Startseite Convergence rate estimates for the kernelized predictor corrector method for fractional order initial value problems
Artikel
Lizenziert
Nicht lizenziert Erfordert eine Authentifizierung

Convergence rate estimates for the kernelized predictor corrector method for fractional order initial value problems

  • Joel A. Rosenfeld EMAIL logo und Warren E. Dixon
Veröffentlicht/Copyright: 22. November 2021
Veröffentlichen auch Sie bei De Gruyter Brill
Informationen für Autor*innen Erkunden Sie dieses Fachgebiet
Fractional Calculus and Applied Analysis
Aus der Zeitschrift Fractional Calculus and Applied Analysis Band 24 Heft 6

Abstract

This manuscript presents a kernelized predictor corrector (KPC) method for fractional order initial value problems, which replaces linear interpolation with interpolation by a radial basis function (RBF) in a predictor-corrector scheme. Specifically, the class of Wendland RBFs is employed as the basis function for interpolation, and a convergence rate estimate is proved based on the smoothness of the particular kernel selected. Use of the Wendland RBFs over Mittag-Leffler kernel functions employed in a previous iteration of the kernelized method removes the problems encountered near the origin in [11]. This manuscript performs several numerical experiments, each with an exact known solution, and compares the results to another frequently used fractional Adams-Bashforth-Moulton method. Ultimately, it is demonstrated that the KPC method is more accurate but requires more computation time than the algorithm in [4].

MSC 2010: 26A33; 65L05; 34A08
Key Words and Phrases: fractional ordinary differential equations; Adams Bashforth Moulton; reproducing kernel Hilbert spaces; Wendland radial basis functions

Acknowledgments

The work of the authors was supported in part by NSF award 1509516 and Office of Naval Research grant N00014-13-1-0151. The first author was further supported by the Air Force Office of Scientific Research (AFOSR) under contract numbers FA9550-15-1-0258, FA9550-16-1-0246, FA9550-18-1-0122, and FA9550-21-1-0134 during the preparation of the manuscript. Any opinions, findings, and conclusions or recommendations expressed in this material are those of the authors and do not necessarily reflect the views of the sponsoring agencies.

References

[1] O. P. Agrawal and P. Kumar, Comparison of five numerical schemes for fractional differential equations. In: Advances in Fractional Calculus, Springer, 2007, 43–60.10.1007/978-1-4020-6042-7_4Suche in Google Scholar

[2] N. Aronszajn, Theory of reproducing kernels. Trans. Amer. Math. Soc. 68 (1950), 337–404, 10.2307/1990404.Suche in Google Scholar

[3] S. De Marchi and R. Schaback, Stability of kernel-based interpolation. Adv. in Computational Math. 32 (2010), 155–161; 10.1007/s10444-008-9093-4.Suche in Google Scholar

[4] K. Diethelm, The Analysis of Fractional Differential Equations: An Application-Oriented Exposition Using Differential Operators of Caputo Type. Springer, 2010.10.1007/978-3-642-14574-2Suche in Google Scholar

[5] K. Diethelm and N. J. Ford, Analysis of fractional differential equations. J. of Math. Anal. and Appl. 265 (2002), 229–248.10.1007/978-3-642-14574-2Suche in Google Scholar

[6] K. Diethelm and N. J. Ford, Multi-order fractional differential equations and their numerical solution. Appl. Math. and Computation 154 (2004), 621–640.10.1016/S0096-3003(03)00739-2Suche in Google Scholar

[7] K. Diethelm, N. J. Ford, and A. D. Freed, A predictor-corrector approach for the numerical solution of fractional differential equations. Nonlin. Dynamics 29 (2002), 3–22.10.1023/A:1016592219341Suche in Google Scholar

[8] L. C. Evans, Partial Differential Equations. Graduate Studies in Mathematics, Vol. 19, Amer. Math. Soc., 1998.Suche in Google Scholar

[9] G. E. Fasshauer, Meshfree Approximation Methods with Matlab (With CD-ROM), Vol. 6. World Scientific Publishing Company, 2007.10.1142/6437Suche in Google Scholar

[10] R. Garrappa, Numerical solution of fractional differential equations: A survey and a software tutorial. Mathematics 6, No 2 (2018), 16 pp.; 10.3390/math6020016.Suche in Google Scholar

