Distributed-order fractional constitutive stress–strain relation in wave propagation modeling

Konjik, Sanja; Oparnica, Ljubica; Zorica, Dušan

doi:10.1007/s00033-019-1097-z

Cited by 25 publications

(37 citation statements)

References 64 publications

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“…Since σ (g) sr = a3 b , see [28,Eq. (57)], the wave propagation speed (44) is exactly the wave propagation speed (8) that is obtained in [22] for the constitutive models having fractional differentiation orders not exceeding one.…”

Section: After Inverting Fourier and Laplace Transforms In (35)mentioning

confidence: 60%

“…obtained and analyzed in [2] for thermodynamical consistency and used in [22] as constitutive equations in wave propagation modeling. Namely, the results of [20,21], where the wave propagation speed is found via the conic solution support, i.e., |x| < ct, in the case of the fractional Zener model and its generalization, respectively given by…”

Section: Introductionmentioning

confidence: 99%

“…22) yields 0 < β−(µ − α) < β+(µ − α) < 1, so that by setting ζ = β−(µ − α) and ξ = β + (µ − α) in function g given by (49), using (50) one hassin ((α + β − µ) ϕ) sin ((µ − α + β) ϕ) < sin (µ−α−β)πTherefore, again by(22), one has that b − a3 a1 |sin((µ−α−β)ϕ)| sin((µ−α+β)ϕ) > 0, which, along with the positivity of all other terms in (52), implies that f ρ (ϕ) > 0 if ϕ ∈ 0, π 2 .…”

mentioning

confidence: 99%

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Fractional Burgers wave equation

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Thermodynamically consistent fractional Burgers constitutive models for viscoelastic media, divided into two classes according to model behavior in stress relaxation and creep tests near the initial time instant, are coupled with the equation of motion and strain forming the fractional Burgers wave equations. Cauchy problem is solved for both classes of Burgers models using integral transform method and analytical solution is obtained as a convolution of the solution kernels and initial data. The form of solution kernel is found to be dependent on model parameters, while its support properties implied infinite wave propagation speed for the first class and finite for the second class. Spatial profiles corresponding to the initial Dirac delta displacement with zero initial velocity display features which are not expected in wave propagation behavior.

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Section: After Inverting Fourier and Laplace Transforms In (35)mentioning

confidence: 60%

Section: Introductionmentioning

confidence: 99%

mentioning

confidence: 99%

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Fractional Burgers wave equation

2019

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“…Often a memory is not of power-type. A direct generalization of (k1) leads to multiterm and distributed order fractional derivatives [15][16][17]. These derivatives have the following kernels:…”

Section: Generalized Fractional Derivativesmentioning

confidence: 99%

An Inverse Problem for a Generalized Fractional Derivative with an Application in Reconstruction of Time- and Space-Dependent Sources in Fractional Diffusion and Wave Equations

Kinash

Janno

2019

Mathematics

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In this article, we consider two inverse problems with a generalized fractional derivative. The first problem, IP1, is to reconstruct the function u based on its value and the value of its fractional derivative in the neighborhood of the final time. We prove the uniqueness of the solution to this problem. Afterwards, we investigate the IP2, which is to reconstruct a source term in an equation that generalizes fractional diffusion and wave equations, given measurements in a neighborhood of final time. The source to be determined depends on time and all space variables. The uniqueness is proved based on the results for IP1. Finally, we derive the explicit solution formulas to the IP1 and IP2 for some particular cases of the generalized fractional derivative.

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“…A faithful description of such anomalous transport requires exploiting distributed-order derivatives, in which the derivative order has a distribution over a range of values. The reader is referred to [14,15,19,28,36,37,42,53,58] and the references given therein for more details on the distributed-order fractional equations.…”

Section: Introductionmentioning

confidence: 99%

A Unified Petrov–Galerkin Spectral Method and Fast Solver for Distributed-Order Partial Differential Equations

Samiee

Kharazmi

Meerschaert

et al. 2020

Commun. Appl. Math. Comput.

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Fractional calculus and fractional-order modeling provide effective tools for modeling and simulation of anomalous diffusion with power-law scalings. In complex multi-fractal anomalous transport phenomena, distributed-order partial differential equations appear as tractable mathematical models, where the underlying derivative orders are distributed over a range of values, hence taking into account a wide range of multi-physics from ultraslow-to-standard-to-superdiffusion/wave dynamics. We develop a unified, fast, and stable Petrov-Galerkin spectral method for such models by employing Jacobi poly-fractonomials and Legendre polynomials as temporal and spatial basis/test functions, respectively. By defining the proper underlying distributed Sobolev spaces and their equivalent norms, we rigorously prove the well-posedness of the weak formulation, and thereby, we carry out the corresponding stability and error analysis. We finally provide several numerical simulations to study the performance and convergence of proposed scheme.

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Distributed-order fractional constitutive stress–strain relation in wave propagation modeling

Cited by 25 publications

References 64 publications

Fractional Burgers wave equation

Fractional Burgers wave equation

An Inverse Problem for a Generalized Fractional Derivative with an Application in Reconstruction of Time- and Space-Dependent Sources in Fractional Diffusion and Wave Equations

A Unified Petrov–Galerkin Spectral Method and Fast Solver for Distributed-Order Partial Differential Equations

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