Stability of nonlinear neutral stochastic functional differential equations.
Stability of retarded systems with slowly varying coefficient
The “freezing” method for ordinary differential equations is extended to multivariable retarded systems with distributed delays and slowly varying coefficients. Explicit stability conditions are derived. The main tool of the paper is a combined usage of the generalized Bohl-Perron principle and norm estimates for the fundamental solutions of the considered equations.
Stability of retarded systems with slowly varying coefficient
The “freezing” method for ordinary differential equations is extended to multivariable retarded systems with distributed delays and slowly varying coefficients. Explicit stability conditions are derived. The main tool of the paper is a combined usage of the generalized Bohl-Perron principle and norm estimates for the fundamental solutions of the considered equations.
Stability of simple periodic solutions of neutral functional differential equations.
Stability of solutions for nonlinear nonautonomous differential-delay equations in Hilbert spaces.
Stability of solutions to delay differential equations with periodic coefficients of linear terms.
Stability of suspension bridge. I: Aerodynamic and structural damping.
Stability on a cone in terms of two measures for differential equations with “maxima”.
Stability processes of moving invariant manifolds in uncertain impulsive differential-difference equations
We present a result on the stability of moving invariant manifolds of nonlinear uncertain impulsive differential-difference equations. The result is obtained by means of piecewise continuous Lyapunov functions and a comparison principle.
Stability results for cellular neural networks with delays.
Stability switches for some class of delayed population models
We study stability switches for some class of delay differential equations with one discrete delay. We describe and use a simple method of checking the change of stability which originally comes from the paper of Cook and Driessche (1986). We explain this method on the examples of three types of prey-predator models with delay and compare the dynamics of these models under increasing delay.
Stability theorems for nonlinear functional differential equations
Stabilization of linear continuous time-varying systems with state delays in Hilbert spaces.
Stabilization of solutions to a differential-delay equation in a Banach space
A parameter dependent nonlinear differential-delay equation in a Banach space is investigated. It is shown that if at the critical value of the parameter the problem satisfies a condition of linearized stability then the problem exhibits a stability which is uniform with respect to the whole range of the parameter values. The general theorem is applied to a diffusion system with applications in biology.
Stable periodic solutions in scalar periodic differential delay equations
A class of nonlinear simple form differential delay equations with a -periodic coefficient and a constant delay is considered. It is shown that for an arbitrary value of the period , for some , there is an equation in the class such that it possesses an asymptotically stable -period solution. The periodic solutions are constructed explicitly for the piecewise constant nonlinearities and the periodic coefficients involved, by reduction of the problem to one-dimensional maps. The periodic solutions...
Stage-structured impulsive model for pest management.
Stochastic stability of Cohen-Grossberg neural networks with unbounded distributed delays.
Strict stability criteria for impulsive functional differential systems.
Structured polynomial eigenproblems related to time-delay systems.
Study of Stability in Nonlinear Neutral Differential Equations with Variable Delay Using Krasnoselskii–Burton’s Fixed Point
In this paper, we use a modification of Krasnoselskii’s fixed point theorem introduced by Burton (see [Burton, T. A.: Liapunov functionals, fixed points and stability by Krasnoseskii’s theorem. Nonlinear Stud., 9 (2002), 181–190.] Theorem 3) to obtain stability results of the zero solution of the totally nonlinear neutral differential equation with variable delay The stability of the zero solution of this eqution provided that . The Caratheodory condition is used for the functions and .