Theoretical and Numerical Analysis of Singular Perturbation Problems in Ordinary Differential Equations

Authors

  • Nada Abdul-Hassan Atiyah Mathematics Department, Al-Qadisiyah University, Diwaniyah, Iraq
  • Marwa Qasaim Atshan Mathematics Department, Al-Qadisiyah University, Diwaniyah, Iraq

DOI:

https://doi.org/10.29304/jqcsm.2024.16.31667

Keywords:

Singular Perturbation, Boundary Layer, Matched Asymptotic Expansions, Ordinary Differential Equations (ODEs)

Abstract

Background: Singular perturbation troubles in everyday differential equations (ODEs) involve a small parameter ϵ that causes answers to show off behaviors on multiple scales, main to massive challenges in both theoretical and numerical evaluation.

Objective: This paper at targets to comprehensively look at the theoretical and numerical techniques for reading and solving singular perturbation troubles in ODEs. Focus is located on know-how the behaviors precipitated through the small parameter and developing strong numerical techniques to accurately seize these behaviors.

Methods: Theoretical approaches employed include matched asymptotic expansions and multiple scale analysis. These methods decompose the solution domain into regions with different scales, constructing and matching approximate solutions to ensure smooth transitions. Numerical techniques such as finite difference methods, finite element methods, and spectral methods are utilized, with particular emphasis on adaptive mesh refinement to handle boundary layers effectively

Results: Theoretical evaluation demonstrates the effectiveness of matched asymptotic expansions and multiple scale analysis in presenting correct approximations and easy transitions among one of a kind solution regions. Numerical techniques showed high accuracy and performance, particularly whilst blended with adaptive techniques. Finite distinction strategies with non-uniform grids and adaptive mesh refinement, finite detail techniques with adaptive mesh strategies, and spectral strategies with special handling of boundary layers all proved successful. Stability and convergence analyses showed the reliability of those techniques.

Conclusions: This comprehensive evaluation highlights the strengths and applicability of each theoretical and numerical strategies in tackling singular perturbation issues in ODEs. The mixed use of these techniques lets in for correct and green answers, presenting treasured equipment for applications in diverse clinical and engineering fields.

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References

Bender, C. M., &Orszag, S. A. (1999). *Advanced Mathematical Methods for Scientists and Engineers I: Asymptotic Methods and Perturbation Theory*. Springer.

Holmes, M. H. (2013). *Introduction to Perturbation Methods*. Springer.

Hinch, E. J. (1991). *Perturbation Methods*. Cambridge University Press.

Kevorkian, J., & Cole, J. D. (1981). *Perturbation Methods in Applied Mathematics*.

Springer. Smith, G. D. (1985). *Numerical Solution of Partial Differential Equations: Finite Difference Methods*. Oxford University Press.

Morton, K. W., &Mayers, D. F. (2005). *Numerical Solution of Partial Differential Equations: An Introduction*. Cambridge University Press.

Friedman, A. (2008). *Partial Differential Equations*. Dover Publications.

Trefethen, L. N. (2000). *Spectral Methods in MATLAB*. SIAM.

Ascher, U. M., &Petzold, L. R. (1998). *Computer Methods for Ordinary Differential Equations and Differential-Algebraic Equations*. SIAM.

Roos, H.-G., Stynes, M., &Tobiska, L. (2008). *Robust Numerical Methods for Singularly Perturbed Differential Equations: Convection-Diffusion-Reaction and Flow Problems*. Springer.

Govindarao, L., &Mohapatra, J. (2019). A second order numerical method for singularly perturbed delay parabolic partial differential equation. Engineering Computations, 36(2), 420-444.

Butcher, J. C. (2016). Numerical methods for ordinary differential equations. John Wiley & Sons.

El-Zahar, E. R. (2015). Applications of adaptive multi step differential transform method to singular perturbation problems arising in science and engineering. Applied Mathematics & Information Sciences, 9(1), 223.

Cardin, P. T., & Teixeira, M. A. (2017). Fenichel theory for multiple time scale singular perturbation problems. SIAM Journal on Applied Dynamical Systems, 16(3), 1425-1452.

Dalla Riva, M., Lanza de Cristoforis, M., &Musolino, P. (2021). Singularly perturbed boundary value problems. A Functional Analytic Approach. Springer, Cham.

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Published

2024-09-30

How to Cite

Abdul-Hassan Atiyah, N., & Qasaim Atshan, M. (2024). Theoretical and Numerical Analysis of Singular Perturbation Problems in Ordinary Differential Equations. Journal of Al-Qadisiyah for Computer Science and Mathematics, 16(3), Math. 63–70. https://doi.org/10.29304/jqcsm.2024.16.31667

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Section

Math Articles