Dynamical systems modeling for structural understanding of social-ecological systems: A primer

IF 3.1 3区 环境科学与生态学 Q2 ECOLOGY
Sonja Radosavljevic , Thomas Banitz , Volker Grimm , Lars-Göran Johansson , Emilie Lindkvist , Maja Schlüter , Petri Ylikoski
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引用次数: 0

Abstract

Dynamical systems modeling (DSM) explores how a system evolves in time when its elements and the relationships between them are known. The basic idea is that the structure of a dynamical system, expressed by coupled differential or difference equations, determines attractors of the system and, in turn, its behavior. This leads to structural understanding that can provide insights into qualitative properties of real systems, including ecological and social-ecological systems (SES). DSM generally does not aim to make specific quantitative predictions or explain singular events, but to investigate consequences of different assumptions about a system's structure. SES dynamics and possible causal relationships in SES get revealed through manipulation of individual interactions and observation of their consequences. Structural understanding is therefore particularly valuable for assessing and anticipating the consequences of interventions or shocks and managing transformation toward sustainability. Taking into account social and ecological dynamics, recognizing that SES may operate on different time scales simultaneously and that achieving an attractor might not be possible or relevant, opens up possibilities for DSM setup and analysis. This also highlights the importance of assumptions and research questions for model results and calls for closer connection between modeling and empirics. Understanding the potential and limitations of DSM in SES research is important because the well-developed and established framework of DSM provides a common language and helps break down barriers to shared understanding and dialog within multidisciplinary teams. In this primer we introduce the basic concepts, methods, and possible insights from DSM. Our target audience are both beginners in DSM and modelers who use other model types, both in ecology and SES research.

社会生态系统结构理解的动力系统建模:入门
动态系统建模(DSM)探索了当系统的元素及其之间的关系已知时,系统如何在时间上进化。其基本思想是,由耦合微分方程或差分方程表示的动力系统的结构决定了系统的吸引子,进而决定了其行为。这导致了结构理解,可以深入了解真实系统的定性特性,包括生态和社会生态系统(SES)。DSM通常不旨在做出具体的定量预测或解释奇异事件,而是研究对系统结构的不同假设的后果。通过对个体互动的操纵和对其后果的观察,揭示了SES的动态和可能的因果关系。因此,结构理解对于评估和预测干预或冲击的后果以及管理向可持续性的转变尤其有价值。考虑到社会和生态动态,认识到SES可能同时在不同的时间尺度上运行,并且实现吸引器可能不可能或不相关,为DSM的建立和分析开辟了可能性。这也突出了假设和研究问题对模型结果的重要性,并呼吁在建模和经验之间建立更紧密的联系。了解需求侧管理在SES研究中的潜力和局限性很重要,因为开发和建立的需求侧管理框架提供了一种通用语言,有助于打破多学科团队内部共享理解和对话的障碍。在这篇初级读本中,我们介绍了DSM的基本概念、方法和可能的见解。我们的目标受众既有DSM的初学者,也有在生态学和SES研究中使用其他模型类型的建模师。
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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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