Structural sensitivity in the functional responses of predator–prey models

IF 3.1 3区 环境科学与生态学 Q2 ECOLOGY
Sarah K. Wyse , Maria M. Martignoni , May Anne Mata , Eric Foxall , Rebecca C. Tyson
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引用次数: 3

Abstract

In mathematical modelling, several different functional forms can often be used to fit a data set equally well, especially if the data is sparse. In such cases, these mathematically different but similar looking functional forms are typically considered interchangeable. Recent work, however, shows that similar functional responses may nonetheless result in significantly different bifurcation points for the Rosenzweig–MacArthur predator–prey system. Since the bifurcation behaviours include destabilizing oscillations, predicting the occurrence of such behaviours is clearly important. Ecologically, different bifurcation behaviours mean that different predictions may be obtained from the models. These predictions can range from stable coexistence to the extinction of both species, so obtaining more accurate predictions is also clearly important for conservationists. Mathematically, this difference in bifurcation structure given similar functional responses is called structural sensitivity. We extend the existing work to find that the Leslie–Gower–May predator–prey system is also structurally sensitive to the functional response. Using the Rosenzweig–MacArthur and Leslie–Gower–May models, we then aim to determine if there is some way to obtain a functional description of data so that different functional responses yield the same bifurcation structure, i.e., we aim to describe data such that our model is not structurally sensitive. We first add stochasticity to the functional responses and find that better similarity of the resulting bifurcation structures is achieved. Then, we analyse the functional responses using two different methods to determine which part of each function contributes most to the observed bifurcation behaviour. We find that prey densities around the coexistence steady state are most important in defining the functional response. Lastly, we propose a procedure for ecologists and mathematical modellers to increase the accuracy of model predictions in predator–prey systems.

捕食者-猎物模型功能反应中的结构敏感性
在数学建模中,通常可以使用几种不同的函数形式来很好地拟合数据集,特别是在数据稀疏的情况下。在这种情况下,这些数学上不同但看起来相似的函数形式通常被认为是可互换的。然而,最近的研究表明,相似的功能反应可能会导致Rosenzweig-MacArthur捕食者-猎物系统的显著不同的分岔点。由于分岔行为包括不稳定振荡,因此预测这种行为的发生显然是重要的。在生态学上,不同的分岔行为意味着从模型中可以得到不同的预测。这些预测的范围从稳定共存到两个物种的灭绝,因此获得更准确的预测对保护主义者来说显然也很重要。数学上,在相似的功能响应下,这种分叉结构的差异被称为结构灵敏度。我们扩展了已有的工作,发现Leslie-Gower-May捕食者-猎物系统在结构上也对功能反应敏感。使用罗森茨韦格-麦克阿瑟和莱斯利-高尔-梅模型,我们的目标是确定是否有某种方法来获得数据的功能描述,以便不同的功能响应产生相同的分岔结构,即,我们的目标是描述数据,使我们的模型在结构上不敏感。我们首先在功能响应中加入随机性,并发现得到的分岔结构具有更好的相似性。然后,我们使用两种不同的方法分析功能响应,以确定每个功能的哪一部分对观察到的分岔行为贡献最大。我们发现,在共存稳态附近的猎物密度是定义功能响应的最重要因素。最后,我们为生态学家和数学建模者提出了一个程序,以提高模型预测在捕食者-猎物系统中的准确性。
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来源期刊
Ecological Complexity
Ecological Complexity 环境科学-生态学
CiteScore
7.10
自引率
0.00%
发文量
24
审稿时长
3 months
期刊介绍: Ecological Complexity is an international journal devoted to the publication of high quality, peer-reviewed articles on all aspects of biocomplexity in the environment, theoretical ecology, and special issues on topics of current interest. The scope of the journal is wide and interdisciplinary with an integrated and quantitative approach. The journal particularly encourages submission of papers that integrate natural and social processes at appropriately broad spatio-temporal scales. Ecological Complexity will publish research into the following areas: • All aspects of biocomplexity in the environment and theoretical ecology • Ecosystems and biospheres as complex adaptive systems • Self-organization of spatially extended ecosystems • Emergent properties and structures of complex ecosystems • Ecological pattern formation in space and time • The role of biophysical constraints and evolutionary attractors on species assemblages • Ecological scaling (scale invariance, scale covariance and across scale dynamics), allometry, and hierarchy theory • Ecological topology and networks • Studies towards an ecology of complex systems • Complex systems approaches for the study of dynamic human-environment interactions • Using knowledge of nonlinear phenomena to better guide policy development for adaptation strategies and mitigation to environmental change • New tools and methods for studying ecological complexity
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