Numerical solution of fractional Sturm-Liouville equation in integral form

Abstract: In this paper a fractional differential equation of the Euler-Lagrange/ Sturm-Liouville type is considered. The fractional equation with derivatives of order α ∈ (0, 1] in the finite time interval is transformed to the integral form. Next the numerical scheme is presented. In the final part of this paper examples of numerical solutions of this equation are shown. The convergence of the proposed method on the basis of numerical results is also discussed.MSC 2010 : Primary 26A33; Secondary 34A08, 65L10

“…The results presented in [28] are considered as the beginning of the fractional calculus of variations. After the work of Riewe [28] several authors contributed to the theory of fractional variational calculus and different approaches in literature were discussed: fractional sequential mechanics [1,15], the Green theorem for generalized fractional derivatives [4,23], the fractional Sturm-Liouville problem [11,17]. For other applications of fractional variational principles we refer readers to paper [22] and the references given therein.…”

Fractional oscillator equation – Transformation into integral equation and numerical solution

“…The results presented in [28] are considered as the beginning of the fractional calculus of variations. After the work of Riewe [28] several authors contributed to the theory of fractional variational calculus and different approaches in literature were discussed: fractional sequential mechanics [1,15], the Green theorem for generalized fractional derivatives [4,23], the fractional Sturm-Liouville problem [11,17]. For other applications of fractional variational principles we refer readers to paper [22] and the references given therein.…”

Fractional oscillator equation – Transformation into integral equation and numerical solution

“…For more details, see the recent publications [1,2,3,5,6,7,8,9,10,14,15,17,19,20,21,22], and references cited therein. The Riemann-Liouville (R-L) derivative and Caputo derivative are commonly used, respectively defined below: The left R-L derivative reflects the dependence on the history, while the right R-L derivative the dependence upon the future.…”

“…From the known first Fick's law ∂u(x, t) ∂t 2 . If the advection-diffusion process at any position x ∈ (a, b) relies on the whole space (a, b) (i.e., long-range interactions), then the classical Fick's law does not work well yet.…”

High-Order Algorithms for Riesz Derivative and their Applications (III)

“…This paper proposes a description which does not investigate the structure but assumes some degree of its heterogeneity. When abandoning the classical equation and substituting it with an ordinary differential equation including the left and right fractional derivatives [4,5,7,8,22] we arrive at a model which has such a quality that it does not investigate the structure and does not include such a number of factors. Such equations are the result of the modification of the principle of least action and the application of the fractional rule of integration by parts [5].…”

Modelling and analysis of heat transfer through 1D complex granular system