Author:
Saeed Nagwa A.,Pachpatte Deepak B.
Abstract
AbstractThis research article introduces a novel approach based on the fuzzy Adomian decomposition method (FADM) to solve specific time fuzzy fractional partial differential equations with initial and boundary conditions (IBCs). The proposed approach addresses the challenge of incorporating both initial and boundary conditions into the FADM framework by employing a modified approach. This approach iteratively generates a new initial solution using the decomposition method. The method presented here offers a significant contribution to solving fuzzy fractional partial differential equations (FFPDEs) with fuzzy IBCs, a topic that has received limited attention in the literature. Furthermore, it satisfies a high convergence rate with minimal computational complexity, establishing a novel aspect of this research. By providing a series solution with a small number of recursive formulas, this method enhances accuracy and emerges as a preferred choice for tackling FFPDEs with mixed initial and boundary conditions. The effectiveness of the proposed technique is further supported by the inclusion of several illustrative examples.
Publisher
Springer Science and Business Media LLC
Reference40 articles.
1. Alaroud, M., Ababneh, O., Tahat, N., Al-Omari, S.: Analytic technique for solving temporal time-fractional gas dynamics equations with Caputo fractional derivative. AIMS Math. 7, 17647–17669 (2022)
2. Ali, E.J.: A new technique of initial boundary value problems using Adomian decomposition method. Int. Math. Forum 7, 799–814 (2012)
3. Allahviranloo, T.: Fuzzy Fractional Differential Operators and Equations: Fuzzy Fractional Differential Equations. Springer, Berlin (2020)
4. Allahviranloo, T., Salahshour, S., Abbasbandy, S.: Explicit solutions of fractional differential equations with uncertainty. Soft Comput. 16, 297–302 (2012)
5. Alqurashi, M.S., Rashid, S., Kanwal, B., Jarad, F., Elagan, S.K.: A novel formulation of the fuzzy hybrid transform for dealing nonlinear partial differential equations via fuzzy fractional derivative involving general order. AIMS Math. 7, 14946–14974 (2022)