We consider model order reduction of parameterized Hamiltonian systems describing nondissipative phenomena, like wave-type and transport dominated problems. The development of reduced basis methods for such models is challenged by two main factors: the rich geometric structure encoding the physical and stability properties of the dynamics and its local low-rank nature. To address these aspects, we propose a nonlinear structure-preserving model reduction where the reduced phase space evolves in time. In the spirit of dynamical low-rank approximation, the reduced dynamics is obtained by a symplectic projection of the Hamiltonian vector field onto the tangent space of the approximation manifold at each reduced state. A priori error estimates a...
In this paper we propose a dynamical low-rank strategy for the approximation of second order wave eq...
Abstract. This work proposes a model-reduction methodology that preserves Lagrangian structure (equi...
It is shown that by use of the Kalman-decomposition an uncontrollable and/or unobservable port-Hamil...
We consider model order reduction of parameterized Hamiltonian systems describing nondissipative phe...
We consider model order reduction of parameterized Hamiltonian systems describing nondissipative phe...
This work proposes an adaptive structure-preserving model order reduction method for finite-dimensio...
While reduced-order models (ROMs) are popular for approximately solving large systems of differentia...
Model order reduction provides low-complexity high-fidelity surrogate models that allow rapid and ac...
We develop structure-preserving reduced basis methods for a large class of nondissipative problems b...
This work presents two novel approaches for the symplectic model reduction of high-dimensional Hamil...
Large-scale dynamical systems are expensive to simulate due to the computational cost accrued y the ...
Numerical simulation of parametrized differential equations is of crucial importance in the study of...
The goal of this work is to demonstrate that a specific projection-based model reduction method, whi...
The reduction of Hamiltonian systems aims to build smaller reduced models, valid over a certain rang...
In this paper we propose a dynamical low-rank strategy for the approximation of second order wave eq...
Abstract. This work proposes a model-reduction methodology that preserves Lagrangian structure (equi...
It is shown that by use of the Kalman-decomposition an uncontrollable and/or unobservable port-Hamil...
We consider model order reduction of parameterized Hamiltonian systems describing nondissipative phe...
We consider model order reduction of parameterized Hamiltonian systems describing nondissipative phe...
This work proposes an adaptive structure-preserving model order reduction method for finite-dimensio...
While reduced-order models (ROMs) are popular for approximately solving large systems of differentia...
Model order reduction provides low-complexity high-fidelity surrogate models that allow rapid and ac...
We develop structure-preserving reduced basis methods for a large class of nondissipative problems b...
This work presents two novel approaches for the symplectic model reduction of high-dimensional Hamil...
Large-scale dynamical systems are expensive to simulate due to the computational cost accrued y the ...
Numerical simulation of parametrized differential equations is of crucial importance in the study of...
The goal of this work is to demonstrate that a specific projection-based model reduction method, whi...
The reduction of Hamiltonian systems aims to build smaller reduced models, valid over a certain rang...
In this paper we propose a dynamical low-rank strategy for the approximation of second order wave eq...
Abstract. This work proposes a model-reduction methodology that preserves Lagrangian structure (equi...
It is shown that by use of the Kalman-decomposition an uncontrollable and/or unobservable port-Hamil...