Fractional-order uniaxial visco-elasto-plastic models for structural analysis

Suzuki, Jorge L.; Zayernouri, Mohsen; Bittencourt, Marco L.; Karniadakis, George Em

doi:10.1016/j.cma.2016.05.030

Cited by 56 publications

(75 citation statements)

References 39 publications

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“…Since the grid is non-uniform, equations (33)-(39) do not hold anymore. Thus, using (48), we obtain (1) M (4) M (5) M (3) M (6) M (7) M (8) M (9) M (10) M (11) Ŝ (6) where ∆ε = ε − e > 0, denotes the element difference between the current element ε and the e-th element. Using the same expansion as in (35), we can write (49) as…”

Section: Non-uniform Geometrically Progressive Gridsmentioning

confidence: 99%

“…Fractional order models open up new possibilities for robust mathematical modeling of complex multi-scale problems and anomalous transport phenomena including: non-Markovian (Lévy flights) processes in turbulent flows [2,3], non-Newtonian fluids and rheology [4], non-Brownian transport phenomena in porous and disordered materials [5,6], non-Gaussian processes in multi-scale complex fluids and multi-phase applications [7], visco-elastic bio-tissues, and visco-elastoplastic materials [6,8,9].…”

Section: Introductionmentioning

confidence: 99%

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A Petrov–Galerkin spectral element method for fractional elliptic problems

Kharazmi

Zayernouri

Karniadakis

2017

Computer Methods in Applied Mechanics and Engineering

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We develop a new C 0 -continuous Petrov-Galerkin spectral element method for one-dimensional fractional elliptic problems of the form 0 D α, subject to homogeneous boundary conditions. We employ the standard (modal) spectral element bases and the Jacobi poly-fractonomials as the test functions [1]. We formulate a new procedure for assembling the global linear system from elemental (local) mass and stiffness matrices. The Petrov-Galerkin formulation requires performing elemental (local) construction of mass and stiffness matrices in the standard domain only once. Moreover, we efficiently obtain the non-local (history) stiffness matrices, in which the non-locality is presented analytically for uniform grids. We also investigate two distinct choices of basis/test functions: i) local basis/test functions, and ii) local basis with global test functions. We show that the former choice leads to a better-conditioned system and accuracy. We consider smooth and singular solutions, where the singularity can occur at boundary points as well as in the interior domain. We also construct two non-uniform grids over the whole computational domain in order to capture singular solutions. Finally, we perform a systematic numerical study of non-local effects via full and partial history fading in order to further enhance the efficiency of the scheme.

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Section: Non-uniform Geometrically Progressive Gridsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

A Petrov–Galerkin spectral element method for fractional elliptic problems

Kharazmi

Zayernouri

Karniadakis

2017

Computer Methods in Applied Mechanics and Engineering

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“…Over the past decades, anomalous transport has been observed and investigated in a wide range of applications such as turbulence [11,21,43,49], porous media [4,7,16,59,66,67], geoscience [5], bioscience [45][46][47][48], and viscoelastic material [20,40,54,55,60]. The underlying anomalous features, manifesting in memory effects, non-local interactions, powerlaw distributions, sharp peaks, and self-similar structures, can be well described by fractional partial differential equations (FPDEs) [27,41,42,44].…”

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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“…Due to the spatial non-locality of the operators with fractional orders, these operators have become significant tools that enable researchers to bring new aspects to the dynamics of non-local complex systems [1][2][3][4][5][6][7][8]. In addition, there has been an intensive interest in dealing with differential equations embodying derivatives with fractional order from many point of views including the qualitative, theoretical and numerical aspects [1][2][3] and studying the existence and uniqueness of solutions of differential equations in the frame of the traditional fractional derivative has been tackled in many works (see [9] and the references therein).…”

Section: Introductionmentioning

confidence: 99%

On Dynamic Systems in the Frame of Singular Function Dependent Kernel Fractional Derivatives

et al. 2019

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In this article, we discuss the existence and uniqueness theorem for differential equations in the frame of Caputo fractional derivatives with a singular function dependent kernel. We discuss the Mittag-Leffler bounds of these solutions. Using successive approximation, we find a formula for the solution of a special case. Then, using a modified Laplace transform and the Lyapunov direct method, we prove the Mittag-Leffler stability of the considered system.

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Fractional-order uniaxial visco-elasto-plastic models for structural analysis

Cited by 56 publications

References 39 publications

A Petrov–Galerkin spectral element method for fractional elliptic problems

A Petrov–Galerkin spectral element method for fractional elliptic problems

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

On Dynamic Systems in the Frame of Singular Function Dependent Kernel Fractional Derivatives

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