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Analysis of a finite difference scheme for a nonlinear Caputo fractional differential equation on an adaptive grid

  • Received: 25 April 2021 Accepted: 02 June 2021 Published: 07 June 2021
  • MSC : 65L05, 65L12, 65L20

  • A nonlinear initial value problem whose differential operator is a Caputo derivative of order $ \alpha $ with $ 0 < \alpha < 1 $ is studied. By using the Riemann-Liouville fractional integral transformation, this problem is reformulated as a Volterra integral equation, which is discretized by using the right rectangle formula. Both a priori and an a posteriori error analysis are conducted. Based on the a priori error bound and mesh equidistribution principle, we show that there exists a nonuniform grid that gives first-order convergent result, which is robust with respect to $ \alpha $. Then an a posteriori error estimation is derived and used to design an adaptive grid generation algorithm. Numerical results complement the theoretical findings.

    Citation: Yong Zhang, Xiaobing Bao, Li-Bin Liu, Zhifang Liang. Analysis of a finite difference scheme for a nonlinear Caputo fractional differential equation on an adaptive grid[J]. AIMS Mathematics, 2021, 6(8): 8611-8624. doi: 10.3934/math.2021500

    Related Papers:

  • A nonlinear initial value problem whose differential operator is a Caputo derivative of order $ \alpha $ with $ 0 < \alpha < 1 $ is studied. By using the Riemann-Liouville fractional integral transformation, this problem is reformulated as a Volterra integral equation, which is discretized by using the right rectangle formula. Both a priori and an a posteriori error analysis are conducted. Based on the a priori error bound and mesh equidistribution principle, we show that there exists a nonuniform grid that gives first-order convergent result, which is robust with respect to $ \alpha $. Then an a posteriori error estimation is derived and used to design an adaptive grid generation algorithm. Numerical results complement the theoretical findings.



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