Timer-Based Coverage Control for Mobile Sensors

IF 4 3区计算机科学 Q2 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Control of Network Systems Pub Date : 2025-01-07 DOI:10.1109/TCNS.2025.3526717

Federico M. Zegers;Sean Phillips;Gregory P. Hicks

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Abstract

This work investigates the coverage control problem over a static, compact, and convex workspace and develops a hybrid extension of the continuous-time Lloyd algorithm. Each agent in a multiagent system (MAS) is equipped with a timer mechanism that generates intermittent measurement and control update events, which may occur asynchronously between agents. Between consecutive event times, as determined by the corresponding timer mechanism, the controller of each agent is held constant. These controllers are shown to drive the configuration of the MAS into a neighborhood of the set of centroidal Voronoi configurations, i.e., the minimizers of the standard locational cost. The combination of continuous-time dynamics with intermittently updated control inputs is modeled as a hybrid system. The coverage objective is posed as a set attractivity problem for hybrid systems, where an invariance-based convergence analysis yields sufficient conditions that ensure maximal solutions of the hybrid system asymptotically converge to a desired set. A brief simulation example is included to showcase the result.

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基于定时器的移动传感器覆盖控制

这项工作研究了静态、紧凑和凸工作空间上的覆盖控制问题，并开发了连续时间劳埃德算法的混合扩展。在多智能体系统（MAS）中，每个智能体都配备了一个定时器机制，该定时器机制产生间歇性的测量和控制更新事件，这些事件可能在智能体之间异步发生。在连续的事件时间之间，由相应的计时器机制决定，每个代理的控制器保持不变。这些控制器将MAS的配置驱动到一组质心Voronoi配置的邻域，即标准位置成本的最小值。连续时间动力学与间歇更新控制输入的组合被建模为一个混合系统。将覆盖目标作为混合系统的集合吸引问题，通过基于不变性的收敛性分析，得到了保证混合系统最大解渐近收敛于期望集的充分条件。本文提供了一个简短的模拟示例来展示结果。

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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来源期刊

IEEE Transactions on Control of Network Systems Mathematics-Control and Optimization

CiteScore

7.80

自引率

7.10%

发文量

169

期刊介绍： The IEEE Transactions on Control of Network Systems is committed to the timely publication of high-impact papers at the intersection of control systems and network science. In particular, the journal addresses research on the analysis, design and implementation of networked control systems, as well as control over networks. Relevant work includes the full spectrum from basic research on control systems to the design of engineering solutions for automatic control of, and over, networks. The topics covered by this journal include: Coordinated control and estimation over networks, Control and computation over sensor networks, Control under communication constraints, Control and performance analysis issues that arise in the dynamics of networks used in application areas such as communications, computers, transportation, manufacturing, Web ranking and aggregation, social networks, biology, power systems, economics, Synchronization of activities across a controlled network, Stability analysis of controlled networks, Analysis of networks as hybrid dynamical systems.