AbstractIn this paper we study a class of nonlinear dissipative partial differential equations that have inertial manifolds. This means that the long-time behavior is equivalent to a certain finite system of ordinary differential equations. We investigate ways in which these finite systems can be approximated in theC1sense. Geometrically this may be interpreted as constructing manifolds in phase space that areC1close to the inertial manifold of the partial differential equation. Under such approximations the invariant hyperbolic sets of the global attractor persist
We show that results concerning the persistence of invariant sets of ordinary differential equations...
We derive a numerical scheme to compute invariant manifolds for time-variant discrete dynamical syst...
Abstract. This paper discusses two numerical schemes that can be used to approximate inertial manifo...
AbstractIn this paper we study a class of nonlinear dissipative partial differential equations that ...
A class of nonlinear dissipative partial differential equations that possess finite dimensional attr...
AbstractIn this paper we introduce the concept of an inertial manifold for nonlinear evolutionary eq...
AbstractIn a previous work, we established the existence of finite dimensional attractors for partly...
AbstractRecently, the theory of Inertial Manifolds has shown that the long time behavior (the dynami...
In this article the numerical analysis of dissipative semilinear evolution equations with sectorial ...
ABSTRACT. For nonlinear parabolic evolution equations, it is proved that, under the assumptions oflo...
High- and infinite-dimensional nonlinear dynamical systems often exhibit complicated flow (spatiote...
AbstractWe show that results concerning the persistence of invariant sets of ordinary differential e...
AbstractThe concept of approximate inertial manifold is related to the study of the longtime behavio...
For nonlinear parabolic evolution equations, it is proved that, under the assumptions of local Lipsc...
For nonlinear parabolic evolution equations, it is proved that, under the assumptions of local Lipsc...
We show that results concerning the persistence of invariant sets of ordinary differential equations...
We derive a numerical scheme to compute invariant manifolds for time-variant discrete dynamical syst...
Abstract. This paper discusses two numerical schemes that can be used to approximate inertial manifo...
AbstractIn this paper we study a class of nonlinear dissipative partial differential equations that ...
A class of nonlinear dissipative partial differential equations that possess finite dimensional attr...
AbstractIn this paper we introduce the concept of an inertial manifold for nonlinear evolutionary eq...
AbstractIn a previous work, we established the existence of finite dimensional attractors for partly...
AbstractRecently, the theory of Inertial Manifolds has shown that the long time behavior (the dynami...
In this article the numerical analysis of dissipative semilinear evolution equations with sectorial ...
ABSTRACT. For nonlinear parabolic evolution equations, it is proved that, under the assumptions oflo...
High- and infinite-dimensional nonlinear dynamical systems often exhibit complicated flow (spatiote...
AbstractWe show that results concerning the persistence of invariant sets of ordinary differential e...
AbstractThe concept of approximate inertial manifold is related to the study of the longtime behavio...
For nonlinear parabolic evolution equations, it is proved that, under the assumptions of local Lipsc...
For nonlinear parabolic evolution equations, it is proved that, under the assumptions of local Lipsc...
We show that results concerning the persistence of invariant sets of ordinary differential equations...
We derive a numerical scheme to compute invariant manifolds for time-variant discrete dynamical syst...
Abstract. This paper discusses two numerical schemes that can be used to approximate inertial manifo...