Stability and Hopf Bifurcation Analysis of a Phytoplankton-Zooplankton Model Under Temperature Factor and Stage-Structure Population of Phytoplankton

JST: Engineering and Technology for Sustainable Development Pub Date : 2023-11-15 DOI:10.51316/jst.170.etsd.2023.33.5.7

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Abstract

In the paper, we built a predator-prey model to simulate and study the dynamics of zooplankton and phytoplankton populations under the temperature impact, in which the stage structure is considered in the zooplankton population. Our model is an ordinary differential system of three nonlinear equations with some parameters as temperature-dependent functions and uses the generalized Holling response function. The non-negative and boundedness of the model solutions have been proven. The behaviors of our system are shown by the local stability conditions of the equilibria, especially the co-existence case. The stage transformation of zooplankton was studied through the Hopf bifurcation results of varying the temperature. The analysis and simulation results indicate that the ideal temperature for the co-existence is about 12-21 degrees Celsius. The zooplankton's transformation decreases when the temperature increases, leading to an imbalance in the system. Besides that, we also provided simulation figures to illustrate the found theoretical results.

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温度因子和浮游植物阶段结构种群下浮游植物-浮游动物模型的稳定性和Hopf分岔分析

本文建立了捕食-食饵模型，模拟研究了温度影响下浮游动物和浮游植物种群的动态变化，该模型考虑了浮游动物种群的阶段结构。我们的模型是一个由三个非线性方程组成的常微分系统，其中一些参数作为温度相关函数，并使用广义Holling响应函数。证明了模型解的非负性和有界性。系统的行为用平衡点的局部稳定条件来表示，特别是在共存情况下。通过温度变化的Hopf分岔结果，研究了浮游动物的阶段转化。分析和模拟结果表明，两者共存的理想温度约为12 ~ 21℃。当温度升高时，浮游动物的转化减少，导致系统失衡。此外，我们还提供了仿真图来说明所发现的理论结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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JST: Engineering and Technology for Sustainable Development

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