Stability and resonance conditions of second-order fractional systems

Иванова, Елена; Moreau, Xavier; Malti, Rachid

doi:10.1177/1077546316654790

Cited by 12 publications

(10 citation statements)

References 52 publications

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“…Lemma 3.1. Let 0 < α 1 < α 2 ≤ 1 and a, b, c ∈ R. Then, the following statements hold for the function Q defined in (12).…”

Section: The Variation Of Constants Formula For the Solutionsmentioning

confidence: 99%

“…In addition to the algorithmic approach as in [16], a number of analytic approaches have been used to investigate the zeros of characteristic polynomials of systems of fractional order systems. In [12], the stability and resonance conditions are established for fractional systems of second order in terms of a pseudo-damping factor and a fractional differentiation order. The method in [12] has been successfully extended in [26] for a wide class of second kind non-commensurate elementary systems.…”

Section: Introductionmentioning

confidence: 99%

“…In [12], the stability and resonance conditions are established for fractional systems of second order in terms of a pseudo-damping factor and a fractional differentiation order. The method in [12] has been successfully extended in [26] for a wide class of second kind non-commensurate elementary systems. By the substitution method, a variation of constants formula and the properties of the Mittag-Leffler function in the stable domain, in [10], the authors have shown the asymptotic stability for fractional order systems with (block) triangular coefficient matrices.…”

Section: Introductionmentioning

confidence: 99%

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Asymptotic behaviour of solutions to non-commensurate fractional-order planar systems

Diethelm¹,

Thái²,

Tuan³

2022

Preprint

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This paper is devoted to studying non-commensurate fractional order planar systems. Our contributions are to derive sufficient conditions for the global attractivity of non-trivial solutions to fractional-order inhomogeneous linear planar systems and for the Mittag-Leffler stability of an equilibrium point to fractional order nonlinear planar systems. To achieve these goals, our approach is as follows. Firstly, based on Cauchy's argument principle in complex analysis, we obtain various explicit sufficient conditions for the asymptotic stability of linear systems whose coefficient matrices are constant. Secondly, by using Hankel type contours, we derive some important estimates of special functions arising from a variation of constants formula of solutions to inhomogeneous linear systems. Then, by proposing new weighted norms combined with the Banach fixed point theorem for appropriate Banach spaces, we get the desired conclusions. Finally, numerical examples are provided to illustrate the effect of the main theoretical results.

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“…Lemma 3.1. Let 0 < α 1 < α 2 ≤ 1 and a, b, c ∈ R. Then, the following statements hold for the function Q defined in (12).…”

Section: The Variation Of Constants Formula For the Solutionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Asymptotic behaviour of solutions to non-commensurate fractional-order planar systems

Diethelm¹,

Thái²,

Tuan³

2022

Preprint

View full text Add to dashboard Cite

show abstract

“…Therefore, fractional-order differential equations can more completely and precisely describe systems having responses with long memory transients than the ordinary integer-order differential equations Tavazoei, 2014, 2017). Accordingly, stability and stabilization of fractional-order systems is an important and challenging problem since many physical and real-world processes are modeled with fractional-order state equations (Badri and Sojoodi, 2018;Ivanova et al, 2018;Lu and Chen, 2009;Ma et al, 2014). Unfortunately, uncertainties arising from neglected dynamics, uncertain physical parameters, parametric variations in time, and many other sources are inevitable in real physical system.…”

Section: Introductionmentioning

confidence: 99%

Dynamic robust stabilization of fractional-order linear systems with nonlinear uncertain parameters: an LMI approach

Badri

Sojoodi

Zavvari

2021

International Journal of General Systems

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This paper considers the problem of robust stability and stabilization for linear fractionalorder system with nonlinear uncertain parameters, with fractional order . A dynamic output feedback controller, with predetermined order, for asymptotically stabilizing such uncertain fractional-order systems is designed. The derived stabilization conditions are in LMI form. Simulation results of two numerical examples illustrate that the proposed sufficient theoretical results are applicable and effective for tackling robust stabilization problems.

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“…In this case, viewed the complexity of the algebraic methods as Routh and Jury criteria [11], stability has been essentially investigated using graphical methods as in [30,20,28]. However, very recently, [5,12] establish numerically the stability and resonance limits of uncommensurate systems.…”

mentioning

confidence: 99%

Analytical study of resonance regions for second kind commensurate fractional systems

Boubidi¹,

Kechida²,

Tebbikh³

2021

DCDS-B

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The aim of this paper is to determine analytically the resonance limits for second kind commensurate fractional systems in terms of the pseudo damping factor ξ and the commensurate order v and in addition specify the different resonance regions. In the literature, these limits and regions have never been discussed mathematically, they are determined numerically. Second kind commensurate fractional systems are resonant if the equation : Ω 3v + 3ξcos(vπ/2)Ω 2v + (2ξ 2 + cos(vπ))Ω v + ξcos(vπ/2) = 0, obtained by setting the first derivative of the amplitude-frequency response equal to zero, has at last one strictly positive root. As in the conventional case, resonance limits correspond to zero discriminant of the last equation. This discriminant is a cubic equation in ξ 2 whose coefficients change depending on v. To resolve this equation, the tangent trigonometric solving method is used and the relationship between ξ and v is established, which represents the resonance limits expression. To search resonance regions, a mathematical study is conducted on the first equation to find the positive roots number for each (v, ξ) combination. Compared to works already achieved, a new region appeared in the region of single resonant frequency with an anti-resonant one. The results are tested through numerical examples and applied to a fractional filter.

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Stability and resonance conditions of second-order fractional systems

Cited by 12 publications

References 52 publications

Asymptotic behaviour of solutions to non-commensurate fractional-order planar systems

Asymptotic behaviour of solutions to non-commensurate fractional-order planar systems

Dynamic robust stabilization of fractional-order linear systems with nonlinear uncertain parameters: an LMI approach

Analytical study of resonance regions for second kind commensurate fractional systems

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