复杂多智能体网络动力系统自适应中尺度控制新方法

Q3 Physics and Astronomy

Cybernetics and Physics Pub Date : 2022-12-30 DOI:10.35470/2226-4116-2022-11-4-175-189

K. Amelin, O. Granichin, A.V. Leonova, Vikentiy Pankov, Denis Uzhva, V. Erofeeva, Vladislav Ershov

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引用次数: 0

摘要

应用于大规模系统的集中式策略需要大量的计算和通信资源。与它们相比，分布式策略提供了更高的可伸缩性和可靠性。然而，agent之间的通信和协调对分布式控制系统的性能影响很大。现有的方法导致聚类，其中代理之间的协调仅限于要控制的实体组。这些群体的规模通常是事先知道的。反过来，许多系统表现出自组织，并动态地形成集群结构。从这个意义上说，控制方法应该适应这种动态结构，在性能和通信/计算需求之间提供相同的平衡。本文提出了一种基于高效聚类(介观)控制范式的复杂系统控制新方法。我们在一组代理应该达到某个目标的场景中证明了它的有效性。

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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A new method of adaptive mesoscale control in complex multiagent networked dynamical systems

Centralized strategies applied to large-scale systems require a vast amount of computational and communication resources. In contrast to them, distributed strategies offer higher scalability and reliability. However, communication and coordination among agents tremendously impact performance of systems controlled in the distributed manner. The existing methods lead to clustering, where the coordination between agents is limited to groups of entities to be controlled. The size of these groups are usually known in advance. In turn, many systems exhibit self-organization and dynamically form clustering structure. In that sense, control methods should adapt to such dynamic structures offering the same balance between performance and communication/computational demands. In this paper, we propose a new approach to complex system control based on efficient cluster (mesoscopic) control paradigm. We demonstrate its efficacy in scenarios, where a group of agents should reach a certain goal.

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来源期刊

Cybernetics and Physics Chemical Engineering-Fluid Flow and Transfer Processes

CiteScore

1.70

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： The scope of the journal includes: -Nonlinear dynamics and control -Complexity and self-organization -Control of oscillations -Control of chaos and bifurcations -Control in thermodynamics -Control of flows and turbulence -Information Physics -Cyber-physical systems -Modeling and identification of physical systems -Quantum information and control -Analysis and control of complex networks -Synchronization of systems and networks -Control of mechanical and micromechanical systems -Dynamics and control of plasma, beams, lasers, nanostructures -Applications of cybernetic methods in chemistry, biology, other natural sciences The papers in cybernetics with physical flavor as well as the papers in physics with cybernetic flavor are welcome. Cybernetics is assumed to include, in addition to control, such areas as estimation, filtering, optimization, identification, information theory, pattern recognition and other related areas.