Application of an Extended Cubic B-Spline to Find the Numerical Solution of the Generalized Nonlinear Time-Fractional Klein–Gordon Equation in Mathematical Physics

Miguel Vivas-Cortez, M. J. Huntul, Maria Khalid, Madiha Shafiq, Muhammad Abbas, Muhammad Kashif Iqbal

Research output: Contribution to journalArticlepeer-review

3 Scopus citations

Abstract

A B-spline function is a series of flexible elements that are managed by a set of control points to produce smooth curves. By using a variety of points, these functions make it possible to build and maintain complicated shapes. Any spline function of a certain degree can be expressed as a linear combination of the B-spline basis of that degree. The flexibility, symmetry and high-order accuracy of the B-spline functions make it possible to tackle the best solutions. In this study, extended cubic B-spline (ECBS) functions are utilized for the numerical solutions of the generalized nonlinear time-fractional Klein–Gordon Equation (TFKGE). Initially, the Caputo time-fractional derivative (CTFD) is approximated using standard finite difference techniques, and the space derivatives are discretized by utilizing ECBS functions. The stability and convergence analysis are discussed for the given numerical scheme. The presented technique is tested on a variety of problems, and the approximate results are compared with the existing computational schemes.

Original languageEnglish
Article number80
JournalComputation
Volume12
Issue number4
DOIs
StatePublished - 11 Apr 2024

Bibliographical note

Publisher Copyright:
© 2024 by the authors.

Keywords

  • Caputo time-fractional derivative
  • extended cubic B-spline functions
  • nonlinear time-fractional Klein–Gordon equation
  • stability and convergence

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