This work is concerned with the development of an adaptive space-time numerical method, based on a rigorous a posteriori error bound, for the semilinear heat equation with a general local Lipschitz reaction term whose solution may blow-up in finite time. More specifically, conditional a posteriori error bounds are derived in the L∞L∞ norm for the first order (Euler) in time, implicit-explicit (IMEX), conforming finite element method in space discretization of the problem. Numerical experiments applied to both blow-up and non blow-up cases highlight the generality of our approach and complement the theoretical results
AbstractThis note deals with a class of heat emission processes in a medium with a non-negative sour...
In this paper we derive a posteriori error estimates for the heat equation. The time discretization ...
The question of blow-up of solutions to nonlinear parabolic equations and systems has received consi...
This work is concerned with the development of an adaptive space-time numerical method, based on a r...
This work is concerned with the development of a space-time adaptive numerical method, based on a ri...
This work is concerned with the development of a space-time adaptive numerical method, based on a ri...
We prove a posteriori error estimates for time discrete approximations, for semilinear parabolic equ...
In this paper, we study the numerical blow-up solutions and times of the semilinear heat equation wi...
Blow up in a one-dimensional semilinear heat equation is studied using a combination of numerical an...
We consider the blow-up of the solution to a semilinear heat equation with nonlinear boundary condit...
We prove a posteriori error estimates for time discrete approximations, for semilinear parabolic equ...
We consider the semilinear Heat equation with a gradient term, which takes the form....... The full ...
We prove an above and a below differential inequality for the solutions of semilinear heat equation....
22 pagesInternational audienceWe derive a posteriori error estimates for the discretization of the h...
This Chapter aims to investigate the error estimation of numerical approximation to a class of semil...
AbstractThis note deals with a class of heat emission processes in a medium with a non-negative sour...
In this paper we derive a posteriori error estimates for the heat equation. The time discretization ...
The question of blow-up of solutions to nonlinear parabolic equations and systems has received consi...
This work is concerned with the development of an adaptive space-time numerical method, based on a r...
This work is concerned with the development of a space-time adaptive numerical method, based on a ri...
This work is concerned with the development of a space-time adaptive numerical method, based on a ri...
We prove a posteriori error estimates for time discrete approximations, for semilinear parabolic equ...
In this paper, we study the numerical blow-up solutions and times of the semilinear heat equation wi...
Blow up in a one-dimensional semilinear heat equation is studied using a combination of numerical an...
We consider the blow-up of the solution to a semilinear heat equation with nonlinear boundary condit...
We prove a posteriori error estimates for time discrete approximations, for semilinear parabolic equ...
We consider the semilinear Heat equation with a gradient term, which takes the form....... The full ...
We prove an above and a below differential inequality for the solutions of semilinear heat equation....
22 pagesInternational audienceWe derive a posteriori error estimates for the discretization of the h...
This Chapter aims to investigate the error estimation of numerical approximation to a class of semil...
AbstractThis note deals with a class of heat emission processes in a medium with a non-negative sour...
In this paper we derive a posteriori error estimates for the heat equation. The time discretization ...
The question of blow-up of solutions to nonlinear parabolic equations and systems has received consi...