AbstractA data-flow approach is used to solve dense symmetric systems of equations on a torus-connected 2-D mesh of processors. A torus mapping of the matrix onto this processor array allows the Cholesky decomposition to be completed in 3n − 2 time steps using only n2/4 processors (less than half the number needed in previously reported results). New definitions for missized problems and parallel algorithm performance are given along with various time-step, efficiency, and processor utilization plots
We consider the problem of subsystem allocation in the mesh, torus, and hypercube multicomputers. Al...
A SIMD scheme for parallelization of the 2-D array operation M(x) = (D×A + B×I + V) x is developed f...
For the solution of symmetric linear systems, the classical Cholesky method has proved to be difficu...
AbstractA data-flow approach is used to solve dense symmetric systems of equations on a torus-connec...
In this article the authors develop some algorithms and tools for solving matrix problems on paralle...
Dense linear systems of equations are quite common in science and engineering, arising in boundary e...
An algorithm to solve the eigenproblem for non-symmetric matrices on an $N \times N$ array of mesh ...
The bottleneck of most data analyzing systems, signal processing systems, and intensive computing sy...
Abstract. A style for programming problems from matrix algebra is developed with a familiar example ...
As sequential computers seem to be approaching their limits in CPU speed there is increasing intere...
Let A, B be two arbitrary mnnn , matrices. We present a parallel algorithm to solve the dense line...
In this paper we present a new parallel algorithm for computing the Cholesky decomposition (LL^T) of...
New massively parallel computer architecture has revolutionized the design of computer algorithms an...
Abstract. A parallel algorithm is presented for triangular system solving on a distributed-memory MI...
We describe a parallel algorithm for finding the Cholesky factorization of a sparse symmetric posit...
We consider the problem of subsystem allocation in the mesh, torus, and hypercube multicomputers. Al...
A SIMD scheme for parallelization of the 2-D array operation M(x) = (D×A + B×I + V) x is developed f...
For the solution of symmetric linear systems, the classical Cholesky method has proved to be difficu...
AbstractA data-flow approach is used to solve dense symmetric systems of equations on a torus-connec...
In this article the authors develop some algorithms and tools for solving matrix problems on paralle...
Dense linear systems of equations are quite common in science and engineering, arising in boundary e...
An algorithm to solve the eigenproblem for non-symmetric matrices on an $N \times N$ array of mesh ...
The bottleneck of most data analyzing systems, signal processing systems, and intensive computing sy...
Abstract. A style for programming problems from matrix algebra is developed with a familiar example ...
As sequential computers seem to be approaching their limits in CPU speed there is increasing intere...
Let A, B be two arbitrary mnnn , matrices. We present a parallel algorithm to solve the dense line...
In this paper we present a new parallel algorithm for computing the Cholesky decomposition (LL^T) of...
New massively parallel computer architecture has revolutionized the design of computer algorithms an...
Abstract. A parallel algorithm is presented for triangular system solving on a distributed-memory MI...
We describe a parallel algorithm for finding the Cholesky factorization of a sparse symmetric posit...
We consider the problem of subsystem allocation in the mesh, torus, and hypercube multicomputers. Al...
A SIMD scheme for parallelization of the 2-D array operation M(x) = (D×A + B×I + V) x is developed f...
For the solution of symmetric linear systems, the classical Cholesky method has proved to be difficu...