寄主-寄生蜂相互作用模型的种内密度依赖效应

Hua Liu
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引用次数: 1

摘要

本文通过计算机模拟定性地研究了寄主-拟寄主模型中寄主种内竞争的影响。观察到多种形式的复杂动力学,包括拟周期、Hopf分岔逆转和吸引子危机。此外,我们还得出密度相关效应可能是一个稳定因素。当宿主种内竞争增强时,持续稳定相互作用的参数区域增大。自然种群的规模不断变化,变化可大可小;有时是规则的,但大多数情况下是不规则的(1)-(4),因此自然种群的动态非常复杂(5),(6)。处理种群动态模型中的复杂性的研究领域是种群生态学的核心问题。特别是,这一领域的开创性工作是由May(7),(8)发起的。现在,与相互作用的种群动力学相比,单种群动力学理论已经得到了很好的理解。科学家们一直致力于研究世代不重叠的自然种群的种间相互作用,这种相互作用可以用差分方程来建模。差分方程描述了种群如何在离散时间步中进化,并且可以产生比连续时间模型中观察到的更丰富的动态模式(9)。科学家已经建立了许多数学模型来解释这些相互作用的动态行为。由于其固有的非线性,用定性方法分析其全局稳定性是不容易的,因此人们通常通过计算机模拟来研究宿主-寄生性模型的动态复杂性。对于不同的参数和初始条件,我们可以迭代差分方程数千个时间步,分析种群规模的时间序列,以阐明隐藏在种群动态背后的规律和机制。近年来,许多作者采用计算机模拟的方法来研究离散时间寄主-寄生物模型的复杂性。Kaitala和Heino(10)报道了宿主-寄生蜂与免疫和未免疫宿主相互作用的动态复杂性。Kaitala Ylikarjula和Heino (11), Tang和Chen(12)的研究表明,寄主-寄生蜂相互作用模型存在多种形式的复杂动力学,具有holling型功能响应。Xu和Boyce(13)也证明了相互干扰的宿主-寄生性模型的动态复杂性。这些研究都依靠Logistic生长函数来分析寄主-拟虫相互作用的动力学,并获得了一些有趣的结果。然而,所有这些研究都没有考虑到这些数学模型预测的动态之间的差异通常是非常好奇的,而实际数据的动态行为要简单得多。由于这种明显的差异,许多生态学家拒绝接受确定性数学模型的预测,而更愿意接受环境噪声作为主要驱动力。论文(14)的结论是Allee效应(一种种内相互作用)缓解了动态复杂性,增强了数学模型在种群探索中的实用性。本文将在文献(15)研究的基础上,广泛分析密度依赖的种群动态效应,如种内竞争。在下一节中,我们将首先提出宿主-寄生模型,并对所有参数和变量进行解释。然后,通过数值模拟对种群动态进行全面研究。最后,我们将对结果进行总结并进行简短的讨论。
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Intra-Specific Density Dependent Effect of a Host-Parasitoid Interaction Model
In this paper, the effect of intra-specific competition of host in a host-parasitoid model is investigated qualitatively by computer simulation. Many forms of complex dynamic are observed, including quasi-periodic, Hopf bifurcation reversal, and attractors crises. Furthermore, we obtain that the density- dependent effect may be a stabilizing factor. When hosts intra- specific competition stronger, the parameter region for persistent and stable interaction increases. I. INTRODUCTION The size of a natural population varies constantly and the variations may be small or large; sometimes regular, but in most cases irregular (1)-(4), so the dynamics of natural populations are very complicated (5), (6). The research area dealing with the complexities in the population dynamic models is the central issue in population ecology. In particular, the pioneering work in this field was initiated by May (7), (8). Now, the theory of single-population dynamics is quite well understood compared with the dynamics of interacting populations. Scientists have focused on studying interspecific interaction of natural populations whose generations are non- overlapping that can be modeled by difference equations. Difference equations describe how the population evolves in discrete time-step and can produce a much richer set of dynamic patterns than those observed in continuous-time models (9). Scientists have established many mathematical models to explain the dynamic behaviors of these interactions. It is not easy to analyze its global stability by qualitative method since the intrinsic nonlinearity, so people often study the dynamic complexity of host-parasitoid model by computer simulation. For different parameters and initial conditions, we can iterate the difference equations for thousands time steps and analyze the time series of population size to elucidate the regularity and mechanisms that hidden behind the population dynamics. Recently, many authors have adopted computer simulation to investigate the complexities of discrete-time host-parasitoid models. Kaitala and Heino (10) reported the dynamic com- plexity of host-parasitoid interaction with immunized and non- immunized host. Kaitala Ylikarjula and Heino (11), Tang and Chen (12) showed that many forms of complex dynam- ics were observed in host-parasitoid interaction model with Holling-type functional response. Xu and Boyce (13) also demonstrated the dynamic complexity of a mutual interference host-parasitoid model. All these research relied on a Logistic growth function to analyze the dyanmics of the host-parasitoid interaction and obtained some intriguing results. However, all these research are not to account for the discrepancy between dynamics predicted from these mathematical models is usually very intrigued and the dynamic behavior of real data is much simpler. Since this obvious discrepancy, many ecologists refused to accept the predictions from the deterministic mathematical models and prefer to accept environmental noise as the major driving force. In paper (14), the conclusion is that dynamic complexities are alleviated by Allee effect that is a kind of intra-specific interaction and have strengthened the utility of mathematical models in exploring populations. In this Paper, based on research of paper (15), the population dynamics effects by density dependent such as intra-specific competition will be extensively analyzed. In the next section, we will first propose the host-parasitoid model and give the explanation of all the parameters and variables. Then, the population dynamics will be fully investigated through numerical simulations. At last, we will conclude the results and give a short discussion.
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