Rigidity based formation tracking for multi-agent networks

doi:10.1088/1674-1056/24/9/090206

Abstract

This paper considers the formation tracking problem under a rigidity framework, where the target formation is specified as a minimally and infinitesimally rigid formation and the desired velocity of the group is available to only a subset of the agents. The following two cases are considered: the desired velocity is constant, and the desired velocity is time-varying. In the first case, a distributed linear estimator is constructed for each agent to estimate the desired velocity. The velocity estimation and a formation acquisition term are employed to design the control inputs for the agents, where the rigidity matrix plays a central role. In the second case, a distributed non-smooth estimator is constructed to estimate the time-varying velocity, which is shown to converge in a finite time. Theoretical analysis shows that the formation tracking problem can be solved under the proposed control algorithms and estimators. Simulation results are also provided to show the validity of the derived results.

Keywords: multi-agent system formation control graph rigidity distributed estimator

Received: 25 January 2015
Revised: 12 March 2015
Accepted manuscript online:

PACS:	02.30.Yy	(Control theory)
	07.05.Dz	(Control systems)
	02.10.Ox	(Combinatorics; graph theory)

Fund:

Project supported by the National Natural Science Foundation of China (Grant No. 61473240).

Corresponding Authors: Chen Fei
E-mail: feichen@xmu.edu.cn

Cite this article:

Bai Lu (白璐), Chen Fei (陈飞), Lan Wei-Yao (兰维瑶) Rigidity based formation tracking for multi-agent networks 2015 Chin. Phys. B 24 090206

[1]	Anderson B D O, Yu C, Fidan B and Hendrickx J 2008 IEEE Contr.Syst. Mag. 28 48
[2]	Chen F, Chen Z, Xiang L Y, Liu Z and Yuan Z 2009 Automatica 45 1215
[3]	Su H, Chen M Z Q, Wang X and Lam J 2014 IEEE T. Ind. Electron. 61 2842
[4]	Ji L and Liao X 2013 Chin. Phys. B 22 040203
[5]	Bai L, Chen F and Lan W 2014 Proceedings of 2014 Chinese Control Conference, July 28-30, 2014, Nanjing, China, p. 1288
[6]	Oh K K and Ahn H S 2011 Automatica 47 2306
[7]	Cai X and de Queiroz M 2013 Proceedings of the IEEE American Control Conference, June 17-19, 2013, Washington, DC, USA, p. 2521
[8]	Cao Y, Ren W and Meng Z 2010 Syst. Control Lett. 59 522
[9]	Chen F, Cao Y and Ren W 2012 IEEE T. Automat. Contr. 57 3169
[10]	Reza O S 2006 IEEE T. Automat. Contr. 51 401
[11]	Su H, Wang X and Lin Z 2009 IEEE T. Automat. Contr. 54 293
[12]	Wang X, Li X and Zhang Z 2013 Control and Decision 11 001
[13]	Wen L, Zailani S and Fernando Y 2009 J. Technol. Manage. Innovation 4 1
[14]	Cao M, Morse A, Yu C, Anderson B and Dasgupta S 2011 Communications in Information and Systems 11 1
[15]	Dörfler F and Francis B 2009 Proceedings of the 2009 European Control Conference, 2009, Budapest, Hungary, p. 2432
[16]	Mei J, Ren W and Ma G 2011 IEEE T. Automat. Contr. 56 1415
[17]	Oh K K and Ahn H S 2011 Proceedings of IEEE International Symposium on Intelligent Control, September 28-30, 2011, Denver, USA, p. 816
[18]	Gazi V and Passino K M 2011 Swarm Stability and Optimization (Berlin Heidelberg: Springer)
[19]	Luo X, Han N and Guan X 2010 Chin. Phys. B 19 100202
[20]	Wen G, Duan Z, Ren W and Chen G 2014 Int. J. Robust. Nonlinear Control 24 2438
[21]	Khalil H K 2002 Nonlinear Systems, 3rd edn. (New Jersey: Prentice Hall)
[22]	Bernuau E, Polyakov A, Efimov D and Perruquetti W 2013 Joint SSSC, TDS, FDA, Feberuary 2013, Grenoble, France, hal-00745673

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