Communication-aware coverage control for robotic sensor networks

53rd IEEE Conference on Decision and Control Pub Date : 2014-12-01 DOI:10.1109/CDC.2014.7040467

Y. Kantaros, M. Zavlanos

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引用次数: 23

Abstract

The purpose of this paper is to propose a control scheme to maximize area coverage and at the same time ensure reliable communication in networks of mobile robot sensors. The information that is generated at the sensors depends on the sensing capabilities of the sensors as well as on the frequency at which events occur in their vicinity, captured by appropriate probability density functions. This information is then routed to a fixed set of access points via a multi-hop network whose links model the probability that information packets are correctly decoded at their intended destinations. The proposed hybrid controller simultaneously optimizes coverage and routing of information by decoupling control in the continuous and discrete domains. The robots' motion is performed in continuous time, along the negative gradient of a cost function that combines the coverage objective and a barrier potential used to ensure satisfaction of desired communication rates. On the other hand, the communication variables are updated periodically, in discrete time, by the solution of an optimization problem, and constitute the switching signal in the continuous motion control. Simulation studies are conducted verifying the efficiency of the proposed algorithm.

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机器人传感器网络的通信感知覆盖控制

本文的目的是提出一种控制方案，使移动机器人传感器网络的覆盖面积最大化，同时保证网络通信的可靠性。传感器产生的信息取决于传感器的传感能力以及事件在其附近发生的频率，并由适当的概率密度函数捕获。然后将该信息通过多跳网络路由到一组固定的接入点，该网络的链路模拟信息包在其预定目的地被正确解码的概率。该混合控制器通过解耦控制在连续域和离散域同时优化信息的覆盖和路由。机器人的运动在连续时间内，沿着成本函数的负梯度进行，该函数结合了覆盖目标和用于确保满足期望通信速率的障碍势。另一方面，通过求解优化问题，在离散时间内周期性地更新通信变量，构成连续运动控制中的开关信号。仿真研究验证了所提算法的有效性。

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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53rd IEEE Conference on Decision and Control

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