Numerical solution of singularly perturbed parabolic differential difference equations
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Karagandy University of the name of academician E.A. Buketov
Abstract
This study presents a computational method for the singularly perturbed parabolic differential difference
equations with small negative shifts in convection and reaction terms. To handle the small negative shifts,
the Taylor series expansion is applied. Then, the resulting asymptotically equivalent singularly perturbed
parabolic convection-diffusion-reaction problem is discretized in the time variable using the implicit Euler
technique on a uniform mesh, while the upwind method on a Shishkin mesh is used to discretize the space
variable. Almost first-order convergence was achieved by establishing the stability and parameter-uniform
convergence of the method. The Richardson extrapolation approach improved the rate of convergence to
nearly second-order. Numerical experiments have been carried out in order to support the findings from the
theory. The numerical results are presented in tables in terms of maximum absolute errors and graphs. The
present results improve the existing methods in the literature. This finding highlights the efficiency of the
method, paving the way for its application in other types of singularly perturbed parabolic problems. This
method is capable of greatly improving computing performance in a variety of scenarios, which researchers
can further explore.
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Huka D.B. Numerical solution of singularly perturbed parabolic differential difference equations / D.B. Huka, W.G. Melesse, F.W. Gelu // Bulletin of the Karaganda University. Mathematics Series. – 2025. – № 3(119). – pp. 107-124.