We consider a non-autonomous ordinary differential equation over a finite time interval [T1; T2]. The area of exponential attraction consists of solutions such that the distance to adjacent solutions exponentially contracts from T1 to T2. One can use a contraction metric to determine an area of exponential attraction and to provide a bound on the rate of attraction. In this paper, we will give the first method to algorithmically construct a contraction metric for finite-time systems in one spatial dimension. We will show the existence of a contraction metric, given by a function which satisfies a second-order partial differential equation with boundary conditions. We then use meshless collocation to approximately solve this equation, and sh...
We consider a nonautonomous ordinary differential equation of the form x ̇ = f(t,x), x ∈ Rn over a f...
Contraction analysis considers the distance between two adjacent trajectories. If this distance is c...
The stability and basin of attraction of an equilibrium can be determined by a contraction metric. ...
A contraction metric for an autonomous ordinary differential equation is a Riemannian metric such th...
A contraction metric for an autonomous ordinary differential equation is a Riemannian metric such th...
Contraction analysis uses a local criterion to prove the long-term behaviour of a dynamical system. ...
The determination of exponentially stable equilibria and their basin of attraction for a dynamical s...
AbstractIn this article, new concepts of (exponential) attractivity for nonautonomous differential e...
This work is focused on the approximation of sets of attractive solutions of planar dynamical system...
Contraction analysis uses a local criterion to prove the long-term behaviour of a dynamical system. ...
Exponentially stable periodic orbits of ordinary differential equations and their basins' of attract...
Girod A, Hüls T. On areas of attraction and repulsion in finite time dynamical systems and their num...
Numerical methods to determine the basin of attraction for autonomous equations focus on a bounded s...
Abstract. We suggest in this article a new explicit algorithm allowing to construct exponential attr...
We study the stability of invariant sets such as equilibria or periodic orbits of a Dynamical System...
We consider a nonautonomous ordinary differential equation of the form x ̇ = f(t,x), x ∈ Rn over a f...
Contraction analysis considers the distance between two adjacent trajectories. If this distance is c...
The stability and basin of attraction of an equilibrium can be determined by a contraction metric. ...
A contraction metric for an autonomous ordinary differential equation is a Riemannian metric such th...
A contraction metric for an autonomous ordinary differential equation is a Riemannian metric such th...
Contraction analysis uses a local criterion to prove the long-term behaviour of a dynamical system. ...
The determination of exponentially stable equilibria and their basin of attraction for a dynamical s...
AbstractIn this article, new concepts of (exponential) attractivity for nonautonomous differential e...
This work is focused on the approximation of sets of attractive solutions of planar dynamical system...
Contraction analysis uses a local criterion to prove the long-term behaviour of a dynamical system. ...
Exponentially stable periodic orbits of ordinary differential equations and their basins' of attract...
Girod A, Hüls T. On areas of attraction and repulsion in finite time dynamical systems and their num...
Numerical methods to determine the basin of attraction for autonomous equations focus on a bounded s...
Abstract. We suggest in this article a new explicit algorithm allowing to construct exponential attr...
We study the stability of invariant sets such as equilibria or periodic orbits of a Dynamical System...
We consider a nonautonomous ordinary differential equation of the form x ̇ = f(t,x), x ∈ Rn over a f...
Contraction analysis considers the distance between two adjacent trajectories. If this distance is c...
The stability and basin of attraction of an equilibrium can be determined by a contraction metric. ...