Finite-horizon \(H_\infty\) output fault-tolerant consensus for multi-agent systems with switching topology and deception attacks. (English) Zbl 1532.93066
Summary: This article investigates the output fault-tolerant consensus problem for multi-agent systems with switching topology and deception attacks. In order to reduce the effects of switching topology, the differences between topologies can be modeled as topology uncertainties. In practice, the deception attack may occur in a random way and assumed to satisfy Bernoulli distributions. The purpose of this research is to design an output fault-tolerant controller such that, in the presence of switching topology, actuator faults, and deception attacks, the finite-horizon output fault-tolerant consensus can be achieved under a prespecified \(H_\infty\) performance. An initial-state-based performance requirement is constructed, and this bypasses the need for the zero initial condition in the conventional \(H_\infty\) theory. After this, the controller gains are computed by employing an iterative linear matrix inequality scheme. Finally, a numerical example is provided to show the effectiveness of the proposed methods.
{© 2023 John Wiley & Sons Ltd.}
{© 2023 John Wiley & Sons Ltd.}
Keywords:
consensus; fault; fault-tolerant control; attack; \(H_\infty\) performance; multi-agent systemReferences:
| [1] | RenW, CaoY. Distributed Coordination of Multi‐agent Network. Communications and Control Engineering Series. Springer‐Verlag, London; 2011. · Zbl 1225.93003 |
| [2] | AndersonB, FidanB, YuC, WalleD. UAV formation control: theory and application. Recent Advances in Learning and Control. Lecture Notes in Control and Information Sciences. Vol 371. Springer; 2008:15, 15‐33, 33. · Zbl 1201.93089 |
| [3] | LinP, RenW, YangC, GuiW. Distributed consensus of second‐order multiagent systems with nonconvex velocity and control input constraints. IEEE Trans Automat Contr. 2018;63(4):1171‐1176. · Zbl 1390.93053 |
| [4] | WuZ, XuY, PanYJ, SuH, TangY. Event‐triggered control for consensus problem in multi‐agent systems with quantized relative state measurements and external disturbance. IEEE Trans Circ Syst I Regul Pap. 2018;65(7):2232‐2242. · Zbl 1468.93039 |
| [5] | HuW, LiuL, FengG. Consensus of linear multi‐agent systems by distributed event‐triggered strategy. IEEE Trans Cybern. 2016;46(1):148‐157. |
| [6] | LiH, LiaoX, HuangT, ZhuW. Event‐triggereing sampling based leader‐following consensus in second‐order multi‐agent systems. IEEE Trans Automat Contr. 2015;60(7):1998‐2003. · Zbl 1360.93031 |
| [7] | YangD, RenW, LiuX, ChenW. Decentralized event‐triggered consensus for linear multi‐agent systems under general directed graphs. Automatica. 2016;69:242‐249. · Zbl 1338.93239 |
| [8] | XuY, FangM, WuZ, PanYJ, ChadliM, HuangT. Input‐based event‐triggering consensus of multiagent systems under denial‐of‐service attacks. IEEE Trans Syst Man Cybern Syst. 2020;50(4):1455‐1464. |
| [9] | ZuoZ. Nonsigular fixed‐time consensus tracking for second‐order multi‐agent networks. Automatica. 2015;54:305‐309. · Zbl 1318.93010 |
| [10] | WuY, SuH, ShiP, ShuZ, WuZ. Consensus of multiagent systems using aperiodic sampled‐data control. IEEE Trans Cybern. 2016;46(9):2132‐2143. |
| [11] | ZhangD, LiuL, FengG. Consensus of heterogeneous linear multiagent systems subject to aperiodic sampled‐data and DoS attack. IEEE Trans Cybern. 2019;49(4):1501‐1511. |
| [12] | DongS, RenW, WuZ, SuH. H∞ output consensus for Markov jump multiagent systems with uncertainties. IEEE Trans Cybern. 2020;50(5):2264‐2273. |
| [13] | LinP, RenW. Distirbuted [( {H}_{\infty } \]\) constrained consensus problem. System Control Lett. 2017;104:45‐48. · Zbl 1370.93017 |
| [14] | ZhangH, YangR, YanH, YangF. H∞ consensus of event‐based multi‐agent systems with switching topology. Inf Sci. 2016;370‐371:623‐635. · Zbl 1429.93348 |
| [15] | LiJ, HoDWC, LiJ. Adaptive consensus of multi‐agent systems under quantized measurements via the edge Laplacian. Automatica. 2018;92:217‐224. · Zbl 1417.93288 |
| [16] | JinX, WangS, QinJ, ZhengWX, KangY. Adaptive fault‐tolerant consensus for a class of uncertain nonlinear second‐order multi‐agent systems with circuit implementation. IEEE Trans Circ Syst I Regul Pap. 2018;65(7):2243‐2255. · Zbl 1468.93096 |
| [17] | LinP, JiaY, LiL. Distributed robust [( {H}_{\infty } \]\) consensus control in directed networks of agents with time‐delay. Syst Control Lett. 2008;57:643‐653. · Zbl 1140.93355 |
| [18] | GuoJ, JiZ, LiuY. Sufficient conditions and limitations of equivalent partition in multiagent controllability. Sci China Inf Sci. 2022;65(3):132204. |
| [19] | ZhangW, TangY, HuangT, KurthsJ. Sampled‐data consensus of linear multi‐agent systems with packet losses. IEEE Trans Neural Netw Learn Syst. 2017;28(11):2516‐2527. |
