. It is designed to work with st...
The least squares problem is an extremely useful device to represent an approximate solution to over...
Sparse solver has become the bottleneck of SPICE simulators. There has been few work on GPU-based sp...
to appearInternational audienceA wide class of numerical methods needs to solve a linear system, whe...
AbstractLinear least squares problems are commonly solved by QR factorization. When multiple solutio...
Abstract: Few realize that, for large matrices, many dense matrix computations achieve nearly the sa...