The periodic solutions for general periodic impulsive population systems of functional differential equations and its applications

Teng, Zhidong; Nie, Lin-Fei; Fang, Xining

doi:10.1016/j.camwa.2011.03.023

Cited by 15 publications

(9 citation statements)

References 44 publications

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“…As a consequence of Theorems 4 and 5, we have the following necessary and sufficient conditions on the global attractivity of periodic solution .u 10 .t/, u 20 .t/, 0/ and the permanence of species for model (3.1). Further, from the main results given Theorem 1 in [30] on the existence of periodic solutions for the general periodic impulsive differential equations, as consequence of Corollary 2, we have the following result.…”

Section: Remarkmentioning

confidence: 65%

“…Further, from the main results given Theorem 1 in on the existence of periodic solutions for the general periodic impulsive differential equations, as consequence of Corollary , we have the following result.Corollary Model has at least one positive τ ‐periodic solution

(x_{1}^{*} (t), x_{2}^{*} (t), y^{*} (t))

\int_{0}^{τ} ((), - d + cϕ ((), k_{1} u_{10}^{*} (t))) dt > 0 .

Proof From Corollary , we know that if holds, then model is permanent. Therefore, from Theorem 1 in , if an impulsive differential system is permanent, then there must exist at least one periodic solution. This completes the proof of Corollary .…”

Section: Resultsmentioning

confidence: 85%

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The dynamical behavior of a predator–prey system with Gompertz growth function and impulsive dispersal of prey between two patches

Zhang

Teng

2015

Math Methods in App Sciences

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In this paper, we investigate a predator-prey model with Gompertz growth function and impulsive dispersal of prey between two patches. Using the dynamical properties of single-species model with impulsive dispersal in two patches and comparison principle of impulsive differential equations, necessary and sufficient criteria on global attractivity of predator-extinction periodic solution and permanence are established. Finally, a numerical example is given to illustrate the theoretical results.

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Section: Remarkmentioning

confidence: 65%

(x_{1}^{*} (t), x_{2}^{*} (t), y^{*} (t))

\int_{0}^{τ} ((), - d + cϕ ((), k_{1} u_{10}^{*} (t))) dt > 0 .

Section: Resultsmentioning

confidence: 85%

The dynamical behavior of a predator–prey system with Gompertz growth function and impulsive dispersal of prey between two patches

Zhang

Teng

2015

Math Methods in App Sciences

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“…And the human activities always happen in a short time or instantaneously. Thus, the corresponding models are subject to short-term perturbations, which are often assumed to be in the form of impulsive in the modeling process, one can see [21][22][23][24][25][26][27][28][29][30][31][32] and the references therein.…”

Section: Introductionmentioning

confidence: 99%

Extinction and persistence of a nonautonomous stochastic food-chain system with impulsive perturbations

2016

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In this paper, a nonautonomous stochastic food-chain system with functional response and impulsive perturbations is studied. By using Itô's formula, exponential martingale inequality, differential inequality and other mathematical skills, some sufficient conditions for the extinction, nonpersistence in the mean, persistence in the mean, and stochastic permanence of the system are established. Furthermore, some asymptotic properties of the solutions are also investigated. Finally, a series of numerical examples are presented to support the theoretical results, and effects of different intensities of white noises perturbations and impulsive effects are discussed by the simulations.

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“…Applying Theorem 1 given in [16], it is clear that when condition (33) holds, model (1) at least has one positive -periodic solution.…”

Section: Remark 12mentioning

confidence: 99%

“…The discontinuity of human activities and the abrupt variation in the amount of the pest population, which occurs immediately after successful control measures (such as spraying pesticides, releasing natural enemies of the pest, and freeing infective pest individuals), may be described mathematically through making use of impulsive differential equations (see [5][6][7][8][9][10][11][12][13][14][15][16]). …”

Section: Introductionmentioning

confidence: 99%

Dynamic Analysis of General Integrated Pest Management Model with Double Impulsive Control

Teng

Wang

et al. 2015

Discrete Dynamics in Nature and Society

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A general predator-prey model with disease in the prey and double impulsive control is proposed and investigated for the purpose of integrated pest management. By using the Floquet theory, the comparison theorem of impulsive differential equations, and the persistence theory of dynamical systems, we obtain that if threshold value 0 < 1, then the susceptible pest eradication periodic solution is globally asymptotically stable and if 0 > 1, then the model is permanent. The numerical examples not only illustrate the theoretical results, but also show that when the model is permanent, then it may possess a unique globally attractive -periodic solution.

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The periodic solutions for general periodic impulsive population systems of functional differential equations and its applications

Cited by 15 publications

References 44 publications

The dynamical behavior of a predator–prey system with Gompertz growth function and impulsive dispersal of prey between two patches

The dynamical behavior of a predator–prey system with Gompertz growth function and impulsive dispersal of prey between two patches

Extinction and persistence of a nonautonomous stochastic food-chain system with impulsive perturbations

Dynamic Analysis of General Integrated Pest Management Model with Double Impulsive Control

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