Non-autonomous periodic systems with Allee effects

Luís, Rafael; Elaydi, Saber; Oliveira, Henrique M.

doi:10.1080/10236190902794951

Cited by 31 publications

(29 citation statements)

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“…Periodically forced population models exhibiting the Allee effect are relatively new in the literature [14,32,42]. In [32] several periodically forced discrete models exhibiting the Allee effect are studied, while a class of general unimodal maps with such properties has been investigated in [14].…”

Section: Introductionmentioning

confidence: 99%

Global behavior of solutions of a periodically forced Sigmoid Beverton–Holt model

Harry

Kent

Kocic

2012

Journal of Biological Dynamics

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Our aim in this paper is to investigate the boundedness, the extreme stability, and the periodicity of positive solutions of the periodically forced Sigmoid Beverton-Holt model:where {a n } is a positive periodic sequence with period p and δ > 0. In the special case when δ = 1, the above equation reduces to the well-known periodic Pielou logistic equation which is known to be equivalent to the periodically forced Beverton-Holt model.

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Section: Introductionmentioning

confidence: 99%

Global behavior of solutions of a periodically forced Sigmoid Beverton–Holt model

Harry

Kent

Kocic

2012

Journal of Biological Dynamics

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“…See [9] for a discussion of some new examples of models exhibiting the Allee effect and, similar to the Beverton-Holt model, having important biological quantities as parameters, for example, intrinsic growth rate, carrying capacity, Allee threshold, and a new parameter, the shock recovery parameter. Further references pertaining to the Allee effect can be found in [1,3,4,6,[10][11][12][16][17][18]23,26,31,32], and for references to the general theory of difference equations, see [7,20]. For a discussion on the use of the Sigmoid model, see [28, p. 82] In what follows, we show that under certain conditions on the coefficients, Equation (1) has an asymptotically stable p-periodic state and an unstable p-periodic Allee state.…”

Section: Introductionmentioning

confidence: 99%

Difference equations with the Allee effect and the periodic Sigmoid Beverton–Holt equation revisited

Gaut

Goldring

Grogan

et al. 2012

Journal of Biological Dynamics

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In this paper, we investigate the long-term behaviour of solutions of the periodic Sigmoid Beverton-Holt equationwhere the a n and δ n are p-periodic positive sequences. Under certain conditions, there are shown to exist an asymptotically stable p-periodic state and a p-periodic Allee state with the property that populations smaller than the Allee state are driven to extinction while populations greater than the Allee state approach the stable state, thus accounting for the long-term behaviour of all initial states. This appears to be the first study of the equation with variable δ. The results are discussed with possible interpretations in Population Dynamics with emphasis on fish populations and smooth cordgrass.

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“…The concept of a stable point of a function or dynamical system is considered in [15,16]. Obviously if x 0 is a stable point of f then x 0 is a fixed point of f (the set of all fixed points of f will be denoted by Fix( f )).…”

Section: -Approximate Stable Points Of a Functionmentioning

confidence: 99%

On Functions Attracting Positive Entropy

Loranty¹,

Pawlak²

2017

Bull. Aust. Math. Soc.

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We examine dynamical systems which are 'nonchaotic' on a big (in the sense of Lebesgue measure) set in each neighbourhood of a fixed point x 0 , that is, the entropy of this system is zero on a set for which x 0 is a density point. Considerations connected with this family of functions are linked with functions attracting positive entropy at x 0 , that is, each mapping sufficiently close to the function has positive entropy on each neighbourhood of x 0 .2010 Mathematics subject classification: primary 26A18; secondary 37B40, 54C70, 26A15.

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Non-autonomous periodic systems with Allee effects

Cited by 31 publications

References 20 publications

Global behavior of solutions of a periodically forced Sigmoid Beverton–Holt model

Global behavior of solutions of a periodically forced Sigmoid Beverton–Holt model

Difference equations with the Allee effect and the periodic Sigmoid Beverton–Holt equation revisited

On Functions Attracting Positive Entropy

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