Stability and stabilization of fractional-order linear systems with convex polytopic uncertainties

Lu, Jun‐Guo; Chen, YangQuan

doi:10.2478/s13540-013-0010-2

Cited by 60 publications

(24 citation statements)

References 26 publications

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“…For example, flocking movement and food searching by means of the individual secretions and microbial, submarine underwater robots in the bottom of the sea with a large number of microorganisms and viscous substances, unmanned aerial vehicles running in the complex space environment [19]. Fractionalorder dynamics and control have provided many comprehensive results of recent advances in the areas of linesr/nonlinear dynamics with analytical, numerical, and experimental methods [9,1,15,13]. Motivated by the broad application of coordination algorithms in multi-agent systems and the fact that many practical systems demonstrated fractional-order dynamics, the distributed coordination of networked fractional-order systems will be studied in this paper.…”

Section: Introductionmentioning

confidence: 99%

Distributed coordination of fractional order multi-agent systems with communication delays

Yang

Zhu

Cao

2013

fcaa

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Because of the complexity of the practical environments, many distributed multi-agent systems can not be illustrated with the integer-order dynamics and can only be described with the fractional-order dynamics. Under the connected network with directed weighted topologies, the dynamical characteristics of agents with fractional-order derivative operator is analyzed in this paper. Applying the Laplace transform and frequency domain theory of the fractional-order operator, the distributed coordination of fractional-order multi-agent systems (FOMAS) with communication delays is studied, and a critical value of time delay is obtained to ensure the consensus of FOMAS. Since the integer-order model is a special case of fractional-order model, the extended results in this paper are in accordance with that of the integer-order model. Finally, numerical examples are provided to verify our results.MSC 2010 : Primary 34K37; Secondary 68T42, 93C85

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Section: Introductionmentioning

confidence: 99%

Distributed coordination of fractional order multi-agent systems with communication delays

Yang

Zhu

Cao

2013

fcaa

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“…[33]; the stability and synchronization results of fractional-order systems with noncommensurate order were given in Refs. [34] and [35]; almost sure stability of fractional-order Black-Scholes model was treated in [36].…”

Section: Introductionmentioning

confidence: 99%

Stability analysis of impulsive fractional-order systems by vector comparison principle

Fečkan

2015

Nonlinear Dyn

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Stability of impulsive fractional-order systems is investigated in this paper. By Lyapunov direct method and vector comparison principles, results about asymptotic stability are obtained. To this end, comparison principles, including scalar and vector forms, are generalized to impulsive fractional-order systems, through which fractional inequalities are derived for the linear impulsive systems. Then, based on such comparison principles, sufficient conditions for the MittagLeffler stability of impulsive fractional-order systems are established. Examples are given to show the effectiveness of the results.

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“…In [16,17], Podlubny firstly proposed the fractionalorder proportional-integral differential (PID) controllers, which had better dynamical performance and robustness than classical integer-order PID controllers. Fractional-order dynamical control has received some persuasive results in the field of linear/nonlinear dynamics [18,19]. Furthermore, to the best of our knowledge, Cao et al specifically studied distributed coordination of multiagent systems based on fractional order [13,20], and they analyzed and summed up the relationship between the number of individuals and the fractional order in a stable multiagent system for the first time.…”

Section: Introductionmentioning

confidence: 99%

Consensus of Fractional-Order Multiagent Systems with Nonuniform Time Delays

Liu

Qin

Chen

et al. 2018

Mathematical Problems in Engineering

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Due to the complex external environment, many multiagent systems cannot be precisely described or even cannot be described by an integer-order dynamical model and can only be described by a fractional-order dynamical model. In this paper, consensus problems are investigated for two types of fractional-order multiagent systems (FOMASs) with nonuniform time delays: FOMAS with symmetric time delays and undirected topology and FOMAS with asymmetric time delays and directed topology. Employing the Laplace transform and the frequency-domain theory, two delay margins are obtained to guarantee the consensus for the two types of FOMAS, respectively. These results are also suitable for the integer-order dynamical model. Finally, simulation results are provided to illustrate the effectiveness of our theoretical results.

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Stability and stabilization of fractional-order linear systems with convex polytopic uncertainties

Cited by 60 publications

References 26 publications

Distributed coordination of fractional order multi-agent systems with communication delays

Distributed coordination of fractional order multi-agent systems with communication delays

Stability analysis of impulsive fractional-order systems by vector comparison principle

Consensus of Fractional-Order Multiagent Systems with Nonuniform Time Delays

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