Scalable second-order consensus of hierarchical groups

IF 2.5 3区计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS Systems & Control Letters Pub Date : 2025-03-01 Epub Date: 2025-02-04 DOI:10.1016/j.sysconle.2025.106032

Jiamin Wang , Jian Liu , Feng Xiao , Ning Xi , Lipo Mo , Yuanshi Zheng

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Abstract

Motivated by widespread dominance hierarchy, variations of group sizes, and feedback mechanisms in social species, we are devoted to exploring the scalable second-order consensus of hierarchical groups. More specifically, a hierarchical group consists of a collection of agents with double-integrator dynamics on a directed acyclic graph with additional reverse edges, which characterize feedback mechanisms across hierarchical layers. As the group size varies and the reverse edges appear, we investigate whether the absolute velocity protocol and the relative velocity protocol can preserve the system consensus property without tuning the control gains. It is rigorously proved that the absolute velocity protocol is able to achieve completely scalable second-order consensus but the relative velocity protocol cannot. This result theoretically reveals how the scalable coordination behavior in hierarchical groups is determined by local interaction rules. Moreover, we find a hierarchical structure in order to achieve scalable second-order consensus for networks of any size and with any number of reverse edges.

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层次群的可伸缩二阶一致性

受社会物种中普遍存在的优势等级、群体规模变化和反馈机制的影响，我们致力于探索等级群体中可扩展的二阶共识。更具体地说，一个层次群由有向无环图上具有双积分器动态的代理集合组成，这些代理具有附加的逆边，它们表征了跨层次层的反馈机制。在群体大小变化和反向边出现的情况下，研究了绝对速度协议和相对速度协议在不调整控制增益的情况下是否能保持系统的一致性。严格证明了绝对速度协议能够实现完全可扩展的二阶共识，而相对速度协议则不能。这一结果从理论上揭示了层次群体中可扩展协调行为是如何由局部交互规则决定的。此外，我们发现了一种层次结构，以便对任何规模和任何数量的反向边的网络实现可扩展的二阶共识。

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来源期刊

Systems & Control Letters 工程技术-运筹学与管理科学

CiteScore

4.60

自引率

3.80%

发文量

144

审稿时长

6 months

期刊介绍： Founded in 1981 by two of the pre-eminent control theorists, Roger Brockett and Jan Willems, Systems & Control Letters is one of the leading journals in the field of control theory. The aim of the journal is to allow dissemination of relatively concise but highly original contributions whose high initial quality enables a relatively rapid review process. All aspects of the fields of systems and control are covered, especially mathematically-oriented and theoretical papers that have a clear relevance to engineering, physical and biological sciences, and even economics. Application-oriented papers with sophisticated and rigorous mathematical elements are also welcome.