Distributed-Order Dynamic Systems

In this paper, we further develop Podlubny's matrix approach to discretization of integrals and derivatives of non-integer order. Numerical integration and differentiation on non-equidistant grids is introduced and illustrated by several examples of numerical solution of differential equations with fractional derivatives of constant orders and with distributedorder derivatives. In this paper, for the first time, we present a variable-step-length approach that we call 'the method of large steps', because it is applied in combination with the matrix approach for each 'large step'. This new method is also illustrated by an easyto-follow example. The presented approach allows fractional-order and distributed-order differentiation and integration of non-uniformly sampled signals, and opens the way to development of variable-and adaptive-step-length techniques for fractional-and distributed-order differential equations.

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“…In this paper, we use the following definition of distributed-order differential/integral operators [8]:…”

Section: Solution Of Distributed-order Differential Equations On Non-mentioning

confidence: 99%

Matrix approach to discrete fractional calculus III: non-equidistant grids, variable step length and distributed orders

Podlubný

Škovránek

Vinagre

et al. 2013

Phil. Trans. R. Soc. A.

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“…But, in recent decades, this has changed. It was found that fractional calculus is useful, even powerful, for modelling viscoelasticity [4], electromagnetic waves [5], boundary layer effects in ducts [6], quantum evolution of complex systems [7], distributed-order dynamical systems [8] and others. That is, the fractional differential systems are more suitable to describe physical phenomena that have memory and genetic characteristics.…”

Section: Introductionmentioning

confidence: 99%

Chaos synchronization in fractional differential systems

Zhang

Chen

et al. 2013

Phil. Trans. R. Soc. A.

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This paper presents a brief overview of recent developments in chaos synchronization in coupled fractional differential systems, where the original viewpoints are retained. In addition to complete synchronization, several other extended concepts of synchronization, such as projective synchronization, hybrid projective synchronization, function projective synchronization, generalized synchronization and generalized projective synchronization in fractional differential systems, are reviewed.

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“…Materials whose constitutive equations can be described by a fractional derivative [5] are of increasing interest in recent years (see [30,29]). It is well known that materials with such properties can be considered in the class of materials with memory and may describe elastic, fluid and electromagnetic materials, but also other kinds of phenomena, such as heat flux models.…”

Section: Introductionmentioning

confidence: 99%

“…The creep function for such models also has power law form. Such experimental backing has motivated many studies of materials with fading memory given by a fractional derivative, including [6,22,4,14,17,30,23] and in the frequency domain [19,36]. Many experimental observations on a variety of materials subject to a constant load show plastic behavior, which can be described by the fractional derivative approach.…”

Section: Introductionmentioning

confidence: 99%

Fractional rheological models for thermomechanical systems. Dissipation and free energies

Fabrizio

2013

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Within the fractional derivative framework, we study thermomechanical models with memory and compare them with the classical Volterra theory. The fractional models involve significant differences in the type of kernels and predicts important changes in the behavior of fluids and solids. Moreover, an analysis of the thermodynamic restrictions provides compatibility conditions on the kernels and allows us to determine certain free energies, which in turn enables the definition of a topology on the history space. Finally, an analogous analysis is carried out for the phenomenon of heat propagation with memory.MSC 2010 : Primary 26A33; Secondary 33E12, 34A08, 34K37, 35R11, 60G22

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Distributed-Order Dynamic Systems

Cited by 141 publications

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Matrix approach to discrete fractional calculus III: non-equidistant grids, variable step length and distributed orders

Matrix approach to discrete fractional calculus III: non-equidistant grids, variable step length and distributed orders

Chaos synchronization in fractional differential systems

Fractional rheological models for thermomechanical systems. Dissipation and free energies

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