To speed-up the solution of parametrized differential problems, reduced order models (ROMs) have been developed over the years, including projection-based ROMs such as the reduced-basis (RB) method, deep learning-based ROMs, as well as surrogate models obtained through machine learning techniques. Thanks to its physics-based structure, ensured by the use of a Galerkin projection of the full order model (FOM) onto a linear low-dimensional subspace, the Galerkin-RB method yields approximations that fulfill the differential problem at hand. However, to make the assembling of the ROM independent of the FOM dimension, intrusive and expensive hyper-reduction techniques, such as the discrete empirical interpolation method (DEIM), are usually requi...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
This work formulates a new approach to reduced modeling of parameterized, time-dependent partial dif...
We present a Reduced Order Model (ROM) which exploits recent developments in Physics Informed Neural...
To speed-up the solution of parametrized differential problems, reduced order models (ROMs) have bee...
Deep learning-based reduced order models (DL-ROMs) have been recently proposed to overcome common li...
We develop a non-intrusive reduced basis (RB) method for parametrized steady-state partial different...
A reduced basis method based on a physics-informed machine learning framework is developed for effic...
We derive upper bounds on the complexity of ReLU neural networks approximating the solution maps of ...
In this paper, we propose a network model, the multiclass classification-based reduced order model (...
We propose a non-intrusive deep learning-based reduced order model (DL-ROM) capable of capturing the...
Parametric time-dependent systems are of a crucial importance in modeling real phenomena, often char...
We propose a nonlinear reduced basis method for the efficient approximation of parametrized partial ...
We present a novel reduced order model (ROM) approach for parameterized time-dependent PDEs based on...
Models with dominant advection always posed a difficult challenge for projection-based reduced order...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
This work formulates a new approach to reduced modeling of parameterized, time-dependent partial dif...
We present a Reduced Order Model (ROM) which exploits recent developments in Physics Informed Neural...
To speed-up the solution of parametrized differential problems, reduced order models (ROMs) have bee...
Deep learning-based reduced order models (DL-ROMs) have been recently proposed to overcome common li...
We develop a non-intrusive reduced basis (RB) method for parametrized steady-state partial different...
A reduced basis method based on a physics-informed machine learning framework is developed for effic...
We derive upper bounds on the complexity of ReLU neural networks approximating the solution maps of ...
In this paper, we propose a network model, the multiclass classification-based reduced order model (...
We propose a non-intrusive deep learning-based reduced order model (DL-ROM) capable of capturing the...
Parametric time-dependent systems are of a crucial importance in modeling real phenomena, often char...
We propose a nonlinear reduced basis method for the efficient approximation of parametrized partial ...
We present a novel reduced order model (ROM) approach for parameterized time-dependent PDEs based on...
Models with dominant advection always posed a difficult challenge for projection-based reduced order...
Although projection-based reduced-order models (ROMs) for parameterized nonlinear dynamical systems ...
This work formulates a new approach to reduced modeling of parameterized, time-dependent partial dif...
We present a Reduced Order Model (ROM) which exploits recent developments in Physics Informed Neural...