Abstract
Time-fractional nonlinear partial differential equations (TFNPDEs) with proportional delay are commonly used for modeling real-world phenomena like earthquake, volcanic eruption, and brain tumor dynamics. These problems are quite challenging, and the transcendental nature of the delay makes them even more difficult. Hence, the development of efficient numerical methods is open for research. In this paper, we use the concepts of Laplace-like transform and variational theory to develop a new numerical method for solving TFNPDEs with proportional delay. The stability and convergence of the method are analyzed in the Banach sense. The efficiency of the proposed method is demonstrated by solving some test problems. The numerical results show that the proposed method performs much better than some recently developed methods and enables us to obtain more accurate solutions.
Highlights
Fractional calculus is a valuable concept in applied mathematics dedicated to the study of integrals and derivatives of arbitrary positive order [1, 2]
We propose a new numerical method which benefits from the nice properties of Laplace-like transform and variational theory
4 Numerical results and discussion we show the efficiency of Laplace transform variational iteration method (LTVIM) by solving some Time-fractional nonlinear partial differential equations (TFNPDEs) problems with proportional delay
Summary
Fractional calculus is a valuable concept in applied mathematics dedicated to the study of integrals and derivatives of arbitrary positive order [1, 2]. We are interested in time-fractional nonlinear partial differential equations (TFNPDEs) with proportional delay.
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