Finite element based hybrid techniques for advection-diffusion-reaction processes

Authors

  • Murat Sari Yildiz Technical University
  • Huseyin Tunc Department of Mathematics, Yildiz Technical University, Turkey

DOI:

https://doi.org/10.11121/ijocta.01.2018.00452

Keywords:

advection-diffusion-reaction process, Galerkin method, Taylor-Galerkin method, B-spline, finite element method

Abstract

In this paper, numerical solutions of the advection-diffusion-reaction (ADR) equation are investigated using the Galerkin, collocation and Taylor-Galerkin cubic B-spline finite element method in strong form of spatial elements using an ?-family optimization approach for time variation. The main objective of this article is to capture effective results of the finite element techniques with B-spline basis functions under the consideration of the ADR processes. All produced results are compared with the exact solution and the literature for various versions of problems including pure advection, pure diffusion, advection-diffusion, and advection-diffusion-reaction equations. It is proved that the present methods have good agreement with the exact solution and the literature.

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References

Dehghan, M. (2004). Weighted finite difference techniques for the one-dimensional advection-diffusion equation. Applied Mathematics and Computation, 147, 307-319.

Spalding, D.B. (1972). A novel finite difference formulation for differential expressions ivolving both first and second derivatives. International Journal for Numerical Methods in Engineering, 4, 551-559.

Irk, D., Dag, I. & Tombul, M. (2015). Extended cubic B-spline solution pf the advection-diffusion equation. KSCE Journal of Civil Engineering, 19, 929-934.

Aksan, E.N. (2006). Quadratic B-spline finite element method for numerical solution of the Burgers equation. Applied Mathematics and Computation, 174, 884-896.

Dag, I., Saka, B. & Boz, A. (2005). B-spline Galerkin methods for numerical solutions of Burgers’ equation. Applied Mathematics and Computation, 166, 506-522.

Dag, I., Irk, D. & Tombul, M. (2006). Least-squares finite element method for the advection diffusion equation. Applied Mathematics and Computation, 173, 554-565

Goh, J., Majid, A.A., & Ismail, A.I. Md. (2012). Cubic B-spline collocation method for one-dimensional heat and advection-diffusion equations. Journal of Applied Mathematics, 37, 1-8.

Ramakrishnan, C.V. (1979). An upwind finite element scheme for the unsteady convective diffusive transport equation. Applied Mathematical Modelling, 3, 280-284.

Korkmaz, A., & Dag, I. (2016). Quartic and quintic B-spline methods for advection-diffusion equation. Applied Mathematics and Computation, 274, 208-219.

Sari, M., Gürarslan, G. & Zeytinoglu, A. (2010). High-order finite difference schemes for solving the advection diffusion equation. Mathematical and Computational Applications, 15(3), 449-460.

Prenter, P.M. (1975). Splines and Variational Methods. John Wiley & Sons, New York.

Reddy, J. D. (2006). An Introduction to the Finite Element Method. McGraw-Hill. Singapore.

Sun, H. & Zhang, J. (2003). A high order compact boundary value method for solving one dimensional heat equations. Numerical Methods for Partial Differential Equations, 19, 846—857.

Kadalbajoo, M.K. & Arora, P. (2010). Taylor-Galerkin B-spline finite element method for the one-dimensional advection-diffusion equation. Numerical Methods for Partial Differential Equations, 26(5), 1206–1223.

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Published

2018-02-04
CITATION
DOI: 10.11121/ijocta.01.2018.00452
Published: 2018-02-04

How to Cite

Sari, M., & Tunc, H. (2018). Finite element based hybrid techniques for advection-diffusion-reaction processes. An International Journal of Optimization and Control: Theories & Applications (IJOCTA), 8(2), 127–136. https://doi.org/10.11121/ijocta.01.2018.00452

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Research Articles

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