A time semi-exponentially fitted scheme for chemotaxis-growth models

Autor:	M. Benzakour Amine, M. Akhmouch
Rok vydání:	2016
Předmět:	Algebra and Number Theory Finite volume method Discretization Numerical analysis Weak solution Mathematical analysis 010103 numerical & computational mathematics 01 natural sciences Backward Euler method 010101 applied mathematics Computational Mathematics Nonlinear system Convergence (routing) Uniqueness 0101 mathematics Mathematics
Zdroj:	Calcolo. 54:609-641
ISSN:	1126-5434 0008-0624
DOI:	10.1007/s10092-016-0201-4
Popis:	In this work, we develop a new linearized implicit finite volume method for chemotaxis-growth models. First, we derive the scheme for a simplified chemotaxis model arising in embryology. The model consists of two coupled nonlinear PDEs: parabolic convection-diffusion equation with a logistic source term for the cell-density, and an elliptic reaction-diffusion equation for the chemical signal. The numerical approximation makes use of a standard finite volume scheme in space with a special treatment for the convection-diffusion fluxes which are approximated by the classical Il'in fluxes. For the time discretization, we introduce our linearized semi-exponentially fitted scheme. The paper gives a comparison between the proposed scheme and different versions of linearized backward Euler schemes. The existence and uniqueness of a numerical solution to the scheme and its convergence to a weak solution of the studied system are proved. In the last section, we present some numerical tests to show the performance of our method. Our numerical approach is then applied to a chemotaxis-growth model describing bacterial pattern formation.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::698c2a8e0f03db42ed41686e293f7ada https://doi.org/10.1007/s10092-016-0201-4 Zobrazit plný text záznamu Full text from SpringerLink