Add to ORKGWe make more realistic our model [Nonlinear Anal. 73(2010), 650–659] on the coexistence of fishes and plants in Lake Tanganyika. The new model is an asymptotically autonomous system whose limiting equation is a Lotka–Volterra system. We give conditions for the phenomenon that the trajectory of any solution of the original nonautonomous system “rolls up” onto a cycle of the limiting Lotka–Volterra equation as t → ∞, which means that the limit set of the solution of the non-autonomous system coincides with the cycle. A counterexample is constructed showing that the key integral condition on the coefficient function in the original non-autonomous model cannot be dropped. Computer simulations illustrate the results
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Lotka-Volterra systems are the canonical ecological models used to analyze population dynamics of co...
In this paper we study in detail the geometrical structure of global pullback and forwards attracto...
AbstractThe goal of this work is to study in some detail the asymptotic behaviour of a non-autonomou...
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AbstractIn this paper we study in detail the geometrical structure of global pullback and forwards a...
It is well-known that the Lotka–Volterra predator-prey model has a family of periodic orbits, but do...
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AbstractIn Ahmad and Stamova (2004) [1], the author considers a competitive Lotka–Volterra system of...
Abstract. Lotka-Volterra systems are the canonical ecological models used to analyze popula-tion dyn...
This paper deals with the following question: does the asymptotic stability of the positive equilibr...
We consider fast–slow planar systems of predator-prey models with the prey growing much faster than ...
The goal of this work is to study in some detail the asymptotic behaviour of a non-autonomous Lotka...
AbstractThis paper deals with a periodic reaction–diffusion system of plankton allelopathy under hom...
There has been a surge of interest in developing and analysing models of interacting species in ecos...
AbstractThe dynamics of a nonautonomous predator–prey system with the Beddington–DeAngelis functiona...
Lotka-Volterra systems are the canonical ecological models used to analyze population dynamics of co...
In this paper we study in detail the geometrical structure of global pullback and forwards attracto...
AbstractThe goal of this work is to study in some detail the asymptotic behaviour of a non-autonomou...
AbstractThis paper considers a Lotka–Volterra predator–prey model with predators receiving an enviro...
AbstractIn this paper we study in detail the geometrical structure of global pullback and forwards a...
It is well-known that the Lotka–Volterra predator-prey model has a family of periodic orbits, but do...
AbstractIn this paper, we consider an autonomous predator–prey Lotka–Volterra system in which indivi...
AbstractIn Ahmad and Stamova (2004) [1], the author considers a competitive Lotka–Volterra system of...
Abstract. Lotka-Volterra systems are the canonical ecological models used to analyze popula-tion dyn...
This paper deals with the following question: does the asymptotic stability of the positive equilibr...
We consider fast–slow planar systems of predator-prey models with the prey growing much faster than ...
The goal of this work is to study in some detail the asymptotic behaviour of a non-autonomous Lotka...
AbstractThis paper deals with a periodic reaction–diffusion system of plankton allelopathy under hom...
There has been a surge of interest in developing and analysing models of interacting species in ecos...
AbstractThe dynamics of a nonautonomous predator–prey system with the Beddington–DeAngelis functiona...