We consider the application of symmetric Boundary Value Methods to linear autonomous Hamiltonian systems. The numerical approximation of the Hamiltonian function exhibits a superconvergence property, namely its order of convergence is p + 2 for a p order symmetric method. We exploit this result to define a natural projection procedure that slightly modifies the numerical solution so that, without changing the convergence properties of the numerical method, it provides orbits lying on the same quadratic manifold as the continuous ones. A numerical test is also reported
This talk investigates the canonical properties of general linear methods for long time integration ...
In this paper numerical methods for solving linear Hamiltonian systems are proposed. These schemes a...
It is the purpose of this talk to analyze the employ of General Linear Methods (GLMs) for the numeri...
We consider the application of symmetric Boundary Value Methods to linear autonomous Hamiltonian sys...
We consider the application of symmetric Boundary Value Methods to linear autonomous Hamiltonian sys...
Given a Hamiltonian matrix H = JS with S symmetric and positive definite, we analyze a symplectic La...
One main issue, when numerically integrating autonomous Hamiltonian systems, is the long-term conser...
One main issue, when numerically integrating autonomous Hamiltonian systems, is the long-term conser...
This work aims to present a structure-preserving block Lanczos-like method. The Lanczos-like algorit...
It is important, when integrating numerically Hamiltonian problems, that the numerical methods retai...
AbstractLarge sparse Hamiltonian eigenvalue problems arise in a variety of contexts. These problems ...
This paper is concerned with the numerical solution of Hamiltonian problems, by means of nearly cons...
AbstractIt is important, when integrating numerically Hamiltonian problems, that the numerical metho...
AbstractWe discuss a Krylov–Schur like restarting technique applied within the symplectic Lanczos al...
We analyse the behaviour of symmetric boundary value methods applied to Hamiltonian evolutionary pro...
This talk investigates the canonical properties of general linear methods for long time integration ...
In this paper numerical methods for solving linear Hamiltonian systems are proposed. These schemes a...
It is the purpose of this talk to analyze the employ of General Linear Methods (GLMs) for the numeri...
We consider the application of symmetric Boundary Value Methods to linear autonomous Hamiltonian sys...
We consider the application of symmetric Boundary Value Methods to linear autonomous Hamiltonian sys...
Given a Hamiltonian matrix H = JS with S symmetric and positive definite, we analyze a symplectic La...
One main issue, when numerically integrating autonomous Hamiltonian systems, is the long-term conser...
One main issue, when numerically integrating autonomous Hamiltonian systems, is the long-term conser...
This work aims to present a structure-preserving block Lanczos-like method. The Lanczos-like algorit...
It is important, when integrating numerically Hamiltonian problems, that the numerical methods retai...
AbstractLarge sparse Hamiltonian eigenvalue problems arise in a variety of contexts. These problems ...
This paper is concerned with the numerical solution of Hamiltonian problems, by means of nearly cons...
AbstractIt is important, when integrating numerically Hamiltonian problems, that the numerical metho...
AbstractWe discuss a Krylov–Schur like restarting technique applied within the symplectic Lanczos al...
We analyse the behaviour of symmetric boundary value methods applied to Hamiltonian evolutionary pro...
This talk investigates the canonical properties of general linear methods for long time integration ...
In this paper numerical methods for solving linear Hamiltonian systems are proposed. These schemes a...
It is the purpose of this talk to analyze the employ of General Linear Methods (GLMs) for the numeri...