Numerical analysis of a semi-implicit Euler scheme for the Keller-Segel model
By: Xueling Huang, Olivier Goubet, Jie Shen
Potential Business Impact:
Keeps cell movement math accurate and stable.
We study the properties of a semi-implicit Euler scheme that is widely used in time discretization of Keller-Segel equations both in the parabolic-elliptic form and the parabolic-parabolic form. We prove that this linear, decoupled, first-order scheme preserves unconditionally the important properties of Keller-Segel equations at the semi-discrete level, including the mass conservation and positivity preserving of the cell density, and the energy dissipation. We also establish optimal error estimates in $L^p$-norm $(1<p<\infty)$.
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