[11] J. A. Rosenfeld and W. E. Dixon, Approximating the Caputo fractional derivative through the Mittag-Leffler reproducing kernel Hilbert space and the kernelized Adams–Bashforth–Moulton method. SIAM J. on Numer. Anal. 55 (2017), 1201–1217.10.1137/16M1056894Suche in Google Scholar

[12] J. A. Rosenfeld, B. Russo, and W. E. Dixon, The Mittag-Leffler reproducing kernel Hilbert spaces of entire and analytic functions. J. of Math. Anal. and Appl. 463 (2018), 576–592.10.1016/j.jmaa.2018.03.036Suche in Google Scholar

[13] I. Steinwart and A. Christmann, Support Vector Machines. Springer Sci. & Business Media, 2008.Suche in Google Scholar

[14] H. Wendland, Scattered Data Approximation, Vol. 17. Cambridge University Press, 2004.10.1017/CBO9780511617539Suche in Google Scholar
Received: 2019-06-18
Revised: 2021-10-24
Published Online: 2021-11-22
Published in Print: 2021-12-20

© 2021 Diogenes Co., Sofia

Artikel in diesem Heft

  1. Frontmatter
  2. Editorial
  3. FCAA related news, events and books (FCAA–volume 24–6–2021)
  4. Research Paper
  5. Weighted fractional Hardy operators and their commutators on generalized Morrey spaces over quasi-metric measure spaces
  6. B-spline collocation discretizations of caputo and Riemann-Liouville derivatives: A matrix comparison
  7. A strong maximum principle for the fractional laplace equation with mixed boundary condition
  8. Difference between Riesz derivative and fractional Laplacian on the proper subset of ℝ
  9. Some properties of the fractal convolution of functions
  10. Continuous dependence of fuzzy mild solutions on parameters for IVP of fractional fuzzy evolution equations
  11. Discrete fractional boundary value problems and inequalities
  12. On the generalized fractional Laplacian
  13. Recent developments on the realization of fractance device
  14. Explicit representation of discrete fractional resolvent families in Banach spaces
  15. Convergence rate estimates for the kernelized predictor corrector method for fractional order initial value problems
  16. Inverse problems for diffusion equation with fractional Dzherbashian-Nersesian operator
  17. An inverse problem approach to determine possible memory length of fractional differential equations
https://doi.org/10.1515/fca-2021-0081
Schlagwörter für diesen Artikel
fractional ordinary differential equations; Adams Bashforth Moulton; reproducing kernel Hilbert spaces; Wendland radial basis functions

Artikel in diesem Heft

  1. Frontmatter
  2. Editorial
  3. FCAA related news, events and books (FCAA–volume 24–6–2021)
  4. Research Paper
  5. Weighted fractional Hardy operators and their commutators on generalized Morrey spaces over quasi-metric measure spaces
  6. B-spline collocation discretizations of caputo and Riemann-Liouville derivatives: A matrix comparison
  7. A strong maximum principle for the fractional laplace equation with mixed boundary condition
  8. Difference between Riesz derivative and fractional Laplacian on the proper subset of ℝ
  9. Some properties of the fractal convolution of functions
  10. Continuous dependence of fuzzy mild solutions on parameters for IVP of fractional fuzzy evolution equations
  11. Discrete fractional boundary value problems and inequalities
  12. On the generalized fractional Laplacian
  13. Recent developments on the realization of fractance device
  14. Explicit representation of discrete fractional resolvent families in Banach spaces
  15. Convergence rate estimates for the kernelized predictor corrector method for fractional order initial value problems
  16. Inverse problems for diffusion equation with fractional Dzherbashian-Nersesian operator
  17. An inverse problem approach to determine possible memory length of fractional differential equations
Jetzt anmelden und 20% sparen
Institutioneller Zugang
Wie funktioniert Authentifizierung?
Haben Sie eine Idee, wie wir unsere Website verbessern können?
Bitte schreiben Sie uns.
© 2025 De Gruyter Brill
Heruntergeladen am 16.11.2025 von https://www.degruyterbrill.com/document/doi/10.1515/fca-2021-0081/pdf
Button zum nach oben scrollen