Abstract
We describe a quasi-variable meshes implicit compact finite-difference discretization having an accuracy of order four in the spatial direction and second-order in the temporal direction for obtaining numerical solution values of generalized Burger’s-Huxley and Burger’s-Fisher equations. The new difference scheme is derived for a general one-dimension quasi-linear parabolic partial differential equation on a quasi-variable meshes network to the extent that the magnitude of local truncation error of the high-order compact scheme remains unchanged in case of uniform meshes network. Practically, quasi-variable meshes high-order compact schemes yield more precise solution compared with uniform meshes high-order schemes of the same magnitude. A detailed exposition of the new scheme has been introduced and discussed the Fourier analysis based stability theory. The computational results with generalized Burger’s-Huxley equation and Burger’s-Fisher equation are obtained using quasi-variable meshes high-order compact scheme and compared with a numerical solution using uniform meshes high-order schemes to demonstrate capability and accuracy.
Highlights
The quasi-linear parabolic partial differential equations (PPDEs) play an important role in engineering and physical sciences such as convection effect, diffusion transport interaction, option pricing, fluid flow, and image processing
We list some of the famous examples to one-dimension PPDEs in the literature
We extend the scheme (4.14) to the quasi-linear parabolic partial differential equation (1.7) that involves first-order spatial and temporal derivative as a non-linear term
Summary
The quasi-linear parabolic partial differential equations (PPDEs) play an important role in engineering and physical sciences such as convection effect, diffusion transport interaction, option pricing, fluid flow, and image processing. Where 0 <
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