| [20] | ChenY, DongH, LüJ, SunX, LiuK. Robust consensus of nonlinear multiagent systems with switching topology and bounded noises. IEEE Trans Cybern. 2016;46(6):1276‐1285. |
| [21] | XuW, HoDWC, LiL, CaoJ. Event‐triggered schemes on leader‐following consensus of general linear multiagent systems under different topologies. IEEE Trans Cybern. 2017;47(1):212‐223. |
| [22] | WuZ, XuY, LuR, WuY, HuangT. Event‐triggered control for consensus of multiagent systems with fixed/switching topologies. IEEE Trans Syst Man Cybern Syst. 2018;48(10):1736‐1746. |
| [23] | ZhengY, WangL. Consensus of switched multiagent systems. IEEE Trans Circuits Syst‐II Exp Briefs. 2016;63(3):314‐318. |
| [24] | LiJ, XuY, GuK, LiL, XuX. Mixed passive/ [( {H}_{\infty } \]\) hybrid control for delayed Markovian jump system with actuator constraints and fault alarm. Int J Robust Nonlinear Control. 2018;28:6016‐6037. · Zbl 1405.93126 |
| [25] | LiX, YangGH. Neural‐network‐based adaptive decentralized fualt‐tolerant control for a class of interconnected nonlinear systems. IEEE Trans Neural Netw Learn Syst. 2018;29(1):144‐155. |
| [26] | FangQ, YangGH. Event‐based fuzzy adaptive fault‐tolerant control for a class of nonlinear systems. IEEE Trans Fuzzy Syst. 2018;26(6):2686‐2698. |
| [27] | HeX, WangZ, QinL, ZhouD. Active fault‐tolerant control for an Internet‐based networked three‐tank system. IEEE Trans Control Syst Technol. 2016;24(6):2150‐2157. |
| [28] | LiJ, LiL. Reliabel control for bilateral teleoperation systems with actuator faults using fuzzy disturbance observer. IET Control Theory Appl. 2017;11(3):446‐455. |
| [29] | LiJ, RenW. Finite‐horizon [( {H}_{\infty } \]\) fault‐tolerant constrained consensus for multiagent systems with communication delays. IEEE Trans Cybern. 2021;51(1):416‐426. |
| [30] | LiJ, LiuX, RuX, XuX. Disturbance rejection adaptive fault‐tolerant constrained consensus for multi‐agent systems with failures. IEEE Trans Circuits Syst II Express Briefs. 2020;67(12):3302‐3306. |
| [31] | ZhangG, QinJ, ZhengWX, KangY. Fault‐tolerant coordination control for second‐order multi‐agent systems with partial actuator effectiveness. Inf Sci. 2018;423:115‐127. · Zbl 1447.93011 |
| [32] | ZhaoL, YangGH. End to end communication rate‐based adaptive fault tolerant control of multi‐agent systems under unreliable interconnections. Inf Sci. 2018;460‐461:331‐345. · Zbl 1448.93177 |
| [33] | KhaliliM, ZhangX, PolycarpouMM, ParisiniT, CaoY. Distributed adaptive fault‐tolerant control of uncertain multi‐agent systems. Automatica. 2018;87:142‐151. · Zbl 1378.93040 |
| [34] | YeD, ChenM, YangH. Distributed adaptive event‐triggered fault‐tolerant consensus of multiagent systems with general linear dynamics. IEEE Trans Cybern. 2019;49(3):757‐767. |
| [35] | LuA, YangG. Distributed consensus control for multi‐agent systems under denial‐of‐service. Inf Sci. 2018;439‐440:95‐107. · Zbl 1448.93297 |
| [36] | HeW, GaoX, ZhongW, QianF. Secure impulsive synchronization control of multi‐agent systems under deception attacks. Inf Sci. 2018;459:354‐368. · Zbl 1448.93248 |
| [37] | CuiY, LiuY, ZhangW, AlsaadiFE. Sampled‐based consensus for nonlinear multiagent systems with deception attacks: the decoupled method. IEEE Trans Syst Man Cybern Syst. 2021;51(1):561‐573. |
| [38] | DongH, WangZ, DingSX, GaoH. On [( {H}_{\infty } \]\) estimation of randomly occuring fauts for a class of nonlinear time‐varying systems with fading channels. IEEE Trans Automat Contr. 2016;61(2):479‐484. · Zbl 1359.93464 |
| [39] | WangJ, DingB, HuJ. Security control for LPV system with deception attacks via model predictive control: a dynamic output feedback approach. IEEE Trans Automat Contr. 2021;66(2):760‐767. · Zbl 1536.93274 |
| [40] | GuZ, YinT, DingZ. Path tracking control of autonomous vehicles subject to deception attacks via a learning‐based event‐triggered mechanism. IEEE Trans Neural Netw Learn Syst. 2021. doi:10.1109/TNNLS.2021.3056764 |
| [41] | SongH, DingD, DongH, HanQL. Distributed maximum correntropy filtering for stochastic nonlinear systems under deception attacks. IEEE Trans Cybern. 2020. doi:10.1109/TCYB.2020.3016093 |
| [42] | RenW, BeardRW. Consensus seeking in multiagent systems under dynamically changing interaction topologies. IEEE Trans Automat Contr. 2005;50(5):655‐661. · Zbl 1365.93302 |
| [43] | HornRA, JohnsonCR. Matrix Analysis. Cambridge University Press; 1987. |
| [44] | XieL. Output feedback [( {H}_{\infty } \]\) control of system with parameter uncertainty. Int J Control. 1996;63:741‐750. · Zbl 0841.93014 |
| [45] | ZhouJ, ParkJH, KongQ. Robust resilient [( {L}_2-{L}_{\infty } \]\) control for uncertain stochastic systems with multiple time delays via dynamic output feedback. J Franklin Inst. 2016;353(13):3078‐3103. · Zbl 1344.93093 |
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