Residual Power Series Technique for Simulating Fractional Bagley–Torvik Problems Emerging in Applied Physics

Residual Power Series Technique for Simulating Fractional Bagley–Torvik Problems Emerging in Applied Physics

Numerical simulation of physical issues is often performed by nonlinear modeling, which typically involves solving a set of concurrent fractional differential equations through effective approximate methods. In this paper, an analytic-numeric simulation technique, called residual power series (RPS),...

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Veröffentlicht in:Applied sciences 2019-12, Vol.9 (23), p.5029
Hauptverfasser: Alshammari, Saleh, Al-Smadi, Mohammed, Hashim, Ishak, Alias, Mohd Almie
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Applied physics
caputo fractional derivative
Computer simulation
Curricula
Differential equations
Error functions
fractional bagley–torvik model
Mathematical models
Methods
newtonian fluid
Newtonian fluids
Numerical analysis
numerical simulation
Partial differential equations
Physics
Power
Power series
residual power series algorithm
STEM education
Viscoelasticity
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Zusammenfassung:Numerical simulation of physical issues is often performed by nonlinear modeling, which typically involves solving a set of concurrent fractional differential equations through effective approximate methods. In this paper, an analytic-numeric simulation technique, called residual power series (RPS), is proposed in obtaining the numerical solution a class of fractional Bagley–Torvik problems (FBTP) arising in a Newtonian fluid. This approach optimizes the solutions by minimizing the residual error functions that can be directly applied to generate fractional PS with a rapidly convergent rate. The RPS description is presented in detail to approximate the solution of FBTPs by highlighting all the steps necessary to implement the algorithm in addressing some test problems. The results indicate that the RPS algorithm is reliable and suitable in solving a wide range of fractional differential equations applying in physics and engineering.
ISSN:2076-3417
2076-3417
DOI:10.3390/app9235029