A novel time integration scheme is presented for the numerical solution of the dynamics of discrete systems consisting of point masses and thermo-visco-elastic springs. Even considering fully coupled constitutive laws for the elements, the obtained solutions strictly preserve the two laws of thermo dynamics and the symmetries of the continuum evolution equations. Moreover, the unconditional control over the energy and the entropy growth have the effect of stabilizing the numerical solution, allowing the use of larger time steps than those suitable for comparable implicit algorithms. Proofs for these claims are provided in the article as well as numerical examples that illustrate the performance of the method
The dynamics of elastic solids and structures defines classical Hamiltonian systems with a very rich...
This paper presents a novel Smooth Particle Hydrodynamics computational framework for the simulation...
International audienceIn a previous paper [L. Noels, L. Stainier, J.-P. Ponthot, An energy momentum ...
A novel time integration scheme is presented for the numerical solution of the dynamics of discrete ...
This work is concerned with the numerical solution of the evolution equations of thermomechanical sy...
International audienceThe aim of this paper is the design a new one-step implicit and thermodynamica...
Esta tesis aborda la formulación, análisis e implementación de métodos numéricos de integración tem...
The present contribution aims at the consistent discretisation of nonlinear, coupled thermoelectro-e...
The aim of this paper is the design a new one-step implicit and thermodynamically consistent Ene...
It is now well established that discrete energy conservation/dissipation plays a key-role for the un...
The aim of this paper is the design of a new one-step implicit and thermodynamically consistentEnerg...
The present work addresses the design of structure-preserving numerical methods that emanate from th...
In the present contribution structure-preserving numerical methods for finite strain thermoelastodyn...
In a previous paper [L. Noels, L. Stainier, J.-P. Ponthot, An energy momentum conserving algorithm u...
Large‐strain thermo‐viscoelasticity is described in the framework of GENERIC. To this end, a new mat...
The dynamics of elastic solids and structures defines classical Hamiltonian systems with a very rich...
This paper presents a novel Smooth Particle Hydrodynamics computational framework for the simulation...
International audienceIn a previous paper [L. Noels, L. Stainier, J.-P. Ponthot, An energy momentum ...
A novel time integration scheme is presented for the numerical solution of the dynamics of discrete ...
This work is concerned with the numerical solution of the evolution equations of thermomechanical sy...
International audienceThe aim of this paper is the design a new one-step implicit and thermodynamica...
Esta tesis aborda la formulación, análisis e implementación de métodos numéricos de integración tem...
The present contribution aims at the consistent discretisation of nonlinear, coupled thermoelectro-e...
The aim of this paper is the design a new one-step implicit and thermodynamically consistent Ene...
It is now well established that discrete energy conservation/dissipation plays a key-role for the un...
The aim of this paper is the design of a new one-step implicit and thermodynamically consistentEnerg...
The present work addresses the design of structure-preserving numerical methods that emanate from th...
In the present contribution structure-preserving numerical methods for finite strain thermoelastodyn...
In a previous paper [L. Noels, L. Stainier, J.-P. Ponthot, An energy momentum conserving algorithm u...
Large‐strain thermo‐viscoelasticity is described in the framework of GENERIC. To this end, a new mat...
The dynamics of elastic solids and structures defines classical Hamiltonian systems with a very rich...
This paper presents a novel Smooth Particle Hydrodynamics computational framework for the simulation...
International audienceIn a previous paper [L. Noels, L. Stainier, J.-P. Ponthot, An energy momentum ...