Communications on Applied Mathematics and Computation >

2021 , Vol. 3 >Issue 3: 545 - 569

DOI: https://doi.org/10.1007/s42967-021-00132-7

Approximations of the Fractional Integral and Numerical Solutions of Fractional Integral Equations

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  • 1 Department of Mathematics and Physics, University of Forestry, 1756 Sofia, Bulgaria;
    2 Institute of Mathematics and Informatics, Bulgarian Academy of Sciences, 1113 Sofia, Bulgaria

Received date: 2020-08-24

  Revised date: 2020-11-18

  Online published: 2021-09-16

Supported by

This work was supported by the Bulgarian National Science Fund under Project KP-06-M32/2 "Advanced Stochastic and Deterministic Approaches for Large-Scale Problems of Computational Mathematics"

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Abstract

In the present paper, we derive the asymptotic expansion formula for the trapezoidal approximation of the fractional integral. We use the expansion formula to obtain approximations for the fractional integral of orders α, 1 + α, 2 + α, 3 + α and 4 + α. The approximations are applied for computation of the numerical solutions of the ordinary fractional relaxation and the fractional oscillation equations expressed as fractional integral equations.

Key words: Fractional integral; Trapezoidal approximation; Fractional integral equation; Finite-difference scheme

Cite this article

Yuri Dimitrov . Approximations of the Fractional Integral and Numerical Solutions of Fractional Integral Equations[J]. Communications on Applied Mathematics and Computation, 2021 , 3(3) : 545 -569 . DOI: 10.1007/s42967-021-00132-7

References

1. Abramowitz, M., Stegun, I.A.:Handbook of Mathematical Functions with Formulas, Graphs, and Mathematical Tables. Dover, New York (1964)
2. Anjara, F., Solofoniaina, J.:Solution of general fractional oscillation relaxation equation by Adomian's method. Gen. Math. Notes 20(2), 1-11 (2014)
3. Cartea, A., del Castillo-Negrete, D.:Fractional diffusion models of option prices in markets with jumps. Physica A 374(2), 749-763 (2007)
4. Diethelm, K., Ford, N.J.:Volterra integral equations and fractional calculus:do neighboring solutions intersect? J. Integral Equ. Appl. 24(1), 25-37 (2012)
5. Dimitrov, Y.:Numerical approximations for fractional differential equations. J. Fract. Calc. Appl. 5(3S), 1-45 (2014)
6. Dimitrov, Y.:A second order approximation for the Caputo fractional derivative. J. Fract. Calc. Appl. 7(2), 175-195 (2016)
7. Dimitrov, Y.:Three-point approximation for Caputo fractional derivative. Commun. Appl. Math. Comput. 31(4), 413-442 (2017)
8. Dimitrov, Y., Miryanov, R., Todorov, V.:Quadrature formulas and Taylor series of secant and tangent. Econ. Comput. Sci. 4, 23-40 (2017)
9. Ding, H., Li, C.:High-order algorithms for Riesz derivative and their applications (III). Fract. Calc. Appl. Anal. 19(1), 19-55 (2016)
10. Ding, H., Li, C.:High-order numerical algorithms for Riesz derivatives via constructing new generating functions. J. Sci. Comput. 71, 759-784 (2017)
11. Eslahchi, M.R., Dehghan, M., Parvizi, M.:Application of the collocation method for solving nonlinear fractional integro-differential equations. J. Comput. Appl. Math. 257, 105-128 (2014)
12. Gülsu, M., Öztürk, Y., Anapali, A.:Numerical approach for solving fractional relaxation-oscillation equation. Appl. Math. Model. 37(8), 5927-5937 (2013)
13. Hilfer, R.:Applications of Fractional Calculus in Physics. World Scientific Publ. Co., Singapore (2000)
14. Huang, L., Li, X.F., Zhao, Y.L., Duan, X.Y.:Approximate solution of fractional integro-differential equations by Taylor expansion method. Comput. Math. Appl. 62, 1127-1134 (2011)
15. Kouba, O.:Bernoulli polynomials and applications. arXiv:1309. 7560v2 (2013)
16. Lampret, V.:The Euler-Maclaurin and Taylor formulas:twin, elementary derivations. Math. Mag. 74(2), 109-122 (2001)
17. Mainardi, F.:Fractional relaxation-oscillation and fractional diffusion-wave phenomena. Chaos Solit. Fract. 7(9), 1461-1477 (1996)
18. Mainardi, F., Gorenflo, R.:Time-fractional derivatives in relaxation processes:a tutorial survey. Fract. Calc. Appl. Anal. 10(3), 269-308 (2007)
19. Mokhtary, P.:Discrete Galerkin method for fractional integro-differential equations. Acta Math. Sci. 36(2), 560-578 (2016)
20. Pérez, D., Yamilet, Q.:A survey on the Weierstrass approximation theorem. Divulgaciones Matemáticas 16(1), 231-247 (2008)
21. Podlubny, I.:Fractional Differential Equations. Academic Press, San Diego (1999)
22. Sidi, A.:Euler-Maclaurin expansions for integrals with endpoint singularities:a new perspective. Numerische Mathematik 98(2), 371-387 (2004)
23. Sun, H.G., Zhang, Y., Baleanu, D., Chen, W., Chen, Y.Q.:A new collection of real world applications of fractional calculus in science and engineering. Commun. Nonlinear Sci. Numer. Simulat. 64, 213-231 (2018)
24. Tadjeran, C., Meerschaert, M.M., Scheffer, H.P.:A second-order accurate numerical approximation for the fractional diffusion equation. J. Comput. Phys. 213, 205-213 (2006)
25. Tian, W.Y., Zhou, H., Deng, W.:A class of second order difference approximation for solving space fractional diffusion equations. Math. Comput. 84(294), 1703-1727 (2012)
26. Todorov, V., Dimitrov, Y., Dimov, I.:Second order shifted approximations for the first derivative. In:Dimov, I., Fidanova, S. (eds) Advances in High Performance Computing. HPC 2019. Studies in Computational Intelligence 902, Springer, Cham (2020)
27. Wu, R., Ding, H., Li, C.:Determination of coefficients of high-order schemes for Riemann-Liouville derivative. Sci. World. J. 2014, 402373 (2014)
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