Authors: Xianqing Liu, Shouming Zhong, Lijiang Xiang

Abstract:

In this paper, a stochastic predator-prey system with Bedding-DeAngelis functional response is studied. By constructing a suitable Lyapunov founction, sufficient conditions for species to be stochastically permanent is established. Meanwhile, we show that the species will become extinct with probability one if the noise is sufficiently large.

Keywords: Stochastically permanent, extinct, white noise, Bedding-DeAngelis functional response.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1337103

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References:

[1] M. Liu and K. Wang, Global stability of a nonlinear stochastic predatorprey system with Beddington-DeAngelis functional response, Commun. Nonlinear Sci. Numer. Simulat, 2011, 16, 1114-1121.
[2] C. Ji, D. Q. Jiang and X. Li, Qualitative analysis of a stochastic ratiodependent predator-prey system, Journal of Computational and Applied Mathematics, 2011, 235, 1326-1341.
[3] J. Lv and K. Wang, Asymptotic properties of a stochastic predator-prey system with Holling II functional response, Commun Nonlinear Sci Numer Simulat, 2011, 16, 4037-4048.
[4] D. Q. Jiang, N. Shi and X. Li, Global stability and stochastic permanence of a non-autonomous logistic equation with random perturbation, J. Math. Anal. Appl, 2008, 340, 588-597.
[5] C. Ji, D. Q. Jiang and N. Jiang, Analysis of a predator-prey model with modified Leslie-Gower and Holling-type II schemes with stochastic perturbation, J Math Anal Appl, 2009, 359, 482-498.
[6] Z. Xing, J. Peng, Boundedness, persistence and extinction of a stochastic non-autonomous logistic system with time delays, Applied Mathematical Modelling, 2012, 36, 3379C3386.
[7] M. Liu and K. Wang, Extinction and permanence in a stochastic nonautonomous population system, Applied Mathematics Letters, 2010, 23, 1464C1467.
[8] M. Liu and K. Wang, Global asymptotic stability of a stochastic LotkaCVolterra model with infinite delays, Commun Nonlinear Sci Numer Simulat, 2012, 17, 3115C3123.
[9] M. Liu and K. Wang, On a stochastic logistic equation with impulsive perturbations, Computers and Mathematics with Applications, 2012, 63, 871C886.
[10] C. Zhu and G. Yin, On competitive LotkaCVolterra model in random environments, J. Math. Anal. Appl., 2009, 357, 154C170.
[11] M. Liu and K. Wang, Persistence and extinction in stochastic nonautonomous logistic systems, J. Math. Anal. Appl., 2011, 375, 443C457.
[12] X. Liu, S. Zhong, B. Tian, F. Zheng, Asymptotic properties of a stochastic predator-prey model with Crowley-Martin functional response, Journal of Applied Mathematics and Computing (2013) doi:10.1007/s12190-013-0674-0.
[13] X. Liu, S. Zhong, F. Zhong, Z. Liu, Properties of a stochastic predatorprey system with Holling II functional response, Inter. J. Math. Sci., 2013, 7, 73-79.
[14] X. Li, X Mao. Population dynamical behavior of non-autonomous Lotka- Volterra competitive system with random perturbation. Discrete Contin Dyn Syst, 2009;24:523-545.