AbstractThe study of high-dimensional differential equations is challenging and difficult due to the analytical and computational intractability. Here, we improve the speed of waveform relaxation (WR), a method to simulate high-dimensional differential-algebraic equations. This new method termed adaptive waveform relaxation (AWR) is tested on a communication network example. Further, we propose different heuristics for computing graph partitions tailored to adaptive waveform relaxation. We find that AWR coupled with appropriate graph partitioning methods provides a speedup by a factor between 3 and 16
The authors develop a new class of waveform relaxation algorithms for large systems of ordinary diff...
We apply a Runge-Kutta-based waveform relaxation method to initial-value problems for implicit diffe...
The traditional approach for solving large dynamical systems is time consuming. Waveform method, an ...
This paper introduces a parallel algorithm to solve large stiff ODE systems on distributed clusters,...
International audienceThis paper introduces a parallel algorithm to solve large stiff ODE systems on...
Waveform relaxation is a numerical method for solving large-scale systems of ordinary differential e...
This thesis reports the continuing effort towards establishing a parallel numerical algorithm known ...
An extension of the waveform relaxation (WR) algorithm to systems of differential/algebraic equation...
Waveform relaxation (WR) is a technique which can be used to solve large systems of ordinary differe...
Multiprocessor architecture machines offer promising opportunities to achieve significant speedup in...
Abstract: This paper surveys the family of Waveform Relaxation Methods for solving large systems of ...
AbstractWe are interested in solving linear time-dependent index one differential algebraic equation...
It is the purpose of this paper to provide an acceleration of waveform relaxation (WR) methods for ...
This paper presents a fast algorithm for transient simulation of power grids in VLSI systems using w...
We investigate the concurrent solution of low-index differential-algebraic equations (DAE’s) b...
The authors develop a new class of waveform relaxation algorithms for large systems of ordinary diff...
We apply a Runge-Kutta-based waveform relaxation method to initial-value problems for implicit diffe...
The traditional approach for solving large dynamical systems is time consuming. Waveform method, an ...
This paper introduces a parallel algorithm to solve large stiff ODE systems on distributed clusters,...
International audienceThis paper introduces a parallel algorithm to solve large stiff ODE systems on...
Waveform relaxation is a numerical method for solving large-scale systems of ordinary differential e...
This thesis reports the continuing effort towards establishing a parallel numerical algorithm known ...
An extension of the waveform relaxation (WR) algorithm to systems of differential/algebraic equation...
Waveform relaxation (WR) is a technique which can be used to solve large systems of ordinary differe...
Multiprocessor architecture machines offer promising opportunities to achieve significant speedup in...
Abstract: This paper surveys the family of Waveform Relaxation Methods for solving large systems of ...
AbstractWe are interested in solving linear time-dependent index one differential algebraic equation...
It is the purpose of this paper to provide an acceleration of waveform relaxation (WR) methods for ...
This paper presents a fast algorithm for transient simulation of power grids in VLSI systems using w...
We investigate the concurrent solution of low-index differential-algebraic equations (DAE’s) b...
The authors develop a new class of waveform relaxation algorithms for large systems of ordinary diff...
We apply a Runge-Kutta-based waveform relaxation method to initial-value problems for implicit diffe...
The traditional approach for solving large dynamical systems is time consuming. Waveform method, an ...