Mobile Robot Networks for Environmental Monitoring: A Cooperative Receding Horizon Temporal Logic Control Approach

被引：0

作者：

Lu Q. ^{[1
]}

Han Q.-L. ^{[2
]}

机构：

[1] School of Automation, Hangzhou Dianzi University, Hangzhou

[2] School of Software and Electrical Engineering, Swinburne University of Technology, Melbourne, 3122, VIC

来源：

IEEE Transactions on Cybernetics | 2019年 / 49卷 / 02期

基金：

澳大利亚研究理事会;

关键词：

Cooperative control; environmental monitoring; linear temporal logic (LTL); mobile robot networks; receding horizon control (RHC);

D O I：

10.1109/TCYB.2018.2879905Y

中图分类号：

学科分类号：

摘要：

This paper deals with the problem of environmental monitoring by designing and analyzing a cooperative receding horizon temporal logic (CRH-TL) control approach for mobile robot networks. First, a radial basis function network is used to model the distribution of environmental attributes in the monitored environment. On the basis of the established environment model, the problem of environmental monitoring can be formulated as a dynamical optimization problem. Second, an acceptable node set is obtained by enforcing appropriate constraints from linear temporal logic (LTL) specifications on the task of environmental monitoring. Third, by designing a cooperative energy function and using the acceptable node set, the CRH-TL control approach is proposed to generate the movement trajectory of each robot, which satisfies the given LTL specifications while guiding mobile robot networks to trace the peaks of environmental attributes. Finally, the effectiveness of the proposed CRH-TL control approach is illustrated for the problem of environmental monitoring. © 2013 IEEE.

引用

页码：698 / 711

页数：13

共 50 条

[1]

Atanasov N.A., Ny J.L., Pappas G.J., Distributed algorithms for stochastic source seeking with mobile robot networks, J. Dyn. Syst. Meas. Control, 137, 3, pp. 1011-1020, (2015)

[2]

Azuma S., Sakar M.S., Pappas G.J., Stochastic source seeking by mobile robots, IEEE Trans. Autom. Control, 57, 9, pp. 2308-2321, (2012)

[3]

Baier C., Katoen J.-P., Principles of Model Checking, (2008)

[4]

Choi J., Oh S., Horowitz R., Distributed learning and cooperative control for multi-agent systems, Automatica, 45, 12, pp. 2802-2814, (2009)

[5]

Cortes J., Distributed kriged Kalman filter for spatial estimation, IEEE Trans. Autom. Control, 54, 12, pp. 2816-2827, (2009)

[6]

Dimarogonas D.V., Johansson K.H., Further results on the stability of distance-based multi-robot formations, Proc. Amer. Control Conf., pp. 2972-2977, (2009)

[7]

Ding L., Han Q.-L., Ge X., Zhang X.-M., An overview of recent advances in event-triggered consensus of multiagent systems, IEEE Trans. Cybern., 48, 4, pp. 1110-1123, (2018)

[8]

Ding L., Han Q.-L., Guo G., Network-based leader-following consensus for distributed multi-agent systems, Automatica, 49, 7, pp. 2281-2286, (2013)

[9]

Ding X., Lazar M., Belta C., LTL receding horizon control for finite deterministic systems, Automatica, 50, 2, pp. 399-408, (2014)

[10]

Dunbar W.B., Murray R.M., Distributed receding horizon control for multi-vehicle formation stabilization, Automatica, 42, 4, pp. 549-558, (2006)

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