New Operational Matrices for Solving Fractional Differential Equations on the Half-Line

Bhrawy, A. H.; Taha, Taha M.; Alzahrani, Ebraheem O.; Băleanu, Dumitru; Al-Zahrani, Abdulrahim A.

doi:10.1371/journal.pone.0126620

Cited by 12 publications

(5 citation statements)

References 43 publications

(21 reference statements)

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“…The point of departure of the spectral technique is to approximate the solutions yfalse[lfalse]false(x,tfalse) and pfalse[lfalse]false(x,tfalse) of the two PDEs in equations (3) via orthogonal functions false{φjfalse(xfalse)false}j=1m~-1 where m~≥2 is an integer. Here, we consider two kinds of orthogonal functions: the fractional-order generalized Laguerre functions (Bhrawy et al., 2015c) and the shifted Jacobi polynomials (Bhrawy and Zaky, 2015). More choices of the orthogonal functions false{φjfalse(xfalse)false}j=1m~-1 can be found in the work by Bhrawy et al.…”

Section: Numerical Resultsmentioning

confidence: 99%

“…(2015d: Sections 4 and 5), we have which implies that where boldDm~∈ ℝfalse(m~-1false)×false(m~-1false) and Θm~∈ ℝfalse(m~-1false)×false(m~-1false) are the operational matrices of the left Riemann–Liouville fractional integration and the regular second-order derivative, respectively. For the fractional-order generalized Laguerre functions (the shifted Jacobi polynomials), respectively, the concrete expression of the two operational matrices boldDm~ and Θm~ can be found in the work by Bhrawy et al. (2015c) (Bhrawy and Zaky, 2015), respectively.…”

Section: Numerical Resultsmentioning

confidence: 99%

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A fast second-order parareal solver for fractional optimal control problems

Huang

2017

Journal of Vibration and Control

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The gradient projection technique has recently been used to solve the optimal control problems governed by a fractional diffusion equation. It lies in repeatedly solving the state and co-state equations derived from the optimality conditions, and the Crank–Nicolson (CN) scheme, which gives a second-order numerical solution, is a widely used method to solve these two equations. The goal of this paper is to implement the CN scheme in a parallel-in-time manner in the framework of the parareal algorithm. Because of the stiffness of the approximation matrix of the fractional operator, direct use of the CN scheme results in a convergence factor ρ satisfying [Formula: see text] as [Formula: see text] for the parareal algorithm, where [Formula: see text] denotes the space step-size. Here, we provide a new idea to let the parareal algorithm use the CN scheme as the basic component possessing a constant convergence factor [Formula: see text], which is independent of [Formula: see text]. Numerical results are provided to show the efficiency of the proposed algorithm.

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Section: Numerical Resultsmentioning

confidence: 99%

Section: Numerical Resultsmentioning

confidence: 99%

A fast second-order parareal solver for fractional optimal control problems

Huang

2017

Journal of Vibration and Control

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“…It should be mentioned that there are also applications from the viewpoint of many fields such as physics, chemistry, engineering, finance, and other sciences that have been developed in the last few decades [12,24,25,27,28,35,43]. A large number of authors studied fractional differential equations, such as [1,6,7,32,39].…”

Section: Introductionmentioning

confidence: 99%

Numerical approach for solving space fractional orderdiffusion equations using shifted Chebyshev polynomials of the fourth kind

Sweilam¹,

Nagy²,

Ei-Sayed³

2016

Turk J Math

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In this paper, a new approach for solving space fractional order diffusion equations is proposed. The fractional derivative in this problem is in the Caputo sense. This approach is based on shifted Chebyshev polynomials of the fourth kind with the collocation method. The finite difference method is used to reduce the equations obtained by our approach for a system of algebraic equations that can be efficiently solved. Numerical results obtained with our approach are presented and compared with the results obtained by other numerical methods. The numerical results show the efficiency of the proposed approach.

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“…The derivation process is similar to that of the linear system. Assuming f (t) = 𝐹 T 𝐻 N (t) and y(t) = 𝑌 T 𝐻 N (t), equation (32) can be simplified by a Haar wavelet operational matrix of integration as follows:…”

Section: Nonlinear System Identificationmentioning

confidence: 99%

“…This method has been used to identify the FOS by Tang et al [27] Li and Sun used the Block-Pulse operational matrix for analyzing the fractional order systems. [28] Other operational matrices include the Legendre operational matrix, [29][30][31][32] Chebyshev operational matrix, [33,34] Jacobi operational matrix, [35] operational matrices of triangular functions, [36] and Haar wavelet operational matrix. [37][38][39] However, for an actual system, the quantity of measurement data is large, which will lead to a high-dimensional operational matrix.…”

Section: Introductionmentioning

confidence: 99%

Using wavelet multi-resolution nature to accelerate the identification of fractional order system

Meng

Ding

2017

Chinese Phys. B

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Because of the fractional order derivatives, the identification of the fractional order system (FOS) is more complex than that of an integral order system (IOS). In order to avoid high time consumption in the system identification, the leastsquares method is used to find other parameters by fixing the fractional derivative order. Hereafter, the optimal parameters of a system will be found by varying the derivative order in an interval. In addition, the operational matrix of the fractional order integration combined with the multi-resolution nature of a wavelet is used to accelerate the FOS identification, which is achieved by discarding wavelet coefficients of high-frequency components of input and output signals. In the end, the identifications of some known fractional order systems and an elastic torsion system are used to verify the proposed method.

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New Operational Matrices for Solving Fractional Differential Equations on the Half-Line

Cited by 12 publications

References 43 publications

A fast second-order parareal solver for fractional optimal control problems

A fast second-order parareal solver for fractional optimal control problems

Numerical approach for solving space fractional orderdiffusion equations using shifted Chebyshev polynomials of the fourth kind

Using wavelet multi-resolution nature to accelerate the identification of fractional order system

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