季节性浮游生物繁殖的离散时间模型

G. P. Neverova, O. Zhdanova, A. Abakumov
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引用次数: 5

摘要

在模拟浮游植物华流方面,最有趣的结果是基于对浮游植物和浮游动物相互作用的经典系统的修改而得到的。使用延迟方程的修改,以及对中毒过程具有延迟响应的分段连续函数,使得获得像自然界一样足够的浮游植物动力学成为可能。本文建立了一个由两个离散时间方程组成的浮游植物-浮游动物群落动态模型。我们使用循环方程,它允许自然地描述响应的延迟。所提出的模型考虑了浮游植物毒性和与浮游植物毒性相关的浮游动物反应。我们使用Verhulst模型的离散模拟来描述自调节过程下群落中每个物种的动态。我们使用考虑捕食者饱和度的Holling-II型响应函数来描述浮游植物密度因被浮游动物消耗而下降。浮游动物的生长和存活率也取决于它们的摄食。由于浮游动物密度高,有毒物质浓度增加所引起的浮游动物死亡率也包括在限制过程中。对所提出的模型进行了分析和数值研究。分析表明,浮游植物和浮游动物共存所对应的非平凡不动点的稳定性损失可以通过一连串的周期加倍分岔发生,并根据neimmark - saker情景导致准周期波动的出现。提出的浮游植物和浮游动物群落动态模型允许观测长周期振荡,这与野外实验结果一致。同时,该模型具有多稳定区,在所有模型参数不变的情况下,初始条件的变化会导致当前动态模式的改变。
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Discrete-Time Model of Seasonal Plankton Bloom
The most interesting results in modeling phytoplankton bloom were obtained based on a modification of the classical system of phytoplankton and zooplankton interaction. The modifications using delayed equations, as well as piecewise continuous functions with a delayed response to intoxication processes, made it possible to obtain adequate phytoplankton dynamics like in nature. This work develops a dynamic model of phytoplankton-zooplankton community consisting of two equations with discrete time. We use recurrent equations, which allows to describe delay in response naturally. The proposed model takes into account the phytoplankton toxicity and zooplankton response associated with phytoplankton toxicity. We use a discrete analogue of the Verhulst model to describe the dynamics of each of the species in the community under autoregulation processes. We use Holling-II type response function taking into account predator saturation to describe decrease in phytoplankton density due to its consumption by zooplankton. Growth and survival rates of zooplankton also depend on its feeding. Zooplankton mortality, caused by an increase in the toxic substances concentration with high density of zooplankton, is included in the limiting processes. An analytical and numerical study of the model proposed is made. The analysis shows that the stability loss of nontrivial fixed point corresponding to the coexistence of phytoplankton and zooplankton can occur through a cascade of period doubling bifurcations and according to the Neimark-Saker scenario leading to the appearance of quasiperiodic fluctuations as well. The proposed dynamic model of the phytoplankton and zooplankton community allows observing long-period oscillations, which is consistent with the results of field experiments. As well, the model have multistability areas, where a variation in initial conditions with the unchanged values of all model parameters can result in a shift of the current dynamic mode.
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来源期刊
Mathematical Biology and Bioinformatics
Mathematical Biology and Bioinformatics Mathematics-Applied Mathematics
CiteScore
1.10
自引率
0.00%
发文量
13
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