ROBUST CLUSTER CONSENSUS OF GENERAL FRACTIONAL-ORDER NONLINEAR MULTI-AGENT SYSTEMS WITH DYNAMIC UNCERTAINTY, 165-170.

Zahra Yaghoubi and Heidar A. Talebi

References

1. [1] Z. Zhang, Y. Shi, Z. Zhang, and W. Yan, New results on sliding-mode control for Takagi–Sugeno fuzzy multiagent systems, IEEE Transactions on Cybernetics, 49, 2019, 1592–1604.
2. [2] Z. Zhang, Z. Zhang, and H. Zhang, Distributed attitude control for multispacecraft via Takagi–Sugeno fuzzy approach, IEEE Transactions on Aerospace and Electronic Systems, 54(2), 2018, 642–654.
3. [3] H. Wang, L. Ji and Z. Zhou, ESO-based consensus of multi-ple Euler–Lagrange systems under a fixed or switching topology, Mechatronic Systems and Control (formerly Control and Intelligent Systems), 45(2), 2017.
4. [4] Z. Yaghoubi and H.A. Talebi, Consensus tracking for nonlinear fractional-order multi agent systems using adaptive sliding mode controller, Mechatronic Systems and Control (formerly Control and Intelligent Systems), 47, 2019, 194–200.
5. [5] H. Li, Y. Shi, W. Yan, and F. Liu, Receding horizon consensus of general linear multi-agent systems with input constraints: An inverse optimality approach, Automatica, 91, 2018, 10–16.
6. [6] Z. Ma, Y. Wang, and X. Li, Cluster-delay consensus in first- order multi-agent systems with nonlinear dynamics, Nonlinear Dynamics, 83(3), 2016, 1303–1310.
7. [7] Y. Wang, Z. Ma, and G. Chen, Avoiding congestion in cluster consensus of the second-order nonlinear multiagent systems, IEEE Transactions on Neural Networks and Learning Systems, 29(8), 2018, 3490–3498.
8. [8] Z. Zuo, B. Tian, M. Defoort, and Z. Ding, Fixed-time consensus tracking for multiagent systems with high-order integrator dynamics, IEEE Transactions on Automatic Control, 63(2), 2018, 563–570. 169
9. [9] X. Liu, K. Zhang, and W.-C. Xie, Consensus of multi-agent systems via hybrid impulsive protocols with time-delay, Nonlinear Analysis: Hybrid Systems, 30, 2018, 134–146.
10. [10] R. Yang, S. Liu, Y.-Y. Tan, Y.-J. Zhang, and W. Jiang, Consensus analysis of fractional-order nonlinear multi-agent systems with distributed and input delays, Neurocomputing, 329, 2019, 46–52.
11. [11] J. Zhan and X. Li, Cluster consensus in networks of agents with weighted cooperative–competitive interactions, IEEE Transactions on Circuits and Systems II: Express Briefs, 65(2), 2018, 241–245.
12. [12] K. Chen, J. Wang, Y. Zhang, and F.L. Lewis, Cluster consensus of heterogeneous linear multi-agent systems, IET Control Theory & Applications, 12(11), 2018, 1533–1542.
13. [13] A.S. Dolby and T.C. Grubb Jr, Benefits to satellite members in mixed-species foraging groups: an experimental analysis, Animal Behaviour, 56(2), 1998, 501–509.
14. [14] V.D. Blondel, J.M. Hendrickx, and J.N. Tsitsiklis, On Krause’s multi-agent consensus model with state-dependent connectivity, IEEE Transactions on Automatic Control, 54(11), 2009, 2586–2597.
15. [15] Z. Li, Z. Duan, and G. Chen, Global synchronised regions of linearly coupled Lur’e systems, International Journal of Control, 84(2), 2011, 216–227.
16. [16] Y. Zhao, Z. Duan, G. Wen, and G. Chen, Robust consensus tracking of multi-agent systems with uncertain Lur’e-type non-linear dynamics, IET Control Theory & Applications, 7(9), 2013, 1249–1260.
17. [17] B. Ning, Q.-L. Han, and Z. Zuo, Practical fixed-time consensus for integrator-type multi-agent systems: A time base generator approach, Automatica, 105, 2019, 406–414.
18. [18] L. Ding, P. Yu, Z.-W. Liu, and Z.-H. Guan, Consensus and performance optimisation of multi-agent systems with position-only information via impulsive control, IET Control Theory & Applications, 7(1), 2013, 16–24.
19. [19] I. Podlubny, Fractional differential equations: an introduction to fractional derivatives, fractional differential equations, to methods of their solution and some of their applications (Amsterdam: Elsevier, 1998).
20. [20] Y. Li, Y. Chen, and I. Podlubny, Stability of fractional-order nonlinear dynamic systems: Lyapunov direct method and generalized Mittag-Leffler stability, Computers & Mathematics with Applications, 59(5), 2010, 1810–1821.
21. [21] N. Aguila-Camacho, M.A. Duarte-Mermoud, and J.A. Gallegos, Lyapunov functions for fractional order systems, Communications in Nonlinear Science and Numerical Simulation, 19(9), 2014, 2951–2957.
22. [22] S. Zhang, Y. Yu, and J. Yu, LMI conditions for global stability of fractional-order neural networks, IEEE Transactions on Neural Networks and Learning Systems, 28(10), 2017, 2423– 2433.
23. [23] Z. Li, Z. Duan, G. Chen, and L. Huang, Consensus of multiagent systems and synchronization of complex networks: A unified viewpoint, IEEE Transactions on Circuits & Systems I: Regular Papers, 57(1), 2010, 213–224.
24. [24] I. Stamova, Mittag-Leffler stability of impulsive differential equations of fractional order, Quarterly of Applied Mathematics, 73(3), 2015, 525–535.
25. [25] X. Yang, C. Li, T. Huang and Q. Song, Mittag-Leffler stability analysis of nonlinear fractional-order systems with impulses, Applied Mathematics and Computation, 293, 2017, 416–422.
26. [26] G. Wen, Z. Duan, G. Chen, and W. Yu, Consensus tracking of multi-agent systems with Lipschitz-type node dynamics and switching topologies, IEEE Transactions on Circuits and Systems I: Regular Papers, 61(2), 2014, 499–511.
27. [27] R.A. Horn and C.R. Johnson, Matrix analysis (Cambridge: Cambridge University Press, 1990).
28. [28] F. Zhu and Z. Han, A note on observers for Lipschitz nonlinear systems, IEEE Transactions on Automatic Control, 47(10), 2002, 1751–1754.

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• Abstract
• DOI: 10.2316/J.2020.201-0063
• From Journal (201) Mechatronic Systems and Control - 2020

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