Open AccessUniformly Convergent Hybrid Numerical Method for Singularly Perturbed Delay Convection-Diffusion Problems
Author(s) -
Mesfin Mekuria Woldaregay,
Gemechis File Duressa
Publication year - 2021
Publication title -
international journal of differential equations
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.324
H-Index - 20
eISSN - 1687-9651
pISSN - 1687-9643
DOI - 10.1155/2021/6654495
Subject(s) - mathematics , discretization , piecewise , uniform convergence , mathematical analysis , boundary (topology) , boundary layer , convergence (economics) , convection–diffusion equation , rate of convergence , stability (learning theory) , temporal discretization , series (stratigraphy) , mechanics , computer network , channel (broadcasting) , paleontology , physics , bandwidth (computing) , machine learning , computer science , economics , biology , economic growth , engineering , electrical engineering
This paper deals with numerical treatment of nonstationary singularly perturbed delay convection-diffusion problems. The solution of the considered problem exhibits boundary layer on the right side of the spatial domain. To approximate the term with the delay, Taylor’s series approximation is used. The resulting time-dependent singularly perturbed convection-diffusion problems are solved using Crank-Nicolson method for temporal discretization and hybrid method for spatial discretization. The hybrid method is designed using mid-point upwind in regular region with central finite difference in boundary layer region on piecewise uniform Shishkin mesh. Numerical examples are used to validate the theoretical findings and analysis of the proposed scheme. The present method gives accurate and nonoscillatory solutions in regular and boundary layer regions of the solution domain. The stability and the uniform convergence of the scheme are proved. The scheme converges uniformly with almost second-order rate of convergence.